GDHS-LEC-04

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Lecture # 4

Transcript

الحمد لله رب العالمين والصالة والسالم على خاتم

النبيين

Geometric Design ndash Basic Principles Safety for all users Functionality ndash the need for access and mobility Accessibility for people with disabilities ndash as a prerequisite to

access to employment recreation and healthcare Mutual support and compatibility between transportation

facilities and services and the adjacent land uses and associated activities they serve

Consistency with transportation plans and policies and environmental regulations that guide the community the region the province and the Federal government

Transportation facility design and operational requirements established by others

Input and participation from local constituents and the appropriate local regional and state reviewing agencies 1048708

Cost effectiveness ndash the value returned for the investments made in transportation

GEOMETRIC DESIGN ndash Course Heads

Cross-Section Elements Horizontal Alignment Vertical Alignment Intersections Interchanges helliphelliphelliphellip helliphelliphelliphellip

500

1000

1500

2000

2500

3000

3500

4000

4500

3-D Model

Curves Straight segments are called Tangents Horizontal curves help change from one

tangent to another

Horizontal Curves MAXIMUM CENTERLINE DEFLECTION

NOT REQUIRING HORIZONTAL CURVE

Design Speed mph Maximum Deflection

25 5deg30

30 3deg45

35 2deg45

40 2deg15

45 1deg15

50 1deg15

55 1deg00

60 1deg00

65 0deg45

70 0deg45

Source Ohio DOT Design Manual Figure 202-1E

Design Elements Curves

Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

Transitions

Curves Horizontal curves are circular to minimize steering

effort Curves need to be long enough to avoid unsafe or

uncomfortable conditions

Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

transition from an infinite radius (a tangent) to the radius of the circular curve

Design Elements Design Questions

Which one to be used where and how What should be the minimum radius

bull without Transitionbull with Transition

With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

Curves Simple Circular

Curves Compound Curves

Horizontal Curves

Horizontal Curves

Horizontal Curves

Horizontal Curves

Horizontal Curves

Horizontal Curves

Horizontal Curves

Horizontal Curve Sight Distance

Horizontal Curve Sight Distance

Curves Minimum Radius

Rmin = ____V2____

15 (e + f) where Rmin is the minimum radius in feet

V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

and graphed in Green Book) and design speed

bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

bull f decreases as speed increases (less tire pavement contact)

Curves Max e is controlled by 4 factors

bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

influenced by high super elevation rates Max e

bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

bull For consistency use a single rate within a project or on a highway

Curves

Curves

TRANSITIONSTRANSITIONS

SuperelevationSuperelevationSpiral CurvesSpiral Curves

TRANSITIONSTRANSITIONS

SuperelevationSuperelevationSpiral CurvesSpiral Curves

Superelevation

Image

httptechalivemtuedumodulesmodule0003Superelevationhtm

Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

design may help avoid roadside obstacles that might otherwise be impacted by the alignment

In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

Superelevation Although superelevation is advantageous for traffic

operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

Attainment of Superelevation - General

bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

bull Change in pavement slope should be consistent over a distance

Tangent Runout Section Superelevation Runoff Section bull Methods

bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

Tangent Runout Section

Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

For rotation about centerline

Superelevation Runoff Section

Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

For undivided highways with cross-section rotated about centerline

Superelevation Transitioning The development of superelevation on a horizontal curve requires a

transition from a normal crown section which is accomplished by rotating the pavement

The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

Cross section (-a-) is the normal crown section where the transitioning begins

Cross section (-b-) is reached by rotating half the pavement until it is level

Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

Superelevation Transitioning Rotation about the centerline profile of traveled way

This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

Superelevation Transitioning Rotation about the outside-edge profile of traveled way

This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

39

40

Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

Same as point E of GB

Attainment Location - WHERE

Superelevation must be attained over a length that includes the tangent and the curve

Typical 66 on tangent and 33 on curve of length of runoff if no spiral

Super runoff is all attained in Spiral if used

Minimum Length of Runoff for curve

Lr based on drainage and aesthetics

rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

Minimum Length of Tangent Runout

Lt = eNC x Lr

ed

where

eNC = normal cross slope rate ()

ed = design superelevation rate

Lr = minimum length of superelevation runoff (ft)

(Result is the edge slope is same as for Runoff segment)

Length of Superelevation Runoff

α = multilane adjustment factor adjusts for total width

r

Relative Gradient (G)

Maximum longitudinal slope Depends on design speed higher speed =

gentler slope

For example For 15 mph G = 078 For 80 mph G = 035 See table next page

Maximum Relative Gradient (G)

Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

Multilane Adjustment

Runout and runoff must be adjusted for multilane rotation

See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

Length of Superelevation Runoff Example

For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

Lr = 12eα

G

50

Lr = 12eα = (12) (004) (15)

G 05

Lr = 144 feet

Tangent runout length Example continued

Lt = (eNC ed ) x Lr

as defined previously if NC = 2

Tangent runout for the example is

LT = 2 4 144rsquo = 72 feet

52

From previous example speed = 50 mph e = 4

From chart runoff = 144 feet same as from calculation

Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

Spiral Curve Transitions Vehicles follow a transition path as they enter or

leave a horizontal curve

Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

Spirals Advantages

Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

Provides location for superelevation runoff (not part on tangentcurve)

Provides transition in width when horizontal curve is widened

Aesthetic

Minimum Length of Spiral

Possible Equations

Larger of (1) L = 315 V3

RC

Where

L = minimum length of spiral (ft)

V = speed (mph)

R = curve radius (ft)

C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

Minimum Length of Spiral

Or (2) L = (24pminR)12

Where

L = minimum length of spiral (ft)

R = curve radius (ft)

pmin = minimum lateral offset between the tangent and circular curve (066 feet)

Maximum Length of Spiral

L = (24pmaxR)12

Where

L = maximum length of spiral (ft)

R = curve radius (ft)

pmax = maximum lateral offset between the tangent and circular curve (33 feet)

Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

Length of Spiralo AASHTO also provides recommended spiral lengths

based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

o Superelevation runoff length is set equal to the spiral curve length when spirals are used

o Design Note For construction purposes round your designs to a reasonable values eg

Ls = 147 feet round it to

Ls = 150 feet

Source Iowa DOT Design Manual

SPIRAL TERMINOLOGY

Source Iowa DOT Design Manual

Source Iowa DOT Design Manual

Source Iowa DOT Design Manual

Attainment of Superelevationon spiral curves

See sketches that follow

Normal Crown (DOT ndash pt A)

1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

2 Point of reversal of crown (DOT ndash C) note A to B = B to C

3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

4 Fully superelevate remainder of curve and then reverse the process at the CS

65Source Iowa DOT Standard Road Plans RP-2

With Spirals

Same as point E of GB

With Spirals

Tangent runout (A to B)

With Spirals

Removal of crown

With Spirals

Transition of superelevation

Full superelevation

69

  • Slide 1
  • Geometric Design ndash Basic Principles
  • GEOMETRIC DESIGN ndash Course Heads
  • Slide 4
  • Curves
  • Horizontal Curves
  • Design Elements
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Horizontal Curves
  • Slide 13
  • Slide 14
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Horizontal Curve Sight Distance
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • TRANSITIONS Superelevation Spiral Curves
  • Superelevation
  • Image
  • Superelevation Transitioning
  • Slide 30
  • Attainment of Superelevation - General
  • Tangent Runout Section
  • Superelevation Runoff Section
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Slide 38
  • Slide 39
  • Slide 40
  • Slide 41
  • Attainment Location - WHERE
  • Minimum Length of Runoff for curve
  • Minimum Length of Tangent Runout
  • Length of Superelevation Runoff
  • Relative Gradient (G)
  • Maximum Relative Gradient (G)
  • Multilane Adjustment
  • Length of Superelevation Runoff Example
  • Slide 50
  • Tangent runout length Example continued
  • Slide 52
  • Spiral Curve Transitions
  • Slide 54
  • Spirals
  • Minimum Length of Spiral
  • Slide 57
  • Maximum Length of Spiral
  • Length of Spiral
  • Slide 60
  • Slide 61
  • Slide 62
  • Slide 63
  • Attainment of Superelevation on spiral curves
  • Slide 65
  • Slide 66
  • Slide 67
  • Slide 68
  • Slide 69

    Geometric Design ndash Basic Principles Safety for all users Functionality ndash the need for access and mobility Accessibility for people with disabilities ndash as a prerequisite to

    access to employment recreation and healthcare Mutual support and compatibility between transportation

    facilities and services and the adjacent land uses and associated activities they serve

    Consistency with transportation plans and policies and environmental regulations that guide the community the region the province and the Federal government

    Transportation facility design and operational requirements established by others

    Input and participation from local constituents and the appropriate local regional and state reviewing agencies 1048708

    Cost effectiveness ndash the value returned for the investments made in transportation

    GEOMETRIC DESIGN ndash Course Heads

    Cross-Section Elements Horizontal Alignment Vertical Alignment Intersections Interchanges helliphelliphelliphellip helliphelliphelliphellip

    500

    1000

    1500

    2000

    2500

    3000

    3500

    4000

    4500

    3-D Model

    Curves Straight segments are called Tangents Horizontal curves help change from one

    tangent to another

    Horizontal Curves MAXIMUM CENTERLINE DEFLECTION

    NOT REQUIRING HORIZONTAL CURVE

    Design Speed mph Maximum Deflection

    25 5deg30

    30 3deg45

    35 2deg45

    40 2deg15

    45 1deg15

    50 1deg15

    55 1deg00

    60 1deg00

    65 0deg45

    70 0deg45

    Source Ohio DOT Design Manual Figure 202-1E

    Design Elements Curves

    Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

    Transitions

    Curves Horizontal curves are circular to minimize steering

    effort Curves need to be long enough to avoid unsafe or

    uncomfortable conditions

    Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

    transition from an infinite radius (a tangent) to the radius of the circular curve

    Design Elements Design Questions

    Which one to be used where and how What should be the minimum radius

    bull without Transitionbull with Transition

    With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

    Curves Simple Circular

    Curves Compound Curves

    Horizontal Curves

    Horizontal Curves

    Horizontal Curves

    Horizontal Curves

    Horizontal Curves

    Horizontal Curves

    Horizontal Curves

    Horizontal Curve Sight Distance

    Horizontal Curve Sight Distance

    Curves Minimum Radius

    Rmin = ____V2____

    15 (e + f) where Rmin is the minimum radius in feet

    V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

    Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

    and graphed in Green Book) and design speed

    bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

    bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

    bull f decreases as speed increases (less tire pavement contact)

    Curves Max e is controlled by 4 factors

    bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

    influenced by high super elevation rates Max e

    bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

    bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

    bull For consistency use a single rate within a project or on a highway

    Curves

    Curves

    TRANSITIONSTRANSITIONS

    SuperelevationSuperelevationSpiral CurvesSpiral Curves

    TRANSITIONSTRANSITIONS

    SuperelevationSuperelevationSpiral CurvesSpiral Curves

    Superelevation

    Image

    httptechalivemtuedumodulesmodule0003Superelevationhtm

    Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

    design may help avoid roadside obstacles that might otherwise be impacted by the alignment

    In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

    Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

    Superelevation Although superelevation is advantageous for traffic

    operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

    Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

    Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

    Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

    Attainment of Superelevation - General

    bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

    bull Change in pavement slope should be consistent over a distance

    Tangent Runout Section Superelevation Runoff Section bull Methods

    bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

    Tangent Runout Section

    Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

    For rotation about centerline

    Superelevation Runoff Section

    Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

    For undivided highways with cross-section rotated about centerline

    Superelevation Transitioning The development of superelevation on a horizontal curve requires a

    transition from a normal crown section which is accomplished by rotating the pavement

    The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

    Cross section (-a-) is the normal crown section where the transitioning begins

    Cross section (-b-) is reached by rotating half the pavement until it is level

    Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

    Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

    Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

    Superelevation Transitioning Rotation about the centerline profile of traveled way

    This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

    Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

    Superelevation Transitioning Rotation about the outside-edge profile of traveled way

    This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

    Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

    The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

    39

    40

    Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

    Same as point E of GB

    Attainment Location - WHERE

    Superelevation must be attained over a length that includes the tangent and the curve

    Typical 66 on tangent and 33 on curve of length of runoff if no spiral

    Super runoff is all attained in Spiral if used

    Minimum Length of Runoff for curve

    Lr based on drainage and aesthetics

    rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

    current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

    Minimum Length of Tangent Runout

    Lt = eNC x Lr

    ed

    where

    eNC = normal cross slope rate ()

    ed = design superelevation rate

    Lr = minimum length of superelevation runoff (ft)

    (Result is the edge slope is same as for Runoff segment)

    Length of Superelevation Runoff

    α = multilane adjustment factor adjusts for total width

    r

    Relative Gradient (G)

    Maximum longitudinal slope Depends on design speed higher speed =

    gentler slope

    For example For 15 mph G = 078 For 80 mph G = 035 See table next page

    Maximum Relative Gradient (G)

    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

    Multilane Adjustment

    Runout and runoff must be adjusted for multilane rotation

    See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

    Length of Superelevation Runoff Example

    For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

    Lr = 12eα

    G

    50

    Lr = 12eα = (12) (004) (15)

    G 05

    Lr = 144 feet

    Tangent runout length Example continued

    Lt = (eNC ed ) x Lr

    as defined previously if NC = 2

    Tangent runout for the example is

    LT = 2 4 144rsquo = 72 feet

    52

    From previous example speed = 50 mph e = 4

    From chart runoff = 144 feet same as from calculation

    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

    Spiral Curve Transitions Vehicles follow a transition path as they enter or

    leave a horizontal curve

    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

    Spirals Advantages

    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

    Provides location for superelevation runoff (not part on tangentcurve)

    Provides transition in width when horizontal curve is widened

    Aesthetic

    Minimum Length of Spiral

    Possible Equations

    Larger of (1) L = 315 V3

    RC

    Where

    L = minimum length of spiral (ft)

    V = speed (mph)

    R = curve radius (ft)

    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

    Minimum Length of Spiral

    Or (2) L = (24pminR)12

    Where

    L = minimum length of spiral (ft)

    R = curve radius (ft)

    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

    Maximum Length of Spiral

    L = (24pmaxR)12

    Where

    L = maximum length of spiral (ft)

    R = curve radius (ft)

    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

    Length of Spiralo AASHTO also provides recommended spiral lengths

    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

    o Design Note For construction purposes round your designs to a reasonable values eg

    Ls = 147 feet round it to

    Ls = 150 feet

    Source Iowa DOT Design Manual

    SPIRAL TERMINOLOGY

    Source Iowa DOT Design Manual

    Source Iowa DOT Design Manual

    Source Iowa DOT Design Manual

    Attainment of Superelevationon spiral curves

    See sketches that follow

    Normal Crown (DOT ndash pt A)

    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

    4 Fully superelevate remainder of curve and then reverse the process at the CS

    65Source Iowa DOT Standard Road Plans RP-2

    With Spirals

    Same as point E of GB

    With Spirals

    Tangent runout (A to B)

    With Spirals

    Removal of crown

    With Spirals

    Transition of superelevation

    Full superelevation

    69

    • Slide 1
    • Geometric Design ndash Basic Principles
    • GEOMETRIC DESIGN ndash Course Heads
    • Slide 4
    • Curves
    • Horizontal Curves
    • Design Elements
    • Slide 8
    • Slide 9
    • Slide 10
    • Slide 11
    • Horizontal Curves
    • Slide 13
    • Slide 14
    • Slide 15
    • Slide 16
    • Slide 17
    • Slide 18
    • Horizontal Curve Sight Distance
    • Slide 20
    • Slide 21
    • Slide 22
    • Slide 23
    • Slide 24
    • Slide 25
    • TRANSITIONS Superelevation Spiral Curves
    • Superelevation
    • Image
    • Superelevation Transitioning
    • Slide 30
    • Attainment of Superelevation - General
    • Tangent Runout Section
    • Superelevation Runoff Section
    • Slide 34
    • Slide 35
    • Slide 36
    • Slide 37
    • Slide 38
    • Slide 39
    • Slide 40
    • Slide 41
    • Attainment Location - WHERE
    • Minimum Length of Runoff for curve
    • Minimum Length of Tangent Runout
    • Length of Superelevation Runoff
    • Relative Gradient (G)
    • Maximum Relative Gradient (G)
    • Multilane Adjustment
    • Length of Superelevation Runoff Example
    • Slide 50
    • Tangent runout length Example continued
    • Slide 52
    • Spiral Curve Transitions
    • Slide 54
    • Spirals
    • Minimum Length of Spiral
    • Slide 57
    • Maximum Length of Spiral
    • Length of Spiral
    • Slide 60
    • Slide 61
    • Slide 62
    • Slide 63
    • Attainment of Superelevation on spiral curves
    • Slide 65
    • Slide 66
    • Slide 67
    • Slide 68
    • Slide 69

      GEOMETRIC DESIGN ndash Course Heads

      Cross-Section Elements Horizontal Alignment Vertical Alignment Intersections Interchanges helliphelliphelliphellip helliphelliphelliphellip

      500

      1000

      1500

      2000

      2500

      3000

      3500

      4000

      4500

      3-D Model

      Curves Straight segments are called Tangents Horizontal curves help change from one

      tangent to another

      Horizontal Curves MAXIMUM CENTERLINE DEFLECTION

      NOT REQUIRING HORIZONTAL CURVE

      Design Speed mph Maximum Deflection

      25 5deg30

      30 3deg45

      35 2deg45

      40 2deg15

      45 1deg15

      50 1deg15

      55 1deg00

      60 1deg00

      65 0deg45

      70 0deg45

      Source Ohio DOT Design Manual Figure 202-1E

      Design Elements Curves

      Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

      Transitions

      Curves Horizontal curves are circular to minimize steering

      effort Curves need to be long enough to avoid unsafe or

      uncomfortable conditions

      Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

      transition from an infinite radius (a tangent) to the radius of the circular curve

      Design Elements Design Questions

      Which one to be used where and how What should be the minimum radius

      bull without Transitionbull with Transition

      With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

      Curves Simple Circular

      Curves Compound Curves

      Horizontal Curves

      Horizontal Curves

      Horizontal Curves

      Horizontal Curves

      Horizontal Curves

      Horizontal Curves

      Horizontal Curves

      Horizontal Curve Sight Distance

      Horizontal Curve Sight Distance

      Curves Minimum Radius

      Rmin = ____V2____

      15 (e + f) where Rmin is the minimum radius in feet

      V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

      Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

      and graphed in Green Book) and design speed

      bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

      bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

      bull f decreases as speed increases (less tire pavement contact)

      Curves Max e is controlled by 4 factors

      bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

      influenced by high super elevation rates Max e

      bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

      bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

      bull For consistency use a single rate within a project or on a highway

      Curves

      Curves

      TRANSITIONSTRANSITIONS

      SuperelevationSuperelevationSpiral CurvesSpiral Curves

      TRANSITIONSTRANSITIONS

      SuperelevationSuperelevationSpiral CurvesSpiral Curves

      Superelevation

      Image

      httptechalivemtuedumodulesmodule0003Superelevationhtm

      Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

      design may help avoid roadside obstacles that might otherwise be impacted by the alignment

      In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

      Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

      Superelevation Although superelevation is advantageous for traffic

      operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

      Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

      Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

      Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

      Attainment of Superelevation - General

      bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

      bull Change in pavement slope should be consistent over a distance

      Tangent Runout Section Superelevation Runoff Section bull Methods

      bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

      Tangent Runout Section

      Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

      For rotation about centerline

      Superelevation Runoff Section

      Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

      For undivided highways with cross-section rotated about centerline

      Superelevation Transitioning The development of superelevation on a horizontal curve requires a

      transition from a normal crown section which is accomplished by rotating the pavement

      The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

      Cross section (-a-) is the normal crown section where the transitioning begins

      Cross section (-b-) is reached by rotating half the pavement until it is level

      Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

      Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

      Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

      Superelevation Transitioning Rotation about the centerline profile of traveled way

      This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

      Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

      Superelevation Transitioning Rotation about the outside-edge profile of traveled way

      This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

      Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

      The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

      39

      40

      Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

      Same as point E of GB

      Attainment Location - WHERE

      Superelevation must be attained over a length that includes the tangent and the curve

      Typical 66 on tangent and 33 on curve of length of runoff if no spiral

      Super runoff is all attained in Spiral if used

      Minimum Length of Runoff for curve

      Lr based on drainage and aesthetics

      rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

      current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

      Minimum Length of Tangent Runout

      Lt = eNC x Lr

      ed

      where

      eNC = normal cross slope rate ()

      ed = design superelevation rate

      Lr = minimum length of superelevation runoff (ft)

      (Result is the edge slope is same as for Runoff segment)

      Length of Superelevation Runoff

      α = multilane adjustment factor adjusts for total width

      r

      Relative Gradient (G)

      Maximum longitudinal slope Depends on design speed higher speed =

      gentler slope

      For example For 15 mph G = 078 For 80 mph G = 035 See table next page

      Maximum Relative Gradient (G)

      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

      Multilane Adjustment

      Runout and runoff must be adjusted for multilane rotation

      See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

      Length of Superelevation Runoff Example

      For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

      Lr = 12eα

      G

      50

      Lr = 12eα = (12) (004) (15)

      G 05

      Lr = 144 feet

      Tangent runout length Example continued

      Lt = (eNC ed ) x Lr

      as defined previously if NC = 2

      Tangent runout for the example is

      LT = 2 4 144rsquo = 72 feet

      52

      From previous example speed = 50 mph e = 4

      From chart runoff = 144 feet same as from calculation

      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

      Spiral Curve Transitions Vehicles follow a transition path as they enter or

      leave a horizontal curve

      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

      Spirals Advantages

      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

      Provides location for superelevation runoff (not part on tangentcurve)

      Provides transition in width when horizontal curve is widened

      Aesthetic

      Minimum Length of Spiral

      Possible Equations

      Larger of (1) L = 315 V3

      RC

      Where

      L = minimum length of spiral (ft)

      V = speed (mph)

      R = curve radius (ft)

      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

      Minimum Length of Spiral

      Or (2) L = (24pminR)12

      Where

      L = minimum length of spiral (ft)

      R = curve radius (ft)

      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

      Maximum Length of Spiral

      L = (24pmaxR)12

      Where

      L = maximum length of spiral (ft)

      R = curve radius (ft)

      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

      Length of Spiralo AASHTO also provides recommended spiral lengths

      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

      o Design Note For construction purposes round your designs to a reasonable values eg

      Ls = 147 feet round it to

      Ls = 150 feet

      Source Iowa DOT Design Manual

      SPIRAL TERMINOLOGY

      Source Iowa DOT Design Manual

      Source Iowa DOT Design Manual

      Source Iowa DOT Design Manual

      Attainment of Superelevationon spiral curves

      See sketches that follow

      Normal Crown (DOT ndash pt A)

      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

      4 Fully superelevate remainder of curve and then reverse the process at the CS

      65Source Iowa DOT Standard Road Plans RP-2

      With Spirals

      Same as point E of GB

      With Spirals

      Tangent runout (A to B)

      With Spirals

      Removal of crown

      With Spirals

      Transition of superelevation

      Full superelevation

      69

      • Slide 1
      • Geometric Design ndash Basic Principles
      • GEOMETRIC DESIGN ndash Course Heads
      • Slide 4
      • Curves
      • Horizontal Curves
      • Design Elements
      • Slide 8
      • Slide 9
      • Slide 10
      • Slide 11
      • Horizontal Curves
      • Slide 13
      • Slide 14
      • Slide 15
      • Slide 16
      • Slide 17
      • Slide 18
      • Horizontal Curve Sight Distance
      • Slide 20
      • Slide 21
      • Slide 22
      • Slide 23
      • Slide 24
      • Slide 25
      • TRANSITIONS Superelevation Spiral Curves
      • Superelevation
      • Image
      • Superelevation Transitioning
      • Slide 30
      • Attainment of Superelevation - General
      • Tangent Runout Section
      • Superelevation Runoff Section
      • Slide 34
      • Slide 35
      • Slide 36
      • Slide 37
      • Slide 38
      • Slide 39
      • Slide 40
      • Slide 41
      • Attainment Location - WHERE
      • Minimum Length of Runoff for curve
      • Minimum Length of Tangent Runout
      • Length of Superelevation Runoff
      • Relative Gradient (G)
      • Maximum Relative Gradient (G)
      • Multilane Adjustment
      • Length of Superelevation Runoff Example
      • Slide 50
      • Tangent runout length Example continued
      • Slide 52
      • Spiral Curve Transitions
      • Slide 54
      • Spirals
      • Minimum Length of Spiral
      • Slide 57
      • Maximum Length of Spiral
      • Length of Spiral
      • Slide 60
      • Slide 61
      • Slide 62
      • Slide 63
      • Attainment of Superelevation on spiral curves
      • Slide 65
      • Slide 66
      • Slide 67
      • Slide 68
      • Slide 69

        500

        1000

        1500

        2000

        2500

        3000

        3500

        4000

        4500

        3-D Model

        Curves Straight segments are called Tangents Horizontal curves help change from one

        tangent to another

        Horizontal Curves MAXIMUM CENTERLINE DEFLECTION

        NOT REQUIRING HORIZONTAL CURVE

        Design Speed mph Maximum Deflection

        25 5deg30

        30 3deg45

        35 2deg45

        40 2deg15

        45 1deg15

        50 1deg15

        55 1deg00

        60 1deg00

        65 0deg45

        70 0deg45

        Source Ohio DOT Design Manual Figure 202-1E

        Design Elements Curves

        Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

        Transitions

        Curves Horizontal curves are circular to minimize steering

        effort Curves need to be long enough to avoid unsafe or

        uncomfortable conditions

        Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

        transition from an infinite radius (a tangent) to the radius of the circular curve

        Design Elements Design Questions

        Which one to be used where and how What should be the minimum radius

        bull without Transitionbull with Transition

        With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

        Curves Simple Circular

        Curves Compound Curves

        Horizontal Curves

        Horizontal Curves

        Horizontal Curves

        Horizontal Curves

        Horizontal Curves

        Horizontal Curves

        Horizontal Curves

        Horizontal Curve Sight Distance

        Horizontal Curve Sight Distance

        Curves Minimum Radius

        Rmin = ____V2____

        15 (e + f) where Rmin is the minimum radius in feet

        V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

        Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

        and graphed in Green Book) and design speed

        bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

        bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

        bull f decreases as speed increases (less tire pavement contact)

        Curves Max e is controlled by 4 factors

        bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

        influenced by high super elevation rates Max e

        bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

        bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

        bull For consistency use a single rate within a project or on a highway

        Curves

        Curves

        TRANSITIONSTRANSITIONS

        SuperelevationSuperelevationSpiral CurvesSpiral Curves

        TRANSITIONSTRANSITIONS

        SuperelevationSuperelevationSpiral CurvesSpiral Curves

        Superelevation

        Image

        httptechalivemtuedumodulesmodule0003Superelevationhtm

        Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

        design may help avoid roadside obstacles that might otherwise be impacted by the alignment

        In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

        Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

        Superelevation Although superelevation is advantageous for traffic

        operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

        Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

        Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

        Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

        Attainment of Superelevation - General

        bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

        bull Change in pavement slope should be consistent over a distance

        Tangent Runout Section Superelevation Runoff Section bull Methods

        bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

        Tangent Runout Section

        Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

        For rotation about centerline

        Superelevation Runoff Section

        Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

        For undivided highways with cross-section rotated about centerline

        Superelevation Transitioning The development of superelevation on a horizontal curve requires a

        transition from a normal crown section which is accomplished by rotating the pavement

        The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

        Cross section (-a-) is the normal crown section where the transitioning begins

        Cross section (-b-) is reached by rotating half the pavement until it is level

        Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

        Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

        Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

        Superelevation Transitioning Rotation about the centerline profile of traveled way

        This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

        Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

        Superelevation Transitioning Rotation about the outside-edge profile of traveled way

        This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

        Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

        The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

        39

        40

        Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

        Same as point E of GB

        Attainment Location - WHERE

        Superelevation must be attained over a length that includes the tangent and the curve

        Typical 66 on tangent and 33 on curve of length of runoff if no spiral

        Super runoff is all attained in Spiral if used

        Minimum Length of Runoff for curve

        Lr based on drainage and aesthetics

        rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

        current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

        Minimum Length of Tangent Runout

        Lt = eNC x Lr

        ed

        where

        eNC = normal cross slope rate ()

        ed = design superelevation rate

        Lr = minimum length of superelevation runoff (ft)

        (Result is the edge slope is same as for Runoff segment)

        Length of Superelevation Runoff

        α = multilane adjustment factor adjusts for total width

        r

        Relative Gradient (G)

        Maximum longitudinal slope Depends on design speed higher speed =

        gentler slope

        For example For 15 mph G = 078 For 80 mph G = 035 See table next page

        Maximum Relative Gradient (G)

        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

        Multilane Adjustment

        Runout and runoff must be adjusted for multilane rotation

        See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

        Length of Superelevation Runoff Example

        For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

        Lr = 12eα

        G

        50

        Lr = 12eα = (12) (004) (15)

        G 05

        Lr = 144 feet

        Tangent runout length Example continued

        Lt = (eNC ed ) x Lr

        as defined previously if NC = 2

        Tangent runout for the example is

        LT = 2 4 144rsquo = 72 feet

        52

        From previous example speed = 50 mph e = 4

        From chart runoff = 144 feet same as from calculation

        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

        Spiral Curve Transitions Vehicles follow a transition path as they enter or

        leave a horizontal curve

        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

        Spirals Advantages

        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

        Provides location for superelevation runoff (not part on tangentcurve)

        Provides transition in width when horizontal curve is widened

        Aesthetic

        Minimum Length of Spiral

        Possible Equations

        Larger of (1) L = 315 V3

        RC

        Where

        L = minimum length of spiral (ft)

        V = speed (mph)

        R = curve radius (ft)

        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

        Minimum Length of Spiral

        Or (2) L = (24pminR)12

        Where

        L = minimum length of spiral (ft)

        R = curve radius (ft)

        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

        Maximum Length of Spiral

        L = (24pmaxR)12

        Where

        L = maximum length of spiral (ft)

        R = curve radius (ft)

        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

        Length of Spiralo AASHTO also provides recommended spiral lengths

        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

        o Design Note For construction purposes round your designs to a reasonable values eg

        Ls = 147 feet round it to

        Ls = 150 feet

        Source Iowa DOT Design Manual

        SPIRAL TERMINOLOGY

        Source Iowa DOT Design Manual

        Source Iowa DOT Design Manual

        Source Iowa DOT Design Manual

        Attainment of Superelevationon spiral curves

        See sketches that follow

        Normal Crown (DOT ndash pt A)

        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

        4 Fully superelevate remainder of curve and then reverse the process at the CS

        65Source Iowa DOT Standard Road Plans RP-2

        With Spirals

        Same as point E of GB

        With Spirals

        Tangent runout (A to B)

        With Spirals

        Removal of crown

        With Spirals

        Transition of superelevation

        Full superelevation

        69

        • Slide 1
        • Geometric Design ndash Basic Principles
        • GEOMETRIC DESIGN ndash Course Heads
        • Slide 4
        • Curves
        • Horizontal Curves
        • Design Elements
        • Slide 8
        • Slide 9
        • Slide 10
        • Slide 11
        • Horizontal Curves
        • Slide 13
        • Slide 14
        • Slide 15
        • Slide 16
        • Slide 17
        • Slide 18
        • Horizontal Curve Sight Distance
        • Slide 20
        • Slide 21
        • Slide 22
        • Slide 23
        • Slide 24
        • Slide 25
        • TRANSITIONS Superelevation Spiral Curves
        • Superelevation
        • Image
        • Superelevation Transitioning
        • Slide 30
        • Attainment of Superelevation - General
        • Tangent Runout Section
        • Superelevation Runoff Section
        • Slide 34
        • Slide 35
        • Slide 36
        • Slide 37
        • Slide 38
        • Slide 39
        • Slide 40
        • Slide 41
        • Attainment Location - WHERE
        • Minimum Length of Runoff for curve
        • Minimum Length of Tangent Runout
        • Length of Superelevation Runoff
        • Relative Gradient (G)
        • Maximum Relative Gradient (G)
        • Multilane Adjustment
        • Length of Superelevation Runoff Example
        • Slide 50
        • Tangent runout length Example continued
        • Slide 52
        • Spiral Curve Transitions
        • Slide 54
        • Spirals
        • Minimum Length of Spiral
        • Slide 57
        • Maximum Length of Spiral
        • Length of Spiral
        • Slide 60
        • Slide 61
        • Slide 62
        • Slide 63
        • Attainment of Superelevation on spiral curves
        • Slide 65
        • Slide 66
        • Slide 67
        • Slide 68
        • Slide 69

          Curves Straight segments are called Tangents Horizontal curves help change from one

          tangent to another

          Horizontal Curves MAXIMUM CENTERLINE DEFLECTION

          NOT REQUIRING HORIZONTAL CURVE

          Design Speed mph Maximum Deflection

          25 5deg30

          30 3deg45

          35 2deg45

          40 2deg15

          45 1deg15

          50 1deg15

          55 1deg00

          60 1deg00

          65 0deg45

          70 0deg45

          Source Ohio DOT Design Manual Figure 202-1E

          Design Elements Curves

          Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

          Transitions

          Curves Horizontal curves are circular to minimize steering

          effort Curves need to be long enough to avoid unsafe or

          uncomfortable conditions

          Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

          transition from an infinite radius (a tangent) to the radius of the circular curve

          Design Elements Design Questions

          Which one to be used where and how What should be the minimum radius

          bull without Transitionbull with Transition

          With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

          Curves Simple Circular

          Curves Compound Curves

          Horizontal Curves

          Horizontal Curves

          Horizontal Curves

          Horizontal Curves

          Horizontal Curves

          Horizontal Curves

          Horizontal Curves

          Horizontal Curve Sight Distance

          Horizontal Curve Sight Distance

          Curves Minimum Radius

          Rmin = ____V2____

          15 (e + f) where Rmin is the minimum radius in feet

          V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

          Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

          and graphed in Green Book) and design speed

          bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

          bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

          bull f decreases as speed increases (less tire pavement contact)

          Curves Max e is controlled by 4 factors

          bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

          influenced by high super elevation rates Max e

          bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

          bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

          bull For consistency use a single rate within a project or on a highway

          Curves

          Curves

          TRANSITIONSTRANSITIONS

          SuperelevationSuperelevationSpiral CurvesSpiral Curves

          TRANSITIONSTRANSITIONS

          SuperelevationSuperelevationSpiral CurvesSpiral Curves

          Superelevation

          Image

          httptechalivemtuedumodulesmodule0003Superelevationhtm

          Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

          design may help avoid roadside obstacles that might otherwise be impacted by the alignment

          In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

          Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

          Superelevation Although superelevation is advantageous for traffic

          operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

          Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

          Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

          Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

          Attainment of Superelevation - General

          bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

          bull Change in pavement slope should be consistent over a distance

          Tangent Runout Section Superelevation Runoff Section bull Methods

          bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

          Tangent Runout Section

          Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

          For rotation about centerline

          Superelevation Runoff Section

          Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

          For undivided highways with cross-section rotated about centerline

          Superelevation Transitioning The development of superelevation on a horizontal curve requires a

          transition from a normal crown section which is accomplished by rotating the pavement

          The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

          Cross section (-a-) is the normal crown section where the transitioning begins

          Cross section (-b-) is reached by rotating half the pavement until it is level

          Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

          Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

          Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

          Superelevation Transitioning Rotation about the centerline profile of traveled way

          This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

          Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

          Superelevation Transitioning Rotation about the outside-edge profile of traveled way

          This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

          Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

          The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

          39

          40

          Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

          Same as point E of GB

          Attainment Location - WHERE

          Superelevation must be attained over a length that includes the tangent and the curve

          Typical 66 on tangent and 33 on curve of length of runoff if no spiral

          Super runoff is all attained in Spiral if used

          Minimum Length of Runoff for curve

          Lr based on drainage and aesthetics

          rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

          current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

          Minimum Length of Tangent Runout

          Lt = eNC x Lr

          ed

          where

          eNC = normal cross slope rate ()

          ed = design superelevation rate

          Lr = minimum length of superelevation runoff (ft)

          (Result is the edge slope is same as for Runoff segment)

          Length of Superelevation Runoff

          α = multilane adjustment factor adjusts for total width

          r

          Relative Gradient (G)

          Maximum longitudinal slope Depends on design speed higher speed =

          gentler slope

          For example For 15 mph G = 078 For 80 mph G = 035 See table next page

          Maximum Relative Gradient (G)

          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

          Multilane Adjustment

          Runout and runoff must be adjusted for multilane rotation

          See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

          Length of Superelevation Runoff Example

          For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

          Lr = 12eα

          G

          50

          Lr = 12eα = (12) (004) (15)

          G 05

          Lr = 144 feet

          Tangent runout length Example continued

          Lt = (eNC ed ) x Lr

          as defined previously if NC = 2

          Tangent runout for the example is

          LT = 2 4 144rsquo = 72 feet

          52

          From previous example speed = 50 mph e = 4

          From chart runoff = 144 feet same as from calculation

          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

          Spiral Curve Transitions Vehicles follow a transition path as they enter or

          leave a horizontal curve

          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

          Spirals Advantages

          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

          Provides location for superelevation runoff (not part on tangentcurve)

          Provides transition in width when horizontal curve is widened

          Aesthetic

          Minimum Length of Spiral

          Possible Equations

          Larger of (1) L = 315 V3

          RC

          Where

          L = minimum length of spiral (ft)

          V = speed (mph)

          R = curve radius (ft)

          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

          Minimum Length of Spiral

          Or (2) L = (24pminR)12

          Where

          L = minimum length of spiral (ft)

          R = curve radius (ft)

          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

          Maximum Length of Spiral

          L = (24pmaxR)12

          Where

          L = maximum length of spiral (ft)

          R = curve radius (ft)

          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

          Length of Spiralo AASHTO also provides recommended spiral lengths

          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

          o Design Note For construction purposes round your designs to a reasonable values eg

          Ls = 147 feet round it to

          Ls = 150 feet

          Source Iowa DOT Design Manual

          SPIRAL TERMINOLOGY

          Source Iowa DOT Design Manual

          Source Iowa DOT Design Manual

          Source Iowa DOT Design Manual

          Attainment of Superelevationon spiral curves

          See sketches that follow

          Normal Crown (DOT ndash pt A)

          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

          4 Fully superelevate remainder of curve and then reverse the process at the CS

          65Source Iowa DOT Standard Road Plans RP-2

          With Spirals

          Same as point E of GB

          With Spirals

          Tangent runout (A to B)

          With Spirals

          Removal of crown

          With Spirals

          Transition of superelevation

          Full superelevation

          69

          • Slide 1
          • Geometric Design ndash Basic Principles
          • GEOMETRIC DESIGN ndash Course Heads
          • Slide 4
          • Curves
          • Horizontal Curves
          • Design Elements
          • Slide 8
          • Slide 9
          • Slide 10
          • Slide 11
          • Horizontal Curves
          • Slide 13
          • Slide 14
          • Slide 15
          • Slide 16
          • Slide 17
          • Slide 18
          • Horizontal Curve Sight Distance
          • Slide 20
          • Slide 21
          • Slide 22
          • Slide 23
          • Slide 24
          • Slide 25
          • TRANSITIONS Superelevation Spiral Curves
          • Superelevation
          • Image
          • Superelevation Transitioning
          • Slide 30
          • Attainment of Superelevation - General
          • Tangent Runout Section
          • Superelevation Runoff Section
          • Slide 34
          • Slide 35
          • Slide 36
          • Slide 37
          • Slide 38
          • Slide 39
          • Slide 40
          • Slide 41
          • Attainment Location - WHERE
          • Minimum Length of Runoff for curve
          • Minimum Length of Tangent Runout
          • Length of Superelevation Runoff
          • Relative Gradient (G)
          • Maximum Relative Gradient (G)
          • Multilane Adjustment
          • Length of Superelevation Runoff Example
          • Slide 50
          • Tangent runout length Example continued
          • Slide 52
          • Spiral Curve Transitions
          • Slide 54
          • Spirals
          • Minimum Length of Spiral
          • Slide 57
          • Maximum Length of Spiral
          • Length of Spiral
          • Slide 60
          • Slide 61
          • Slide 62
          • Slide 63
          • Attainment of Superelevation on spiral curves
          • Slide 65
          • Slide 66
          • Slide 67
          • Slide 68
          • Slide 69

            Horizontal Curves MAXIMUM CENTERLINE DEFLECTION

            NOT REQUIRING HORIZONTAL CURVE

            Design Speed mph Maximum Deflection

            25 5deg30

            30 3deg45

            35 2deg45

            40 2deg15

            45 1deg15

            50 1deg15

            55 1deg00

            60 1deg00

            65 0deg45

            70 0deg45

            Source Ohio DOT Design Manual Figure 202-1E

            Design Elements Curves

            Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

            Transitions

            Curves Horizontal curves are circular to minimize steering

            effort Curves need to be long enough to avoid unsafe or

            uncomfortable conditions

            Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

            transition from an infinite radius (a tangent) to the radius of the circular curve

            Design Elements Design Questions

            Which one to be used where and how What should be the minimum radius

            bull without Transitionbull with Transition

            With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

            Curves Simple Circular

            Curves Compound Curves

            Horizontal Curves

            Horizontal Curves

            Horizontal Curves

            Horizontal Curves

            Horizontal Curves

            Horizontal Curves

            Horizontal Curves

            Horizontal Curve Sight Distance

            Horizontal Curve Sight Distance

            Curves Minimum Radius

            Rmin = ____V2____

            15 (e + f) where Rmin is the minimum radius in feet

            V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

            Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

            and graphed in Green Book) and design speed

            bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

            bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

            bull f decreases as speed increases (less tire pavement contact)

            Curves Max e is controlled by 4 factors

            bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

            influenced by high super elevation rates Max e

            bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

            bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

            bull For consistency use a single rate within a project or on a highway

            Curves

            Curves

            TRANSITIONSTRANSITIONS

            SuperelevationSuperelevationSpiral CurvesSpiral Curves

            TRANSITIONSTRANSITIONS

            SuperelevationSuperelevationSpiral CurvesSpiral Curves

            Superelevation

            Image

            httptechalivemtuedumodulesmodule0003Superelevationhtm

            Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

            design may help avoid roadside obstacles that might otherwise be impacted by the alignment

            In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

            Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

            Superelevation Although superelevation is advantageous for traffic

            operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

            Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

            Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

            Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

            Attainment of Superelevation - General

            bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

            bull Change in pavement slope should be consistent over a distance

            Tangent Runout Section Superelevation Runoff Section bull Methods

            bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

            Tangent Runout Section

            Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

            For rotation about centerline

            Superelevation Runoff Section

            Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

            For undivided highways with cross-section rotated about centerline

            Superelevation Transitioning The development of superelevation on a horizontal curve requires a

            transition from a normal crown section which is accomplished by rotating the pavement

            The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

            Cross section (-a-) is the normal crown section where the transitioning begins

            Cross section (-b-) is reached by rotating half the pavement until it is level

            Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

            Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

            Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

            Superelevation Transitioning Rotation about the centerline profile of traveled way

            This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

            Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

            Superelevation Transitioning Rotation about the outside-edge profile of traveled way

            This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

            Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

            The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

            39

            40

            Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

            Same as point E of GB

            Attainment Location - WHERE

            Superelevation must be attained over a length that includes the tangent and the curve

            Typical 66 on tangent and 33 on curve of length of runoff if no spiral

            Super runoff is all attained in Spiral if used

            Minimum Length of Runoff for curve

            Lr based on drainage and aesthetics

            rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

            current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

            Minimum Length of Tangent Runout

            Lt = eNC x Lr

            ed

            where

            eNC = normal cross slope rate ()

            ed = design superelevation rate

            Lr = minimum length of superelevation runoff (ft)

            (Result is the edge slope is same as for Runoff segment)

            Length of Superelevation Runoff

            α = multilane adjustment factor adjusts for total width

            r

            Relative Gradient (G)

            Maximum longitudinal slope Depends on design speed higher speed =

            gentler slope

            For example For 15 mph G = 078 For 80 mph G = 035 See table next page

            Maximum Relative Gradient (G)

            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

            Multilane Adjustment

            Runout and runoff must be adjusted for multilane rotation

            See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

            Length of Superelevation Runoff Example

            For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

            Lr = 12eα

            G

            50

            Lr = 12eα = (12) (004) (15)

            G 05

            Lr = 144 feet

            Tangent runout length Example continued

            Lt = (eNC ed ) x Lr

            as defined previously if NC = 2

            Tangent runout for the example is

            LT = 2 4 144rsquo = 72 feet

            52

            From previous example speed = 50 mph e = 4

            From chart runoff = 144 feet same as from calculation

            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

            Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

            Spiral Curve Transitions Vehicles follow a transition path as they enter or

            leave a horizontal curve

            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

            Spirals Advantages

            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

            Provides location for superelevation runoff (not part on tangentcurve)

            Provides transition in width when horizontal curve is widened

            Aesthetic

            Minimum Length of Spiral

            Possible Equations

            Larger of (1) L = 315 V3

            RC

            Where

            L = minimum length of spiral (ft)

            V = speed (mph)

            R = curve radius (ft)

            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

            Minimum Length of Spiral

            Or (2) L = (24pminR)12

            Where

            L = minimum length of spiral (ft)

            R = curve radius (ft)

            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

            Maximum Length of Spiral

            L = (24pmaxR)12

            Where

            L = maximum length of spiral (ft)

            R = curve radius (ft)

            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

            Length of Spiralo AASHTO also provides recommended spiral lengths

            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

            o Design Note For construction purposes round your designs to a reasonable values eg

            Ls = 147 feet round it to

            Ls = 150 feet

            Source Iowa DOT Design Manual

            SPIRAL TERMINOLOGY

            Source Iowa DOT Design Manual

            Source Iowa DOT Design Manual

            Source Iowa DOT Design Manual

            Attainment of Superelevationon spiral curves

            See sketches that follow

            Normal Crown (DOT ndash pt A)

            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

            4 Fully superelevate remainder of curve and then reverse the process at the CS

            65Source Iowa DOT Standard Road Plans RP-2

            With Spirals

            Same as point E of GB

            With Spirals

            Tangent runout (A to B)

            With Spirals

            Removal of crown

            With Spirals

            Transition of superelevation

            Full superelevation

            69

            • Slide 1
            • Geometric Design ndash Basic Principles
            • GEOMETRIC DESIGN ndash Course Heads
            • Slide 4
            • Curves
            • Horizontal Curves
            • Design Elements
            • Slide 8
            • Slide 9
            • Slide 10
            • Slide 11
            • Horizontal Curves
            • Slide 13
            • Slide 14
            • Slide 15
            • Slide 16
            • Slide 17
            • Slide 18
            • Horizontal Curve Sight Distance
            • Slide 20
            • Slide 21
            • Slide 22
            • Slide 23
            • Slide 24
            • Slide 25
            • TRANSITIONS Superelevation Spiral Curves
            • Superelevation
            • Image
            • Superelevation Transitioning
            • Slide 30
            • Attainment of Superelevation - General
            • Tangent Runout Section
            • Superelevation Runoff Section
            • Slide 34
            • Slide 35
            • Slide 36
            • Slide 37
            • Slide 38
            • Slide 39
            • Slide 40
            • Slide 41
            • Attainment Location - WHERE
            • Minimum Length of Runoff for curve
            • Minimum Length of Tangent Runout
            • Length of Superelevation Runoff
            • Relative Gradient (G)
            • Maximum Relative Gradient (G)
            • Multilane Adjustment
            • Length of Superelevation Runoff Example
            • Slide 50
            • Tangent runout length Example continued
            • Slide 52
            • Spiral Curve Transitions
            • Slide 54
            • Spirals
            • Minimum Length of Spiral
            • Slide 57
            • Maximum Length of Spiral
            • Length of Spiral
            • Slide 60
            • Slide 61
            • Slide 62
            • Slide 63
            • Attainment of Superelevation on spiral curves
            • Slide 65
            • Slide 66
            • Slide 67
            • Slide 68
            • Slide 69

              Design Elements Curves

              Simple Circular Curvesbull Compound Curvesbull Broken Back Curvesbull S or Reverse Curves

              Transitions

              Curves Horizontal curves are circular to minimize steering

              effort Curves need to be long enough to avoid unsafe or

              uncomfortable conditions

              Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

              transition from an infinite radius (a tangent) to the radius of the circular curve

              Design Elements Design Questions

              Which one to be used where and how What should be the minimum radius

              bull without Transitionbull with Transition

              With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

              Curves Simple Circular

              Curves Compound Curves

              Horizontal Curves

              Horizontal Curves

              Horizontal Curves

              Horizontal Curves

              Horizontal Curves

              Horizontal Curves

              Horizontal Curves

              Horizontal Curve Sight Distance

              Horizontal Curve Sight Distance

              Curves Minimum Radius

              Rmin = ____V2____

              15 (e + f) where Rmin is the minimum radius in feet

              V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

              Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

              and graphed in Green Book) and design speed

              bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

              bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

              bull f decreases as speed increases (less tire pavement contact)

              Curves Max e is controlled by 4 factors

              bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

              influenced by high super elevation rates Max e

              bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

              bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

              bull For consistency use a single rate within a project or on a highway

              Curves

              Curves

              TRANSITIONSTRANSITIONS

              SuperelevationSuperelevationSpiral CurvesSpiral Curves

              TRANSITIONSTRANSITIONS

              SuperelevationSuperelevationSpiral CurvesSpiral Curves

              Superelevation

              Image

              httptechalivemtuedumodulesmodule0003Superelevationhtm

              Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

              design may help avoid roadside obstacles that might otherwise be impacted by the alignment

              In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

              Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

              Superelevation Although superelevation is advantageous for traffic

              operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

              Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

              Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

              Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

              Attainment of Superelevation - General

              bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

              bull Change in pavement slope should be consistent over a distance

              Tangent Runout Section Superelevation Runoff Section bull Methods

              bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

              Tangent Runout Section

              Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

              For rotation about centerline

              Superelevation Runoff Section

              Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

              For undivided highways with cross-section rotated about centerline

              Superelevation Transitioning The development of superelevation on a horizontal curve requires a

              transition from a normal crown section which is accomplished by rotating the pavement

              The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

              Cross section (-a-) is the normal crown section where the transitioning begins

              Cross section (-b-) is reached by rotating half the pavement until it is level

              Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

              Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

              Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

              Superelevation Transitioning Rotation about the centerline profile of traveled way

              This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

              Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

              Superelevation Transitioning Rotation about the outside-edge profile of traveled way

              This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

              Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

              The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

              39

              40

              Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

              Same as point E of GB

              Attainment Location - WHERE

              Superelevation must be attained over a length that includes the tangent and the curve

              Typical 66 on tangent and 33 on curve of length of runoff if no spiral

              Super runoff is all attained in Spiral if used

              Minimum Length of Runoff for curve

              Lr based on drainage and aesthetics

              rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

              current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

              Minimum Length of Tangent Runout

              Lt = eNC x Lr

              ed

              where

              eNC = normal cross slope rate ()

              ed = design superelevation rate

              Lr = minimum length of superelevation runoff (ft)

              (Result is the edge slope is same as for Runoff segment)

              Length of Superelevation Runoff

              α = multilane adjustment factor adjusts for total width

              r

              Relative Gradient (G)

              Maximum longitudinal slope Depends on design speed higher speed =

              gentler slope

              For example For 15 mph G = 078 For 80 mph G = 035 See table next page

              Maximum Relative Gradient (G)

              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

              Multilane Adjustment

              Runout and runoff must be adjusted for multilane rotation

              See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

              Length of Superelevation Runoff Example

              For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

              Lr = 12eα

              G

              50

              Lr = 12eα = (12) (004) (15)

              G 05

              Lr = 144 feet

              Tangent runout length Example continued

              Lt = (eNC ed ) x Lr

              as defined previously if NC = 2

              Tangent runout for the example is

              LT = 2 4 144rsquo = 72 feet

              52

              From previous example speed = 50 mph e = 4

              From chart runoff = 144 feet same as from calculation

              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

              Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

              Spiral Curve Transitions Vehicles follow a transition path as they enter or

              leave a horizontal curve

              Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

              Spirals Advantages

              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

              Provides location for superelevation runoff (not part on tangentcurve)

              Provides transition in width when horizontal curve is widened

              Aesthetic

              Minimum Length of Spiral

              Possible Equations

              Larger of (1) L = 315 V3

              RC

              Where

              L = minimum length of spiral (ft)

              V = speed (mph)

              R = curve radius (ft)

              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

              Minimum Length of Spiral

              Or (2) L = (24pminR)12

              Where

              L = minimum length of spiral (ft)

              R = curve radius (ft)

              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

              Maximum Length of Spiral

              L = (24pmaxR)12

              Where

              L = maximum length of spiral (ft)

              R = curve radius (ft)

              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

              Length of Spiralo AASHTO also provides recommended spiral lengths

              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

              o Design Note For construction purposes round your designs to a reasonable values eg

              Ls = 147 feet round it to

              Ls = 150 feet

              Source Iowa DOT Design Manual

              SPIRAL TERMINOLOGY

              Source Iowa DOT Design Manual

              Source Iowa DOT Design Manual

              Source Iowa DOT Design Manual

              Attainment of Superelevationon spiral curves

              See sketches that follow

              Normal Crown (DOT ndash pt A)

              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

              4 Fully superelevate remainder of curve and then reverse the process at the CS

              65Source Iowa DOT Standard Road Plans RP-2

              With Spirals

              Same as point E of GB

              With Spirals

              Tangent runout (A to B)

              With Spirals

              Removal of crown

              With Spirals

              Transition of superelevation

              Full superelevation

              69

              • Slide 1
              • Geometric Design ndash Basic Principles
              • GEOMETRIC DESIGN ndash Course Heads
              • Slide 4
              • Curves
              • Horizontal Curves
              • Design Elements
              • Slide 8
              • Slide 9
              • Slide 10
              • Slide 11
              • Horizontal Curves
              • Slide 13
              • Slide 14
              • Slide 15
              • Slide 16
              • Slide 17
              • Slide 18
              • Horizontal Curve Sight Distance
              • Slide 20
              • Slide 21
              • Slide 22
              • Slide 23
              • Slide 24
              • Slide 25
              • TRANSITIONS Superelevation Spiral Curves
              • Superelevation
              • Image
              • Superelevation Transitioning
              • Slide 30
              • Attainment of Superelevation - General
              • Tangent Runout Section
              • Superelevation Runoff Section
              • Slide 34
              • Slide 35
              • Slide 36
              • Slide 37
              • Slide 38
              • Slide 39
              • Slide 40
              • Slide 41
              • Attainment Location - WHERE
              • Minimum Length of Runoff for curve
              • Minimum Length of Tangent Runout
              • Length of Superelevation Runoff
              • Relative Gradient (G)
              • Maximum Relative Gradient (G)
              • Multilane Adjustment
              • Length of Superelevation Runoff Example
              • Slide 50
              • Tangent runout length Example continued
              • Slide 52
              • Spiral Curve Transitions
              • Slide 54
              • Spirals
              • Minimum Length of Spiral
              • Slide 57
              • Maximum Length of Spiral
              • Length of Spiral
              • Slide 60
              • Slide 61
              • Slide 62
              • Slide 63
              • Attainment of Superelevation on spiral curves
              • Slide 65
              • Slide 66
              • Slide 67
              • Slide 68
              • Slide 69

                Curves Horizontal curves are circular to minimize steering

                effort Curves need to be long enough to avoid unsafe or

                uncomfortable conditions

                Additional features can help reduce the driving effortbull Super Elevationbull Transition (or spiral) curves which slowly

                transition from an infinite radius (a tangent) to the radius of the circular curve

                Design Elements Design Questions

                Which one to be used where and how What should be the minimum radius

                bull without Transitionbull with Transition

                With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

                Curves Simple Circular

                Curves Compound Curves

                Horizontal Curves

                Horizontal Curves

                Horizontal Curves

                Horizontal Curves

                Horizontal Curves

                Horizontal Curves

                Horizontal Curves

                Horizontal Curve Sight Distance

                Horizontal Curve Sight Distance

                Curves Minimum Radius

                Rmin = ____V2____

                15 (e + f) where Rmin is the minimum radius in feet

                V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                and graphed in Green Book) and design speed

                bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                bull f decreases as speed increases (less tire pavement contact)

                Curves Max e is controlled by 4 factors

                bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                influenced by high super elevation rates Max e

                bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                bull For consistency use a single rate within a project or on a highway

                Curves

                Curves

                TRANSITIONSTRANSITIONS

                SuperelevationSuperelevationSpiral CurvesSpiral Curves

                TRANSITIONSTRANSITIONS

                SuperelevationSuperelevationSpiral CurvesSpiral Curves

                Superelevation

                Image

                httptechalivemtuedumodulesmodule0003Superelevationhtm

                Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                Superelevation Although superelevation is advantageous for traffic

                operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                Attainment of Superelevation - General

                bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                bull Change in pavement slope should be consistent over a distance

                Tangent Runout Section Superelevation Runoff Section bull Methods

                bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                Tangent Runout Section

                Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                For rotation about centerline

                Superelevation Runoff Section

                Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                For undivided highways with cross-section rotated about centerline

                Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                transition from a normal crown section which is accomplished by rotating the pavement

                The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                Cross section (-a-) is the normal crown section where the transitioning begins

                Cross section (-b-) is reached by rotating half the pavement until it is level

                Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                Superelevation Transitioning Rotation about the centerline profile of traveled way

                This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                39

                40

                Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                Same as point E of GB

                Attainment Location - WHERE

                Superelevation must be attained over a length that includes the tangent and the curve

                Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                Super runoff is all attained in Spiral if used

                Minimum Length of Runoff for curve

                Lr based on drainage and aesthetics

                rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                Minimum Length of Tangent Runout

                Lt = eNC x Lr

                ed

                where

                eNC = normal cross slope rate ()

                ed = design superelevation rate

                Lr = minimum length of superelevation runoff (ft)

                (Result is the edge slope is same as for Runoff segment)

                Length of Superelevation Runoff

                α = multilane adjustment factor adjusts for total width

                r

                Relative Gradient (G)

                Maximum longitudinal slope Depends on design speed higher speed =

                gentler slope

                For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                Maximum Relative Gradient (G)

                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                Multilane Adjustment

                Runout and runoff must be adjusted for multilane rotation

                See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                Length of Superelevation Runoff Example

                For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                Lr = 12eα

                G

                50

                Lr = 12eα = (12) (004) (15)

                G 05

                Lr = 144 feet

                Tangent runout length Example continued

                Lt = (eNC ed ) x Lr

                as defined previously if NC = 2

                Tangent runout for the example is

                LT = 2 4 144rsquo = 72 feet

                52

                From previous example speed = 50 mph e = 4

                From chart runoff = 144 feet same as from calculation

                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                Spiral Curve Transitions Vehicles follow a transition path as they enter or

                leave a horizontal curve

                Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                Spirals Advantages

                Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                Provides location for superelevation runoff (not part on tangentcurve)

                Provides transition in width when horizontal curve is widened

                Aesthetic

                Minimum Length of Spiral

                Possible Equations

                Larger of (1) L = 315 V3

                RC

                Where

                L = minimum length of spiral (ft)

                V = speed (mph)

                R = curve radius (ft)

                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                Minimum Length of Spiral

                Or (2) L = (24pminR)12

                Where

                L = minimum length of spiral (ft)

                R = curve radius (ft)

                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                Maximum Length of Spiral

                L = (24pmaxR)12

                Where

                L = maximum length of spiral (ft)

                R = curve radius (ft)

                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                Length of Spiralo AASHTO also provides recommended spiral lengths

                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                o Design Note For construction purposes round your designs to a reasonable values eg

                Ls = 147 feet round it to

                Ls = 150 feet

                Source Iowa DOT Design Manual

                SPIRAL TERMINOLOGY

                Source Iowa DOT Design Manual

                Source Iowa DOT Design Manual

                Source Iowa DOT Design Manual

                Attainment of Superelevationon spiral curves

                See sketches that follow

                Normal Crown (DOT ndash pt A)

                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                4 Fully superelevate remainder of curve and then reverse the process at the CS

                65Source Iowa DOT Standard Road Plans RP-2

                With Spirals

                Same as point E of GB

                With Spirals

                Tangent runout (A to B)

                With Spirals

                Removal of crown

                With Spirals

                Transition of superelevation

                Full superelevation

                69

                • Slide 1
                • Geometric Design ndash Basic Principles
                • GEOMETRIC DESIGN ndash Course Heads
                • Slide 4
                • Curves
                • Horizontal Curves
                • Design Elements
                • Slide 8
                • Slide 9
                • Slide 10
                • Slide 11
                • Horizontal Curves
                • Slide 13
                • Slide 14
                • Slide 15
                • Slide 16
                • Slide 17
                • Slide 18
                • Horizontal Curve Sight Distance
                • Slide 20
                • Slide 21
                • Slide 22
                • Slide 23
                • Slide 24
                • Slide 25
                • TRANSITIONS Superelevation Spiral Curves
                • Superelevation
                • Image
                • Superelevation Transitioning
                • Slide 30
                • Attainment of Superelevation - General
                • Tangent Runout Section
                • Superelevation Runoff Section
                • Slide 34
                • Slide 35
                • Slide 36
                • Slide 37
                • Slide 38
                • Slide 39
                • Slide 40
                • Slide 41
                • Attainment Location - WHERE
                • Minimum Length of Runoff for curve
                • Minimum Length of Tangent Runout
                • Length of Superelevation Runoff
                • Relative Gradient (G)
                • Maximum Relative Gradient (G)
                • Multilane Adjustment
                • Length of Superelevation Runoff Example
                • Slide 50
                • Tangent runout length Example continued
                • Slide 52
                • Spiral Curve Transitions
                • Slide 54
                • Spirals
                • Minimum Length of Spiral
                • Slide 57
                • Maximum Length of Spiral
                • Length of Spiral
                • Slide 60
                • Slide 61
                • Slide 62
                • Slide 63
                • Attainment of Superelevation on spiral curves
                • Slide 65
                • Slide 66
                • Slide 67
                • Slide 68
                • Slide 69

                  Design Elements Design Questions

                  Which one to be used where and how What should be the minimum radius

                  bull without Transitionbull with Transition

                  With minimum design radius what should bebull Type of Transitionbull Length of Transitionbull Components of Transition

                  Curves Simple Circular

                  Curves Compound Curves

                  Horizontal Curves

                  Horizontal Curves

                  Horizontal Curves

                  Horizontal Curves

                  Horizontal Curves

                  Horizontal Curves

                  Horizontal Curves

                  Horizontal Curve Sight Distance

                  Horizontal Curve Sight Distance

                  Curves Minimum Radius

                  Rmin = ____V2____

                  15 (e + f) where Rmin is the minimum radius in feet

                  V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                  Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                  and graphed in Green Book) and design speed

                  bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                  bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                  bull f decreases as speed increases (less tire pavement contact)

                  Curves Max e is controlled by 4 factors

                  bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                  influenced by high super elevation rates Max e

                  bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                  bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                  bull For consistency use a single rate within a project or on a highway

                  Curves

                  Curves

                  TRANSITIONSTRANSITIONS

                  SuperelevationSuperelevationSpiral CurvesSpiral Curves

                  TRANSITIONSTRANSITIONS

                  SuperelevationSuperelevationSpiral CurvesSpiral Curves

                  Superelevation

                  Image

                  httptechalivemtuedumodulesmodule0003Superelevationhtm

                  Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                  design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                  In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                  Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                  Superelevation Although superelevation is advantageous for traffic

                  operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                  Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                  Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                  Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                  Attainment of Superelevation - General

                  bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                  bull Change in pavement slope should be consistent over a distance

                  Tangent Runout Section Superelevation Runoff Section bull Methods

                  bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                  Tangent Runout Section

                  Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                  For rotation about centerline

                  Superelevation Runoff Section

                  Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                  For undivided highways with cross-section rotated about centerline

                  Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                  transition from a normal crown section which is accomplished by rotating the pavement

                  The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                  Cross section (-a-) is the normal crown section where the transitioning begins

                  Cross section (-b-) is reached by rotating half the pavement until it is level

                  Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                  Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                  Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                  Superelevation Transitioning Rotation about the centerline profile of traveled way

                  This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                  Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                  Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                  This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                  Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                  The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                  39

                  40

                  Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                  Same as point E of GB

                  Attainment Location - WHERE

                  Superelevation must be attained over a length that includes the tangent and the curve

                  Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                  Super runoff is all attained in Spiral if used

                  Minimum Length of Runoff for curve

                  Lr based on drainage and aesthetics

                  rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                  current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                  Minimum Length of Tangent Runout

                  Lt = eNC x Lr

                  ed

                  where

                  eNC = normal cross slope rate ()

                  ed = design superelevation rate

                  Lr = minimum length of superelevation runoff (ft)

                  (Result is the edge slope is same as for Runoff segment)

                  Length of Superelevation Runoff

                  α = multilane adjustment factor adjusts for total width

                  r

                  Relative Gradient (G)

                  Maximum longitudinal slope Depends on design speed higher speed =

                  gentler slope

                  For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                  Maximum Relative Gradient (G)

                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                  Multilane Adjustment

                  Runout and runoff must be adjusted for multilane rotation

                  See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                  Length of Superelevation Runoff Example

                  For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                  Lr = 12eα

                  G

                  50

                  Lr = 12eα = (12) (004) (15)

                  G 05

                  Lr = 144 feet

                  Tangent runout length Example continued

                  Lt = (eNC ed ) x Lr

                  as defined previously if NC = 2

                  Tangent runout for the example is

                  LT = 2 4 144rsquo = 72 feet

                  52

                  From previous example speed = 50 mph e = 4

                  From chart runoff = 144 feet same as from calculation

                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                  Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                  Spiral Curve Transitions Vehicles follow a transition path as they enter or

                  leave a horizontal curve

                  Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                  Spirals Advantages

                  Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                  Provides location for superelevation runoff (not part on tangentcurve)

                  Provides transition in width when horizontal curve is widened

                  Aesthetic

                  Minimum Length of Spiral

                  Possible Equations

                  Larger of (1) L = 315 V3

                  RC

                  Where

                  L = minimum length of spiral (ft)

                  V = speed (mph)

                  R = curve radius (ft)

                  C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                  Minimum Length of Spiral

                  Or (2) L = (24pminR)12

                  Where

                  L = minimum length of spiral (ft)

                  R = curve radius (ft)

                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                  Maximum Length of Spiral

                  L = (24pmaxR)12

                  Where

                  L = maximum length of spiral (ft)

                  R = curve radius (ft)

                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                  Length of Spiralo AASHTO also provides recommended spiral lengths

                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                  o Design Note For construction purposes round your designs to a reasonable values eg

                  Ls = 147 feet round it to

                  Ls = 150 feet

                  Source Iowa DOT Design Manual

                  SPIRAL TERMINOLOGY

                  Source Iowa DOT Design Manual

                  Source Iowa DOT Design Manual

                  Source Iowa DOT Design Manual

                  Attainment of Superelevationon spiral curves

                  See sketches that follow

                  Normal Crown (DOT ndash pt A)

                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                  65Source Iowa DOT Standard Road Plans RP-2

                  With Spirals

                  Same as point E of GB

                  With Spirals

                  Tangent runout (A to B)

                  With Spirals

                  Removal of crown

                  With Spirals

                  Transition of superelevation

                  Full superelevation

                  69

                  • Slide 1
                  • Geometric Design ndash Basic Principles
                  • GEOMETRIC DESIGN ndash Course Heads
                  • Slide 4
                  • Curves
                  • Horizontal Curves
                  • Design Elements
                  • Slide 8
                  • Slide 9
                  • Slide 10
                  • Slide 11
                  • Horizontal Curves
                  • Slide 13
                  • Slide 14
                  • Slide 15
                  • Slide 16
                  • Slide 17
                  • Slide 18
                  • Horizontal Curve Sight Distance
                  • Slide 20
                  • Slide 21
                  • Slide 22
                  • Slide 23
                  • Slide 24
                  • Slide 25
                  • TRANSITIONS Superelevation Spiral Curves
                  • Superelevation
                  • Image
                  • Superelevation Transitioning
                  • Slide 30
                  • Attainment of Superelevation - General
                  • Tangent Runout Section
                  • Superelevation Runoff Section
                  • Slide 34
                  • Slide 35
                  • Slide 36
                  • Slide 37
                  • Slide 38
                  • Slide 39
                  • Slide 40
                  • Slide 41
                  • Attainment Location - WHERE
                  • Minimum Length of Runoff for curve
                  • Minimum Length of Tangent Runout
                  • Length of Superelevation Runoff
                  • Relative Gradient (G)
                  • Maximum Relative Gradient (G)
                  • Multilane Adjustment
                  • Length of Superelevation Runoff Example
                  • Slide 50
                  • Tangent runout length Example continued
                  • Slide 52
                  • Spiral Curve Transitions
                  • Slide 54
                  • Spirals
                  • Minimum Length of Spiral
                  • Slide 57
                  • Maximum Length of Spiral
                  • Length of Spiral
                  • Slide 60
                  • Slide 61
                  • Slide 62
                  • Slide 63
                  • Attainment of Superelevation on spiral curves
                  • Slide 65
                  • Slide 66
                  • Slide 67
                  • Slide 68
                  • Slide 69

                    Curves Simple Circular

                    Curves Compound Curves

                    Horizontal Curves

                    Horizontal Curves

                    Horizontal Curves

                    Horizontal Curves

                    Horizontal Curves

                    Horizontal Curves

                    Horizontal Curves

                    Horizontal Curve Sight Distance

                    Horizontal Curve Sight Distance

                    Curves Minimum Radius

                    Rmin = ____V2____

                    15 (e + f) where Rmin is the minimum radius in feet

                    V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                    Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                    and graphed in Green Book) and design speed

                    bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                    bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                    bull f decreases as speed increases (less tire pavement contact)

                    Curves Max e is controlled by 4 factors

                    bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                    influenced by high super elevation rates Max e

                    bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                    bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                    bull For consistency use a single rate within a project or on a highway

                    Curves

                    Curves

                    TRANSITIONSTRANSITIONS

                    SuperelevationSuperelevationSpiral CurvesSpiral Curves

                    TRANSITIONSTRANSITIONS

                    SuperelevationSuperelevationSpiral CurvesSpiral Curves

                    Superelevation

                    Image

                    httptechalivemtuedumodulesmodule0003Superelevationhtm

                    Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                    design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                    In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                    Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                    Superelevation Although superelevation is advantageous for traffic

                    operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                    Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                    Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                    Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                    Attainment of Superelevation - General

                    bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                    bull Change in pavement slope should be consistent over a distance

                    Tangent Runout Section Superelevation Runoff Section bull Methods

                    bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                    Tangent Runout Section

                    Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                    For rotation about centerline

                    Superelevation Runoff Section

                    Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                    For undivided highways with cross-section rotated about centerline

                    Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                    transition from a normal crown section which is accomplished by rotating the pavement

                    The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                    Cross section (-a-) is the normal crown section where the transitioning begins

                    Cross section (-b-) is reached by rotating half the pavement until it is level

                    Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                    Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                    Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                    Superelevation Transitioning Rotation about the centerline profile of traveled way

                    This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                    Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                    Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                    This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                    Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                    The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                    39

                    40

                    Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                    Same as point E of GB

                    Attainment Location - WHERE

                    Superelevation must be attained over a length that includes the tangent and the curve

                    Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                    Super runoff is all attained in Spiral if used

                    Minimum Length of Runoff for curve

                    Lr based on drainage and aesthetics

                    rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                    current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                    Minimum Length of Tangent Runout

                    Lt = eNC x Lr

                    ed

                    where

                    eNC = normal cross slope rate ()

                    ed = design superelevation rate

                    Lr = minimum length of superelevation runoff (ft)

                    (Result is the edge slope is same as for Runoff segment)

                    Length of Superelevation Runoff

                    α = multilane adjustment factor adjusts for total width

                    r

                    Relative Gradient (G)

                    Maximum longitudinal slope Depends on design speed higher speed =

                    gentler slope

                    For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                    Maximum Relative Gradient (G)

                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                    Multilane Adjustment

                    Runout and runoff must be adjusted for multilane rotation

                    See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                    Length of Superelevation Runoff Example

                    For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                    Lr = 12eα

                    G

                    50

                    Lr = 12eα = (12) (004) (15)

                    G 05

                    Lr = 144 feet

                    Tangent runout length Example continued

                    Lt = (eNC ed ) x Lr

                    as defined previously if NC = 2

                    Tangent runout for the example is

                    LT = 2 4 144rsquo = 72 feet

                    52

                    From previous example speed = 50 mph e = 4

                    From chart runoff = 144 feet same as from calculation

                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                    Spiral Curve Transitions Vehicles follow a transition path as they enter or

                    leave a horizontal curve

                    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                    Spirals Advantages

                    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                    Provides location for superelevation runoff (not part on tangentcurve)

                    Provides transition in width when horizontal curve is widened

                    Aesthetic

                    Minimum Length of Spiral

                    Possible Equations

                    Larger of (1) L = 315 V3

                    RC

                    Where

                    L = minimum length of spiral (ft)

                    V = speed (mph)

                    R = curve radius (ft)

                    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                    Minimum Length of Spiral

                    Or (2) L = (24pminR)12

                    Where

                    L = minimum length of spiral (ft)

                    R = curve radius (ft)

                    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                    Maximum Length of Spiral

                    L = (24pmaxR)12

                    Where

                    L = maximum length of spiral (ft)

                    R = curve radius (ft)

                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                    Length of Spiralo AASHTO also provides recommended spiral lengths

                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                    o Design Note For construction purposes round your designs to a reasonable values eg

                    Ls = 147 feet round it to

                    Ls = 150 feet

                    Source Iowa DOT Design Manual

                    SPIRAL TERMINOLOGY

                    Source Iowa DOT Design Manual

                    Source Iowa DOT Design Manual

                    Source Iowa DOT Design Manual

                    Attainment of Superelevationon spiral curves

                    See sketches that follow

                    Normal Crown (DOT ndash pt A)

                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                    65Source Iowa DOT Standard Road Plans RP-2

                    With Spirals

                    Same as point E of GB

                    With Spirals

                    Tangent runout (A to B)

                    With Spirals

                    Removal of crown

                    With Spirals

                    Transition of superelevation

                    Full superelevation

                    69

                    • Slide 1
                    • Geometric Design ndash Basic Principles
                    • GEOMETRIC DESIGN ndash Course Heads
                    • Slide 4
                    • Curves
                    • Horizontal Curves
                    • Design Elements
                    • Slide 8
                    • Slide 9
                    • Slide 10
                    • Slide 11
                    • Horizontal Curves
                    • Slide 13
                    • Slide 14
                    • Slide 15
                    • Slide 16
                    • Slide 17
                    • Slide 18
                    • Horizontal Curve Sight Distance
                    • Slide 20
                    • Slide 21
                    • Slide 22
                    • Slide 23
                    • Slide 24
                    • Slide 25
                    • TRANSITIONS Superelevation Spiral Curves
                    • Superelevation
                    • Image
                    • Superelevation Transitioning
                    • Slide 30
                    • Attainment of Superelevation - General
                    • Tangent Runout Section
                    • Superelevation Runoff Section
                    • Slide 34
                    • Slide 35
                    • Slide 36
                    • Slide 37
                    • Slide 38
                    • Slide 39
                    • Slide 40
                    • Slide 41
                    • Attainment Location - WHERE
                    • Minimum Length of Runoff for curve
                    • Minimum Length of Tangent Runout
                    • Length of Superelevation Runoff
                    • Relative Gradient (G)
                    • Maximum Relative Gradient (G)
                    • Multilane Adjustment
                    • Length of Superelevation Runoff Example
                    • Slide 50
                    • Tangent runout length Example continued
                    • Slide 52
                    • Spiral Curve Transitions
                    • Slide 54
                    • Spirals
                    • Minimum Length of Spiral
                    • Slide 57
                    • Maximum Length of Spiral
                    • Length of Spiral
                    • Slide 60
                    • Slide 61
                    • Slide 62
                    • Slide 63
                    • Attainment of Superelevation on spiral curves
                    • Slide 65
                    • Slide 66
                    • Slide 67
                    • Slide 68
                    • Slide 69

                      Curves Compound Curves

                      Horizontal Curves

                      Horizontal Curves

                      Horizontal Curves

                      Horizontal Curves

                      Horizontal Curves

                      Horizontal Curves

                      Horizontal Curves

                      Horizontal Curve Sight Distance

                      Horizontal Curve Sight Distance

                      Curves Minimum Radius

                      Rmin = ____V2____

                      15 (e + f) where Rmin is the minimum radius in feet

                      V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                      Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                      and graphed in Green Book) and design speed

                      bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                      bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                      bull f decreases as speed increases (less tire pavement contact)

                      Curves Max e is controlled by 4 factors

                      bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                      influenced by high super elevation rates Max e

                      bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                      bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                      bull For consistency use a single rate within a project or on a highway

                      Curves

                      Curves

                      TRANSITIONSTRANSITIONS

                      SuperelevationSuperelevationSpiral CurvesSpiral Curves

                      TRANSITIONSTRANSITIONS

                      SuperelevationSuperelevationSpiral CurvesSpiral Curves

                      Superelevation

                      Image

                      httptechalivemtuedumodulesmodule0003Superelevationhtm

                      Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                      design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                      In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                      Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                      Superelevation Although superelevation is advantageous for traffic

                      operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                      Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                      Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                      Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                      Attainment of Superelevation - General

                      bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                      bull Change in pavement slope should be consistent over a distance

                      Tangent Runout Section Superelevation Runoff Section bull Methods

                      bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                      Tangent Runout Section

                      Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                      For rotation about centerline

                      Superelevation Runoff Section

                      Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                      For undivided highways with cross-section rotated about centerline

                      Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                      transition from a normal crown section which is accomplished by rotating the pavement

                      The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                      Cross section (-a-) is the normal crown section where the transitioning begins

                      Cross section (-b-) is reached by rotating half the pavement until it is level

                      Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                      Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                      Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                      Superelevation Transitioning Rotation about the centerline profile of traveled way

                      This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                      Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                      Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                      This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                      Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                      The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                      39

                      40

                      Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                      Same as point E of GB

                      Attainment Location - WHERE

                      Superelevation must be attained over a length that includes the tangent and the curve

                      Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                      Super runoff is all attained in Spiral if used

                      Minimum Length of Runoff for curve

                      Lr based on drainage and aesthetics

                      rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                      current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                      Minimum Length of Tangent Runout

                      Lt = eNC x Lr

                      ed

                      where

                      eNC = normal cross slope rate ()

                      ed = design superelevation rate

                      Lr = minimum length of superelevation runoff (ft)

                      (Result is the edge slope is same as for Runoff segment)

                      Length of Superelevation Runoff

                      α = multilane adjustment factor adjusts for total width

                      r

                      Relative Gradient (G)

                      Maximum longitudinal slope Depends on design speed higher speed =

                      gentler slope

                      For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                      Maximum Relative Gradient (G)

                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                      Multilane Adjustment

                      Runout and runoff must be adjusted for multilane rotation

                      See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                      Length of Superelevation Runoff Example

                      For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                      Lr = 12eα

                      G

                      50

                      Lr = 12eα = (12) (004) (15)

                      G 05

                      Lr = 144 feet

                      Tangent runout length Example continued

                      Lt = (eNC ed ) x Lr

                      as defined previously if NC = 2

                      Tangent runout for the example is

                      LT = 2 4 144rsquo = 72 feet

                      52

                      From previous example speed = 50 mph e = 4

                      From chart runoff = 144 feet same as from calculation

                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                      Spiral Curve Transitions Vehicles follow a transition path as they enter or

                      leave a horizontal curve

                      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                      Spirals Advantages

                      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                      Provides location for superelevation runoff (not part on tangentcurve)

                      Provides transition in width when horizontal curve is widened

                      Aesthetic

                      Minimum Length of Spiral

                      Possible Equations

                      Larger of (1) L = 315 V3

                      RC

                      Where

                      L = minimum length of spiral (ft)

                      V = speed (mph)

                      R = curve radius (ft)

                      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                      Minimum Length of Spiral

                      Or (2) L = (24pminR)12

                      Where

                      L = minimum length of spiral (ft)

                      R = curve radius (ft)

                      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                      Maximum Length of Spiral

                      L = (24pmaxR)12

                      Where

                      L = maximum length of spiral (ft)

                      R = curve radius (ft)

                      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                      Length of Spiralo AASHTO also provides recommended spiral lengths

                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                      o Design Note For construction purposes round your designs to a reasonable values eg

                      Ls = 147 feet round it to

                      Ls = 150 feet

                      Source Iowa DOT Design Manual

                      SPIRAL TERMINOLOGY

                      Source Iowa DOT Design Manual

                      Source Iowa DOT Design Manual

                      Source Iowa DOT Design Manual

                      Attainment of Superelevationon spiral curves

                      See sketches that follow

                      Normal Crown (DOT ndash pt A)

                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                      65Source Iowa DOT Standard Road Plans RP-2

                      With Spirals

                      Same as point E of GB

                      With Spirals

                      Tangent runout (A to B)

                      With Spirals

                      Removal of crown

                      With Spirals

                      Transition of superelevation

                      Full superelevation

                      69

                      • Slide 1
                      • Geometric Design ndash Basic Principles
                      • GEOMETRIC DESIGN ndash Course Heads
                      • Slide 4
                      • Curves
                      • Horizontal Curves
                      • Design Elements
                      • Slide 8
                      • Slide 9
                      • Slide 10
                      • Slide 11
                      • Horizontal Curves
                      • Slide 13
                      • Slide 14
                      • Slide 15
                      • Slide 16
                      • Slide 17
                      • Slide 18
                      • Horizontal Curve Sight Distance
                      • Slide 20
                      • Slide 21
                      • Slide 22
                      • Slide 23
                      • Slide 24
                      • Slide 25
                      • TRANSITIONS Superelevation Spiral Curves
                      • Superelevation
                      • Image
                      • Superelevation Transitioning
                      • Slide 30
                      • Attainment of Superelevation - General
                      • Tangent Runout Section
                      • Superelevation Runoff Section
                      • Slide 34
                      • Slide 35
                      • Slide 36
                      • Slide 37
                      • Slide 38
                      • Slide 39
                      • Slide 40
                      • Slide 41
                      • Attainment Location - WHERE
                      • Minimum Length of Runoff for curve
                      • Minimum Length of Tangent Runout
                      • Length of Superelevation Runoff
                      • Relative Gradient (G)
                      • Maximum Relative Gradient (G)
                      • Multilane Adjustment
                      • Length of Superelevation Runoff Example
                      • Slide 50
                      • Tangent runout length Example continued
                      • Slide 52
                      • Spiral Curve Transitions
                      • Slide 54
                      • Spirals
                      • Minimum Length of Spiral
                      • Slide 57
                      • Maximum Length of Spiral
                      • Length of Spiral
                      • Slide 60
                      • Slide 61
                      • Slide 62
                      • Slide 63
                      • Attainment of Superelevation on spiral curves
                      • Slide 65
                      • Slide 66
                      • Slide 67
                      • Slide 68
                      • Slide 69

                        Horizontal Curves

                        Horizontal Curves

                        Horizontal Curves

                        Horizontal Curves

                        Horizontal Curves

                        Horizontal Curves

                        Horizontal Curves

                        Horizontal Curve Sight Distance

                        Horizontal Curve Sight Distance

                        Curves Minimum Radius

                        Rmin = ____V2____

                        15 (e + f) where Rmin is the minimum radius in feet

                        V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                        Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                        and graphed in Green Book) and design speed

                        bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                        bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                        bull f decreases as speed increases (less tire pavement contact)

                        Curves Max e is controlled by 4 factors

                        bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                        influenced by high super elevation rates Max e

                        bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                        bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                        bull For consistency use a single rate within a project or on a highway

                        Curves

                        Curves

                        TRANSITIONSTRANSITIONS

                        SuperelevationSuperelevationSpiral CurvesSpiral Curves

                        TRANSITIONSTRANSITIONS

                        SuperelevationSuperelevationSpiral CurvesSpiral Curves

                        Superelevation

                        Image

                        httptechalivemtuedumodulesmodule0003Superelevationhtm

                        Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                        design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                        In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                        Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                        Superelevation Although superelevation is advantageous for traffic

                        operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                        Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                        Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                        Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                        Attainment of Superelevation - General

                        bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                        bull Change in pavement slope should be consistent over a distance

                        Tangent Runout Section Superelevation Runoff Section bull Methods

                        bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                        Tangent Runout Section

                        Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                        For rotation about centerline

                        Superelevation Runoff Section

                        Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                        For undivided highways with cross-section rotated about centerline

                        Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                        transition from a normal crown section which is accomplished by rotating the pavement

                        The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                        Cross section (-a-) is the normal crown section where the transitioning begins

                        Cross section (-b-) is reached by rotating half the pavement until it is level

                        Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                        Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                        Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                        Superelevation Transitioning Rotation about the centerline profile of traveled way

                        This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                        Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                        Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                        This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                        Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                        The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                        39

                        40

                        Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                        Same as point E of GB

                        Attainment Location - WHERE

                        Superelevation must be attained over a length that includes the tangent and the curve

                        Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                        Super runoff is all attained in Spiral if used

                        Minimum Length of Runoff for curve

                        Lr based on drainage and aesthetics

                        rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                        current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                        Minimum Length of Tangent Runout

                        Lt = eNC x Lr

                        ed

                        where

                        eNC = normal cross slope rate ()

                        ed = design superelevation rate

                        Lr = minimum length of superelevation runoff (ft)

                        (Result is the edge slope is same as for Runoff segment)

                        Length of Superelevation Runoff

                        α = multilane adjustment factor adjusts for total width

                        r

                        Relative Gradient (G)

                        Maximum longitudinal slope Depends on design speed higher speed =

                        gentler slope

                        For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                        Maximum Relative Gradient (G)

                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                        Multilane Adjustment

                        Runout and runoff must be adjusted for multilane rotation

                        See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                        Length of Superelevation Runoff Example

                        For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                        Lr = 12eα

                        G

                        50

                        Lr = 12eα = (12) (004) (15)

                        G 05

                        Lr = 144 feet

                        Tangent runout length Example continued

                        Lt = (eNC ed ) x Lr

                        as defined previously if NC = 2

                        Tangent runout for the example is

                        LT = 2 4 144rsquo = 72 feet

                        52

                        From previous example speed = 50 mph e = 4

                        From chart runoff = 144 feet same as from calculation

                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                        Spiral Curve Transitions Vehicles follow a transition path as they enter or

                        leave a horizontal curve

                        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                        Spirals Advantages

                        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                        Provides location for superelevation runoff (not part on tangentcurve)

                        Provides transition in width when horizontal curve is widened

                        Aesthetic

                        Minimum Length of Spiral

                        Possible Equations

                        Larger of (1) L = 315 V3

                        RC

                        Where

                        L = minimum length of spiral (ft)

                        V = speed (mph)

                        R = curve radius (ft)

                        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                        Minimum Length of Spiral

                        Or (2) L = (24pminR)12

                        Where

                        L = minimum length of spiral (ft)

                        R = curve radius (ft)

                        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                        Maximum Length of Spiral

                        L = (24pmaxR)12

                        Where

                        L = maximum length of spiral (ft)

                        R = curve radius (ft)

                        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                        Length of Spiralo AASHTO also provides recommended spiral lengths

                        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                        o Design Note For construction purposes round your designs to a reasonable values eg

                        Ls = 147 feet round it to

                        Ls = 150 feet

                        Source Iowa DOT Design Manual

                        SPIRAL TERMINOLOGY

                        Source Iowa DOT Design Manual

                        Source Iowa DOT Design Manual

                        Source Iowa DOT Design Manual

                        Attainment of Superelevationon spiral curves

                        See sketches that follow

                        Normal Crown (DOT ndash pt A)

                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                        65Source Iowa DOT Standard Road Plans RP-2

                        With Spirals

                        Same as point E of GB

                        With Spirals

                        Tangent runout (A to B)

                        With Spirals

                        Removal of crown

                        With Spirals

                        Transition of superelevation

                        Full superelevation

                        69

                        • Slide 1
                        • Geometric Design ndash Basic Principles
                        • GEOMETRIC DESIGN ndash Course Heads
                        • Slide 4
                        • Curves
                        • Horizontal Curves
                        • Design Elements
                        • Slide 8
                        • Slide 9
                        • Slide 10
                        • Slide 11
                        • Horizontal Curves
                        • Slide 13
                        • Slide 14
                        • Slide 15
                        • Slide 16
                        • Slide 17
                        • Slide 18
                        • Horizontal Curve Sight Distance
                        • Slide 20
                        • Slide 21
                        • Slide 22
                        • Slide 23
                        • Slide 24
                        • Slide 25
                        • TRANSITIONS Superelevation Spiral Curves
                        • Superelevation
                        • Image
                        • Superelevation Transitioning
                        • Slide 30
                        • Attainment of Superelevation - General
                        • Tangent Runout Section
                        • Superelevation Runoff Section
                        • Slide 34
                        • Slide 35
                        • Slide 36
                        • Slide 37
                        • Slide 38
                        • Slide 39
                        • Slide 40
                        • Slide 41
                        • Attainment Location - WHERE
                        • Minimum Length of Runoff for curve
                        • Minimum Length of Tangent Runout
                        • Length of Superelevation Runoff
                        • Relative Gradient (G)
                        • Maximum Relative Gradient (G)
                        • Multilane Adjustment
                        • Length of Superelevation Runoff Example
                        • Slide 50
                        • Tangent runout length Example continued
                        • Slide 52
                        • Spiral Curve Transitions
                        • Slide 54
                        • Spirals
                        • Minimum Length of Spiral
                        • Slide 57
                        • Maximum Length of Spiral
                        • Length of Spiral
                        • Slide 60
                        • Slide 61
                        • Slide 62
                        • Slide 63
                        • Attainment of Superelevation on spiral curves
                        • Slide 65
                        • Slide 66
                        • Slide 67
                        • Slide 68
                        • Slide 69

                          Horizontal Curves

                          Horizontal Curves

                          Horizontal Curves

                          Horizontal Curves

                          Horizontal Curves

                          Horizontal Curves

                          Horizontal Curve Sight Distance

                          Horizontal Curve Sight Distance

                          Curves Minimum Radius

                          Rmin = ____V2____

                          15 (e + f) where Rmin is the minimum radius in feet

                          V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                          Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                          and graphed in Green Book) and design speed

                          bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                          bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                          bull f decreases as speed increases (less tire pavement contact)

                          Curves Max e is controlled by 4 factors

                          bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                          influenced by high super elevation rates Max e

                          bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                          bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                          bull For consistency use a single rate within a project or on a highway

                          Curves

                          Curves

                          TRANSITIONSTRANSITIONS

                          SuperelevationSuperelevationSpiral CurvesSpiral Curves

                          TRANSITIONSTRANSITIONS

                          SuperelevationSuperelevationSpiral CurvesSpiral Curves

                          Superelevation

                          Image

                          httptechalivemtuedumodulesmodule0003Superelevationhtm

                          Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                          design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                          In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                          Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                          Superelevation Although superelevation is advantageous for traffic

                          operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                          Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                          Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                          Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                          Attainment of Superelevation - General

                          bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                          bull Change in pavement slope should be consistent over a distance

                          Tangent Runout Section Superelevation Runoff Section bull Methods

                          bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                          Tangent Runout Section

                          Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                          For rotation about centerline

                          Superelevation Runoff Section

                          Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                          For undivided highways with cross-section rotated about centerline

                          Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                          transition from a normal crown section which is accomplished by rotating the pavement

                          The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                          Cross section (-a-) is the normal crown section where the transitioning begins

                          Cross section (-b-) is reached by rotating half the pavement until it is level

                          Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                          Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                          Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                          Superelevation Transitioning Rotation about the centerline profile of traveled way

                          This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                          Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                          Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                          This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                          Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                          The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                          39

                          40

                          Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                          Same as point E of GB

                          Attainment Location - WHERE

                          Superelevation must be attained over a length that includes the tangent and the curve

                          Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                          Super runoff is all attained in Spiral if used

                          Minimum Length of Runoff for curve

                          Lr based on drainage and aesthetics

                          rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                          current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                          Minimum Length of Tangent Runout

                          Lt = eNC x Lr

                          ed

                          where

                          eNC = normal cross slope rate ()

                          ed = design superelevation rate

                          Lr = minimum length of superelevation runoff (ft)

                          (Result is the edge slope is same as for Runoff segment)

                          Length of Superelevation Runoff

                          α = multilane adjustment factor adjusts for total width

                          r

                          Relative Gradient (G)

                          Maximum longitudinal slope Depends on design speed higher speed =

                          gentler slope

                          For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                          Maximum Relative Gradient (G)

                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                          Multilane Adjustment

                          Runout and runoff must be adjusted for multilane rotation

                          See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                          Length of Superelevation Runoff Example

                          For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                          Lr = 12eα

                          G

                          50

                          Lr = 12eα = (12) (004) (15)

                          G 05

                          Lr = 144 feet

                          Tangent runout length Example continued

                          Lt = (eNC ed ) x Lr

                          as defined previously if NC = 2

                          Tangent runout for the example is

                          LT = 2 4 144rsquo = 72 feet

                          52

                          From previous example speed = 50 mph e = 4

                          From chart runoff = 144 feet same as from calculation

                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                          Spiral Curve Transitions Vehicles follow a transition path as they enter or

                          leave a horizontal curve

                          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                          Spirals Advantages

                          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                          Provides location for superelevation runoff (not part on tangentcurve)

                          Provides transition in width when horizontal curve is widened

                          Aesthetic

                          Minimum Length of Spiral

                          Possible Equations

                          Larger of (1) L = 315 V3

                          RC

                          Where

                          L = minimum length of spiral (ft)

                          V = speed (mph)

                          R = curve radius (ft)

                          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                          Minimum Length of Spiral

                          Or (2) L = (24pminR)12

                          Where

                          L = minimum length of spiral (ft)

                          R = curve radius (ft)

                          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                          Maximum Length of Spiral

                          L = (24pmaxR)12

                          Where

                          L = maximum length of spiral (ft)

                          R = curve radius (ft)

                          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                          Length of Spiralo AASHTO also provides recommended spiral lengths

                          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                          o Design Note For construction purposes round your designs to a reasonable values eg

                          Ls = 147 feet round it to

                          Ls = 150 feet

                          Source Iowa DOT Design Manual

                          SPIRAL TERMINOLOGY

                          Source Iowa DOT Design Manual

                          Source Iowa DOT Design Manual

                          Source Iowa DOT Design Manual

                          Attainment of Superelevationon spiral curves

                          See sketches that follow

                          Normal Crown (DOT ndash pt A)

                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                          65Source Iowa DOT Standard Road Plans RP-2

                          With Spirals

                          Same as point E of GB

                          With Spirals

                          Tangent runout (A to B)

                          With Spirals

                          Removal of crown

                          With Spirals

                          Transition of superelevation

                          Full superelevation

                          69

                          • Slide 1
                          • Geometric Design ndash Basic Principles
                          • GEOMETRIC DESIGN ndash Course Heads
                          • Slide 4
                          • Curves
                          • Horizontal Curves
                          • Design Elements
                          • Slide 8
                          • Slide 9
                          • Slide 10
                          • Slide 11
                          • Horizontal Curves
                          • Slide 13
                          • Slide 14
                          • Slide 15
                          • Slide 16
                          • Slide 17
                          • Slide 18
                          • Horizontal Curve Sight Distance
                          • Slide 20
                          • Slide 21
                          • Slide 22
                          • Slide 23
                          • Slide 24
                          • Slide 25
                          • TRANSITIONS Superelevation Spiral Curves
                          • Superelevation
                          • Image
                          • Superelevation Transitioning
                          • Slide 30
                          • Attainment of Superelevation - General
                          • Tangent Runout Section
                          • Superelevation Runoff Section
                          • Slide 34
                          • Slide 35
                          • Slide 36
                          • Slide 37
                          • Slide 38
                          • Slide 39
                          • Slide 40
                          • Slide 41
                          • Attainment Location - WHERE
                          • Minimum Length of Runoff for curve
                          • Minimum Length of Tangent Runout
                          • Length of Superelevation Runoff
                          • Relative Gradient (G)
                          • Maximum Relative Gradient (G)
                          • Multilane Adjustment
                          • Length of Superelevation Runoff Example
                          • Slide 50
                          • Tangent runout length Example continued
                          • Slide 52
                          • Spiral Curve Transitions
                          • Slide 54
                          • Spirals
                          • Minimum Length of Spiral
                          • Slide 57
                          • Maximum Length of Spiral
                          • Length of Spiral
                          • Slide 60
                          • Slide 61
                          • Slide 62
                          • Slide 63
                          • Attainment of Superelevation on spiral curves
                          • Slide 65
                          • Slide 66
                          • Slide 67
                          • Slide 68
                          • Slide 69

                            Horizontal Curves

                            Horizontal Curves

                            Horizontal Curves

                            Horizontal Curves

                            Horizontal Curves

                            Horizontal Curve Sight Distance

                            Horizontal Curve Sight Distance

                            Curves Minimum Radius

                            Rmin = ____V2____

                            15 (e + f) where Rmin is the minimum radius in feet

                            V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                            Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                            and graphed in Green Book) and design speed

                            bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                            bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                            bull f decreases as speed increases (less tire pavement contact)

                            Curves Max e is controlled by 4 factors

                            bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                            influenced by high super elevation rates Max e

                            bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                            bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                            bull For consistency use a single rate within a project or on a highway

                            Curves

                            Curves

                            TRANSITIONSTRANSITIONS

                            SuperelevationSuperelevationSpiral CurvesSpiral Curves

                            TRANSITIONSTRANSITIONS

                            SuperelevationSuperelevationSpiral CurvesSpiral Curves

                            Superelevation

                            Image

                            httptechalivemtuedumodulesmodule0003Superelevationhtm

                            Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                            design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                            In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                            Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                            Superelevation Although superelevation is advantageous for traffic

                            operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                            Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                            Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                            Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                            Attainment of Superelevation - General

                            bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                            bull Change in pavement slope should be consistent over a distance

                            Tangent Runout Section Superelevation Runoff Section bull Methods

                            bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                            Tangent Runout Section

                            Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                            For rotation about centerline

                            Superelevation Runoff Section

                            Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                            For undivided highways with cross-section rotated about centerline

                            Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                            transition from a normal crown section which is accomplished by rotating the pavement

                            The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                            Cross section (-a-) is the normal crown section where the transitioning begins

                            Cross section (-b-) is reached by rotating half the pavement until it is level

                            Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                            Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                            Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                            Superelevation Transitioning Rotation about the centerline profile of traveled way

                            This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                            Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                            Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                            This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                            Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                            The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                            39

                            40

                            Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                            Same as point E of GB

                            Attainment Location - WHERE

                            Superelevation must be attained over a length that includes the tangent and the curve

                            Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                            Super runoff is all attained in Spiral if used

                            Minimum Length of Runoff for curve

                            Lr based on drainage and aesthetics

                            rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                            current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                            Minimum Length of Tangent Runout

                            Lt = eNC x Lr

                            ed

                            where

                            eNC = normal cross slope rate ()

                            ed = design superelevation rate

                            Lr = minimum length of superelevation runoff (ft)

                            (Result is the edge slope is same as for Runoff segment)

                            Length of Superelevation Runoff

                            α = multilane adjustment factor adjusts for total width

                            r

                            Relative Gradient (G)

                            Maximum longitudinal slope Depends on design speed higher speed =

                            gentler slope

                            For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                            Maximum Relative Gradient (G)

                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                            Multilane Adjustment

                            Runout and runoff must be adjusted for multilane rotation

                            See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                            Length of Superelevation Runoff Example

                            For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                            Lr = 12eα

                            G

                            50

                            Lr = 12eα = (12) (004) (15)

                            G 05

                            Lr = 144 feet

                            Tangent runout length Example continued

                            Lt = (eNC ed ) x Lr

                            as defined previously if NC = 2

                            Tangent runout for the example is

                            LT = 2 4 144rsquo = 72 feet

                            52

                            From previous example speed = 50 mph e = 4

                            From chart runoff = 144 feet same as from calculation

                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                            Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                            Spiral Curve Transitions Vehicles follow a transition path as they enter or

                            leave a horizontal curve

                            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                            Spirals Advantages

                            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                            Provides location for superelevation runoff (not part on tangentcurve)

                            Provides transition in width when horizontal curve is widened

                            Aesthetic

                            Minimum Length of Spiral

                            Possible Equations

                            Larger of (1) L = 315 V3

                            RC

                            Where

                            L = minimum length of spiral (ft)

                            V = speed (mph)

                            R = curve radius (ft)

                            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                            Minimum Length of Spiral

                            Or (2) L = (24pminR)12

                            Where

                            L = minimum length of spiral (ft)

                            R = curve radius (ft)

                            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                            Maximum Length of Spiral

                            L = (24pmaxR)12

                            Where

                            L = maximum length of spiral (ft)

                            R = curve radius (ft)

                            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                            Length of Spiralo AASHTO also provides recommended spiral lengths

                            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                            o Design Note For construction purposes round your designs to a reasonable values eg

                            Ls = 147 feet round it to

                            Ls = 150 feet

                            Source Iowa DOT Design Manual

                            SPIRAL TERMINOLOGY

                            Source Iowa DOT Design Manual

                            Source Iowa DOT Design Manual

                            Source Iowa DOT Design Manual

                            Attainment of Superelevationon spiral curves

                            See sketches that follow

                            Normal Crown (DOT ndash pt A)

                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                            65Source Iowa DOT Standard Road Plans RP-2

                            With Spirals

                            Same as point E of GB

                            With Spirals

                            Tangent runout (A to B)

                            With Spirals

                            Removal of crown

                            With Spirals

                            Transition of superelevation

                            Full superelevation

                            69

                            • Slide 1
                            • Geometric Design ndash Basic Principles
                            • GEOMETRIC DESIGN ndash Course Heads
                            • Slide 4
                            • Curves
                            • Horizontal Curves
                            • Design Elements
                            • Slide 8
                            • Slide 9
                            • Slide 10
                            • Slide 11
                            • Horizontal Curves
                            • Slide 13
                            • Slide 14
                            • Slide 15
                            • Slide 16
                            • Slide 17
                            • Slide 18
                            • Horizontal Curve Sight Distance
                            • Slide 20
                            • Slide 21
                            • Slide 22
                            • Slide 23
                            • Slide 24
                            • Slide 25
                            • TRANSITIONS Superelevation Spiral Curves
                            • Superelevation
                            • Image
                            • Superelevation Transitioning
                            • Slide 30
                            • Attainment of Superelevation - General
                            • Tangent Runout Section
                            • Superelevation Runoff Section
                            • Slide 34
                            • Slide 35
                            • Slide 36
                            • Slide 37
                            • Slide 38
                            • Slide 39
                            • Slide 40
                            • Slide 41
                            • Attainment Location - WHERE
                            • Minimum Length of Runoff for curve
                            • Minimum Length of Tangent Runout
                            • Length of Superelevation Runoff
                            • Relative Gradient (G)
                            • Maximum Relative Gradient (G)
                            • Multilane Adjustment
                            • Length of Superelevation Runoff Example
                            • Slide 50
                            • Tangent runout length Example continued
                            • Slide 52
                            • Spiral Curve Transitions
                            • Slide 54
                            • Spirals
                            • Minimum Length of Spiral
                            • Slide 57
                            • Maximum Length of Spiral
                            • Length of Spiral
                            • Slide 60
                            • Slide 61
                            • Slide 62
                            • Slide 63
                            • Attainment of Superelevation on spiral curves
                            • Slide 65
                            • Slide 66
                            • Slide 67
                            • Slide 68
                            • Slide 69

                              Horizontal Curves

                              Horizontal Curves

                              Horizontal Curves

                              Horizontal Curves

                              Horizontal Curve Sight Distance

                              Horizontal Curve Sight Distance

                              Curves Minimum Radius

                              Rmin = ____V2____

                              15 (e + f) where Rmin is the minimum radius in feet

                              V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                              Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                              and graphed in Green Book) and design speed

                              bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                              bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                              bull f decreases as speed increases (less tire pavement contact)

                              Curves Max e is controlled by 4 factors

                              bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                              influenced by high super elevation rates Max e

                              bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                              bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                              bull For consistency use a single rate within a project or on a highway

                              Curves

                              Curves

                              TRANSITIONSTRANSITIONS

                              SuperelevationSuperelevationSpiral CurvesSpiral Curves

                              TRANSITIONSTRANSITIONS

                              SuperelevationSuperelevationSpiral CurvesSpiral Curves

                              Superelevation

                              Image

                              httptechalivemtuedumodulesmodule0003Superelevationhtm

                              Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                              design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                              In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                              Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                              Superelevation Although superelevation is advantageous for traffic

                              operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                              Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                              Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                              Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                              Attainment of Superelevation - General

                              bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                              bull Change in pavement slope should be consistent over a distance

                              Tangent Runout Section Superelevation Runoff Section bull Methods

                              bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                              Tangent Runout Section

                              Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                              For rotation about centerline

                              Superelevation Runoff Section

                              Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                              For undivided highways with cross-section rotated about centerline

                              Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                              transition from a normal crown section which is accomplished by rotating the pavement

                              The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                              Cross section (-a-) is the normal crown section where the transitioning begins

                              Cross section (-b-) is reached by rotating half the pavement until it is level

                              Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                              Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                              Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                              Superelevation Transitioning Rotation about the centerline profile of traveled way

                              This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                              Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                              Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                              This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                              Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                              The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                              39

                              40

                              Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                              Same as point E of GB

                              Attainment Location - WHERE

                              Superelevation must be attained over a length that includes the tangent and the curve

                              Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                              Super runoff is all attained in Spiral if used

                              Minimum Length of Runoff for curve

                              Lr based on drainage and aesthetics

                              rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                              current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                              Minimum Length of Tangent Runout

                              Lt = eNC x Lr

                              ed

                              where

                              eNC = normal cross slope rate ()

                              ed = design superelevation rate

                              Lr = minimum length of superelevation runoff (ft)

                              (Result is the edge slope is same as for Runoff segment)

                              Length of Superelevation Runoff

                              α = multilane adjustment factor adjusts for total width

                              r

                              Relative Gradient (G)

                              Maximum longitudinal slope Depends on design speed higher speed =

                              gentler slope

                              For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                              Maximum Relative Gradient (G)

                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                              Multilane Adjustment

                              Runout and runoff must be adjusted for multilane rotation

                              See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                              Length of Superelevation Runoff Example

                              For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                              Lr = 12eα

                              G

                              50

                              Lr = 12eα = (12) (004) (15)

                              G 05

                              Lr = 144 feet

                              Tangent runout length Example continued

                              Lt = (eNC ed ) x Lr

                              as defined previously if NC = 2

                              Tangent runout for the example is

                              LT = 2 4 144rsquo = 72 feet

                              52

                              From previous example speed = 50 mph e = 4

                              From chart runoff = 144 feet same as from calculation

                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                              Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                              Spiral Curve Transitions Vehicles follow a transition path as they enter or

                              leave a horizontal curve

                              Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                              Spirals Advantages

                              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                              Provides location for superelevation runoff (not part on tangentcurve)

                              Provides transition in width when horizontal curve is widened

                              Aesthetic

                              Minimum Length of Spiral

                              Possible Equations

                              Larger of (1) L = 315 V3

                              RC

                              Where

                              L = minimum length of spiral (ft)

                              V = speed (mph)

                              R = curve radius (ft)

                              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                              Minimum Length of Spiral

                              Or (2) L = (24pminR)12

                              Where

                              L = minimum length of spiral (ft)

                              R = curve radius (ft)

                              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                              Maximum Length of Spiral

                              L = (24pmaxR)12

                              Where

                              L = maximum length of spiral (ft)

                              R = curve radius (ft)

                              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                              Length of Spiralo AASHTO also provides recommended spiral lengths

                              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                              o Design Note For construction purposes round your designs to a reasonable values eg

                              Ls = 147 feet round it to

                              Ls = 150 feet

                              Source Iowa DOT Design Manual

                              SPIRAL TERMINOLOGY

                              Source Iowa DOT Design Manual

                              Source Iowa DOT Design Manual

                              Source Iowa DOT Design Manual

                              Attainment of Superelevationon spiral curves

                              See sketches that follow

                              Normal Crown (DOT ndash pt A)

                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                              65Source Iowa DOT Standard Road Plans RP-2

                              With Spirals

                              Same as point E of GB

                              With Spirals

                              Tangent runout (A to B)

                              With Spirals

                              Removal of crown

                              With Spirals

                              Transition of superelevation

                              Full superelevation

                              69

                              • Slide 1
                              • Geometric Design ndash Basic Principles
                              • GEOMETRIC DESIGN ndash Course Heads
                              • Slide 4
                              • Curves
                              • Horizontal Curves
                              • Design Elements
                              • Slide 8
                              • Slide 9
                              • Slide 10
                              • Slide 11
                              • Horizontal Curves
                              • Slide 13
                              • Slide 14
                              • Slide 15
                              • Slide 16
                              • Slide 17
                              • Slide 18
                              • Horizontal Curve Sight Distance
                              • Slide 20
                              • Slide 21
                              • Slide 22
                              • Slide 23
                              • Slide 24
                              • Slide 25
                              • TRANSITIONS Superelevation Spiral Curves
                              • Superelevation
                              • Image
                              • Superelevation Transitioning
                              • Slide 30
                              • Attainment of Superelevation - General
                              • Tangent Runout Section
                              • Superelevation Runoff Section
                              • Slide 34
                              • Slide 35
                              • Slide 36
                              • Slide 37
                              • Slide 38
                              • Slide 39
                              • Slide 40
                              • Slide 41
                              • Attainment Location - WHERE
                              • Minimum Length of Runoff for curve
                              • Minimum Length of Tangent Runout
                              • Length of Superelevation Runoff
                              • Relative Gradient (G)
                              • Maximum Relative Gradient (G)
                              • Multilane Adjustment
                              • Length of Superelevation Runoff Example
                              • Slide 50
                              • Tangent runout length Example continued
                              • Slide 52
                              • Spiral Curve Transitions
                              • Slide 54
                              • Spirals
                              • Minimum Length of Spiral
                              • Slide 57
                              • Maximum Length of Spiral
                              • Length of Spiral
                              • Slide 60
                              • Slide 61
                              • Slide 62
                              • Slide 63
                              • Attainment of Superelevation on spiral curves
                              • Slide 65
                              • Slide 66
                              • Slide 67
                              • Slide 68
                              • Slide 69

                                Horizontal Curves

                                Horizontal Curves

                                Horizontal Curves

                                Horizontal Curve Sight Distance

                                Horizontal Curve Sight Distance

                                Curves Minimum Radius

                                Rmin = ____V2____

                                15 (e + f) where Rmin is the minimum radius in feet

                                V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                                Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                and graphed in Green Book) and design speed

                                bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                bull f decreases as speed increases (less tire pavement contact)

                                Curves Max e is controlled by 4 factors

                                bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                influenced by high super elevation rates Max e

                                bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                bull For consistency use a single rate within a project or on a highway

                                Curves

                                Curves

                                TRANSITIONSTRANSITIONS

                                SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                TRANSITIONSTRANSITIONS

                                SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                Superelevation

                                Image

                                httptechalivemtuedumodulesmodule0003Superelevationhtm

                                Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                Superelevation Although superelevation is advantageous for traffic

                                operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                Attainment of Superelevation - General

                                bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                bull Change in pavement slope should be consistent over a distance

                                Tangent Runout Section Superelevation Runoff Section bull Methods

                                bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                Tangent Runout Section

                                Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                For rotation about centerline

                                Superelevation Runoff Section

                                Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                For undivided highways with cross-section rotated about centerline

                                Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                transition from a normal crown section which is accomplished by rotating the pavement

                                The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                Cross section (-a-) is the normal crown section where the transitioning begins

                                Cross section (-b-) is reached by rotating half the pavement until it is level

                                Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                Superelevation Transitioning Rotation about the centerline profile of traveled way

                                This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                39

                                40

                                Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                Same as point E of GB

                                Attainment Location - WHERE

                                Superelevation must be attained over a length that includes the tangent and the curve

                                Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                Super runoff is all attained in Spiral if used

                                Minimum Length of Runoff for curve

                                Lr based on drainage and aesthetics

                                rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                Minimum Length of Tangent Runout

                                Lt = eNC x Lr

                                ed

                                where

                                eNC = normal cross slope rate ()

                                ed = design superelevation rate

                                Lr = minimum length of superelevation runoff (ft)

                                (Result is the edge slope is same as for Runoff segment)

                                Length of Superelevation Runoff

                                α = multilane adjustment factor adjusts for total width

                                r

                                Relative Gradient (G)

                                Maximum longitudinal slope Depends on design speed higher speed =

                                gentler slope

                                For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                Maximum Relative Gradient (G)

                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                Multilane Adjustment

                                Runout and runoff must be adjusted for multilane rotation

                                See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                Length of Superelevation Runoff Example

                                For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                Lr = 12eα

                                G

                                50

                                Lr = 12eα = (12) (004) (15)

                                G 05

                                Lr = 144 feet

                                Tangent runout length Example continued

                                Lt = (eNC ed ) x Lr

                                as defined previously if NC = 2

                                Tangent runout for the example is

                                LT = 2 4 144rsquo = 72 feet

                                52

                                From previous example speed = 50 mph e = 4

                                From chart runoff = 144 feet same as from calculation

                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                leave a horizontal curve

                                Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                Spirals Advantages

                                Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                Provides location for superelevation runoff (not part on tangentcurve)

                                Provides transition in width when horizontal curve is widened

                                Aesthetic

                                Minimum Length of Spiral

                                Possible Equations

                                Larger of (1) L = 315 V3

                                RC

                                Where

                                L = minimum length of spiral (ft)

                                V = speed (mph)

                                R = curve radius (ft)

                                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                Minimum Length of Spiral

                                Or (2) L = (24pminR)12

                                Where

                                L = minimum length of spiral (ft)

                                R = curve radius (ft)

                                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                Maximum Length of Spiral

                                L = (24pmaxR)12

                                Where

                                L = maximum length of spiral (ft)

                                R = curve radius (ft)

                                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                Length of Spiralo AASHTO also provides recommended spiral lengths

                                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                o Design Note For construction purposes round your designs to a reasonable values eg

                                Ls = 147 feet round it to

                                Ls = 150 feet

                                Source Iowa DOT Design Manual

                                SPIRAL TERMINOLOGY

                                Source Iowa DOT Design Manual

                                Source Iowa DOT Design Manual

                                Source Iowa DOT Design Manual

                                Attainment of Superelevationon spiral curves

                                See sketches that follow

                                Normal Crown (DOT ndash pt A)

                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                65Source Iowa DOT Standard Road Plans RP-2

                                With Spirals

                                Same as point E of GB

                                With Spirals

                                Tangent runout (A to B)

                                With Spirals

                                Removal of crown

                                With Spirals

                                Transition of superelevation

                                Full superelevation

                                69

                                • Slide 1
                                • Geometric Design ndash Basic Principles
                                • GEOMETRIC DESIGN ndash Course Heads
                                • Slide 4
                                • Curves
                                • Horizontal Curves
                                • Design Elements
                                • Slide 8
                                • Slide 9
                                • Slide 10
                                • Slide 11
                                • Horizontal Curves
                                • Slide 13
                                • Slide 14
                                • Slide 15
                                • Slide 16
                                • Slide 17
                                • Slide 18
                                • Horizontal Curve Sight Distance
                                • Slide 20
                                • Slide 21
                                • Slide 22
                                • Slide 23
                                • Slide 24
                                • Slide 25
                                • TRANSITIONS Superelevation Spiral Curves
                                • Superelevation
                                • Image
                                • Superelevation Transitioning
                                • Slide 30
                                • Attainment of Superelevation - General
                                • Tangent Runout Section
                                • Superelevation Runoff Section
                                • Slide 34
                                • Slide 35
                                • Slide 36
                                • Slide 37
                                • Slide 38
                                • Slide 39
                                • Slide 40
                                • Slide 41
                                • Attainment Location - WHERE
                                • Minimum Length of Runoff for curve
                                • Minimum Length of Tangent Runout
                                • Length of Superelevation Runoff
                                • Relative Gradient (G)
                                • Maximum Relative Gradient (G)
                                • Multilane Adjustment
                                • Length of Superelevation Runoff Example
                                • Slide 50
                                • Tangent runout length Example continued
                                • Slide 52
                                • Spiral Curve Transitions
                                • Slide 54
                                • Spirals
                                • Minimum Length of Spiral
                                • Slide 57
                                • Maximum Length of Spiral
                                • Length of Spiral
                                • Slide 60
                                • Slide 61
                                • Slide 62
                                • Slide 63
                                • Attainment of Superelevation on spiral curves
                                • Slide 65
                                • Slide 66
                                • Slide 67
                                • Slide 68
                                • Slide 69

                                  Horizontal Curves

                                  Horizontal Curves

                                  Horizontal Curve Sight Distance

                                  Horizontal Curve Sight Distance

                                  Curves Minimum Radius

                                  Rmin = ____V2____

                                  15 (e + f) where Rmin is the minimum radius in feet

                                  V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                                  Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                  and graphed in Green Book) and design speed

                                  bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                  bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                  bull f decreases as speed increases (less tire pavement contact)

                                  Curves Max e is controlled by 4 factors

                                  bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                  influenced by high super elevation rates Max e

                                  bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                  bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                  bull For consistency use a single rate within a project or on a highway

                                  Curves

                                  Curves

                                  TRANSITIONSTRANSITIONS

                                  SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                  TRANSITIONSTRANSITIONS

                                  SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                  Superelevation

                                  Image

                                  httptechalivemtuedumodulesmodule0003Superelevationhtm

                                  Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                  design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                  In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                  Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                  Superelevation Although superelevation is advantageous for traffic

                                  operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                  Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                  Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                  Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                  Attainment of Superelevation - General

                                  bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                  bull Change in pavement slope should be consistent over a distance

                                  Tangent Runout Section Superelevation Runoff Section bull Methods

                                  bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                  Tangent Runout Section

                                  Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                  For rotation about centerline

                                  Superelevation Runoff Section

                                  Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                  For undivided highways with cross-section rotated about centerline

                                  Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                  transition from a normal crown section which is accomplished by rotating the pavement

                                  The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                  Cross section (-a-) is the normal crown section where the transitioning begins

                                  Cross section (-b-) is reached by rotating half the pavement until it is level

                                  Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                  Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                  Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                  Superelevation Transitioning Rotation about the centerline profile of traveled way

                                  This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                  Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                  Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                  This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                  Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                  The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                  39

                                  40

                                  Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                  Same as point E of GB

                                  Attainment Location - WHERE

                                  Superelevation must be attained over a length that includes the tangent and the curve

                                  Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                  Super runoff is all attained in Spiral if used

                                  Minimum Length of Runoff for curve

                                  Lr based on drainage and aesthetics

                                  rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                  current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                  Minimum Length of Tangent Runout

                                  Lt = eNC x Lr

                                  ed

                                  where

                                  eNC = normal cross slope rate ()

                                  ed = design superelevation rate

                                  Lr = minimum length of superelevation runoff (ft)

                                  (Result is the edge slope is same as for Runoff segment)

                                  Length of Superelevation Runoff

                                  α = multilane adjustment factor adjusts for total width

                                  r

                                  Relative Gradient (G)

                                  Maximum longitudinal slope Depends on design speed higher speed =

                                  gentler slope

                                  For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                  Maximum Relative Gradient (G)

                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                  Multilane Adjustment

                                  Runout and runoff must be adjusted for multilane rotation

                                  See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                  Length of Superelevation Runoff Example

                                  For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                  Lr = 12eα

                                  G

                                  50

                                  Lr = 12eα = (12) (004) (15)

                                  G 05

                                  Lr = 144 feet

                                  Tangent runout length Example continued

                                  Lt = (eNC ed ) x Lr

                                  as defined previously if NC = 2

                                  Tangent runout for the example is

                                  LT = 2 4 144rsquo = 72 feet

                                  52

                                  From previous example speed = 50 mph e = 4

                                  From chart runoff = 144 feet same as from calculation

                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                  Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                  Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                  leave a horizontal curve

                                  Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                  Spirals Advantages

                                  Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                  Provides location for superelevation runoff (not part on tangentcurve)

                                  Provides transition in width when horizontal curve is widened

                                  Aesthetic

                                  Minimum Length of Spiral

                                  Possible Equations

                                  Larger of (1) L = 315 V3

                                  RC

                                  Where

                                  L = minimum length of spiral (ft)

                                  V = speed (mph)

                                  R = curve radius (ft)

                                  C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                  Minimum Length of Spiral

                                  Or (2) L = (24pminR)12

                                  Where

                                  L = minimum length of spiral (ft)

                                  R = curve radius (ft)

                                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                  Maximum Length of Spiral

                                  L = (24pmaxR)12

                                  Where

                                  L = maximum length of spiral (ft)

                                  R = curve radius (ft)

                                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                  Length of Spiralo AASHTO also provides recommended spiral lengths

                                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                  o Design Note For construction purposes round your designs to a reasonable values eg

                                  Ls = 147 feet round it to

                                  Ls = 150 feet

                                  Source Iowa DOT Design Manual

                                  SPIRAL TERMINOLOGY

                                  Source Iowa DOT Design Manual

                                  Source Iowa DOT Design Manual

                                  Source Iowa DOT Design Manual

                                  Attainment of Superelevationon spiral curves

                                  See sketches that follow

                                  Normal Crown (DOT ndash pt A)

                                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                                  65Source Iowa DOT Standard Road Plans RP-2

                                  With Spirals

                                  Same as point E of GB

                                  With Spirals

                                  Tangent runout (A to B)

                                  With Spirals

                                  Removal of crown

                                  With Spirals

                                  Transition of superelevation

                                  Full superelevation

                                  69

                                  • Slide 1
                                  • Geometric Design ndash Basic Principles
                                  • GEOMETRIC DESIGN ndash Course Heads
                                  • Slide 4
                                  • Curves
                                  • Horizontal Curves
                                  • Design Elements
                                  • Slide 8
                                  • Slide 9
                                  • Slide 10
                                  • Slide 11
                                  • Horizontal Curves
                                  • Slide 13
                                  • Slide 14
                                  • Slide 15
                                  • Slide 16
                                  • Slide 17
                                  • Slide 18
                                  • Horizontal Curve Sight Distance
                                  • Slide 20
                                  • Slide 21
                                  • Slide 22
                                  • Slide 23
                                  • Slide 24
                                  • Slide 25
                                  • TRANSITIONS Superelevation Spiral Curves
                                  • Superelevation
                                  • Image
                                  • Superelevation Transitioning
                                  • Slide 30
                                  • Attainment of Superelevation - General
                                  • Tangent Runout Section
                                  • Superelevation Runoff Section
                                  • Slide 34
                                  • Slide 35
                                  • Slide 36
                                  • Slide 37
                                  • Slide 38
                                  • Slide 39
                                  • Slide 40
                                  • Slide 41
                                  • Attainment Location - WHERE
                                  • Minimum Length of Runoff for curve
                                  • Minimum Length of Tangent Runout
                                  • Length of Superelevation Runoff
                                  • Relative Gradient (G)
                                  • Maximum Relative Gradient (G)
                                  • Multilane Adjustment
                                  • Length of Superelevation Runoff Example
                                  • Slide 50
                                  • Tangent runout length Example continued
                                  • Slide 52
                                  • Spiral Curve Transitions
                                  • Slide 54
                                  • Spirals
                                  • Minimum Length of Spiral
                                  • Slide 57
                                  • Maximum Length of Spiral
                                  • Length of Spiral
                                  • Slide 60
                                  • Slide 61
                                  • Slide 62
                                  • Slide 63
                                  • Attainment of Superelevation on spiral curves
                                  • Slide 65
                                  • Slide 66
                                  • Slide 67
                                  • Slide 68
                                  • Slide 69

                                    Horizontal Curves

                                    Horizontal Curve Sight Distance

                                    Horizontal Curve Sight Distance

                                    Curves Minimum Radius

                                    Rmin = ____V2____

                                    15 (e + f) where Rmin is the minimum radius in feet

                                    V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                                    Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                    and graphed in Green Book) and design speed

                                    bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                    bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                    bull f decreases as speed increases (less tire pavement contact)

                                    Curves Max e is controlled by 4 factors

                                    bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                    influenced by high super elevation rates Max e

                                    bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                    bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                    bull For consistency use a single rate within a project or on a highway

                                    Curves

                                    Curves

                                    TRANSITIONSTRANSITIONS

                                    SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                    TRANSITIONSTRANSITIONS

                                    SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                    Superelevation

                                    Image

                                    httptechalivemtuedumodulesmodule0003Superelevationhtm

                                    Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                    design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                    In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                    Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                    Superelevation Although superelevation is advantageous for traffic

                                    operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                    Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                    Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                    Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                    Attainment of Superelevation - General

                                    bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                    bull Change in pavement slope should be consistent over a distance

                                    Tangent Runout Section Superelevation Runoff Section bull Methods

                                    bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                    Tangent Runout Section

                                    Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                    For rotation about centerline

                                    Superelevation Runoff Section

                                    Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                    For undivided highways with cross-section rotated about centerline

                                    Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                    transition from a normal crown section which is accomplished by rotating the pavement

                                    The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                    Cross section (-a-) is the normal crown section where the transitioning begins

                                    Cross section (-b-) is reached by rotating half the pavement until it is level

                                    Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                    Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                    Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                    Superelevation Transitioning Rotation about the centerline profile of traveled way

                                    This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                    Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                    Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                    This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                    Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                    The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                    39

                                    40

                                    Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                    Same as point E of GB

                                    Attainment Location - WHERE

                                    Superelevation must be attained over a length that includes the tangent and the curve

                                    Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                    Super runoff is all attained in Spiral if used

                                    Minimum Length of Runoff for curve

                                    Lr based on drainage and aesthetics

                                    rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                    current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                    Minimum Length of Tangent Runout

                                    Lt = eNC x Lr

                                    ed

                                    where

                                    eNC = normal cross slope rate ()

                                    ed = design superelevation rate

                                    Lr = minimum length of superelevation runoff (ft)

                                    (Result is the edge slope is same as for Runoff segment)

                                    Length of Superelevation Runoff

                                    α = multilane adjustment factor adjusts for total width

                                    r

                                    Relative Gradient (G)

                                    Maximum longitudinal slope Depends on design speed higher speed =

                                    gentler slope

                                    For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                    Maximum Relative Gradient (G)

                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                    Multilane Adjustment

                                    Runout and runoff must be adjusted for multilane rotation

                                    See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                    Length of Superelevation Runoff Example

                                    For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                    Lr = 12eα

                                    G

                                    50

                                    Lr = 12eα = (12) (004) (15)

                                    G 05

                                    Lr = 144 feet

                                    Tangent runout length Example continued

                                    Lt = (eNC ed ) x Lr

                                    as defined previously if NC = 2

                                    Tangent runout for the example is

                                    LT = 2 4 144rsquo = 72 feet

                                    52

                                    From previous example speed = 50 mph e = 4

                                    From chart runoff = 144 feet same as from calculation

                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                    Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                    leave a horizontal curve

                                    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                    Spirals Advantages

                                    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                    Provides location for superelevation runoff (not part on tangentcurve)

                                    Provides transition in width when horizontal curve is widened

                                    Aesthetic

                                    Minimum Length of Spiral

                                    Possible Equations

                                    Larger of (1) L = 315 V3

                                    RC

                                    Where

                                    L = minimum length of spiral (ft)

                                    V = speed (mph)

                                    R = curve radius (ft)

                                    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                    Minimum Length of Spiral

                                    Or (2) L = (24pminR)12

                                    Where

                                    L = minimum length of spiral (ft)

                                    R = curve radius (ft)

                                    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                    Maximum Length of Spiral

                                    L = (24pmaxR)12

                                    Where

                                    L = maximum length of spiral (ft)

                                    R = curve radius (ft)

                                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                    Length of Spiralo AASHTO also provides recommended spiral lengths

                                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                    o Design Note For construction purposes round your designs to a reasonable values eg

                                    Ls = 147 feet round it to

                                    Ls = 150 feet

                                    Source Iowa DOT Design Manual

                                    SPIRAL TERMINOLOGY

                                    Source Iowa DOT Design Manual

                                    Source Iowa DOT Design Manual

                                    Source Iowa DOT Design Manual

                                    Attainment of Superelevationon spiral curves

                                    See sketches that follow

                                    Normal Crown (DOT ndash pt A)

                                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                                    65Source Iowa DOT Standard Road Plans RP-2

                                    With Spirals

                                    Same as point E of GB

                                    With Spirals

                                    Tangent runout (A to B)

                                    With Spirals

                                    Removal of crown

                                    With Spirals

                                    Transition of superelevation

                                    Full superelevation

                                    69

                                    • Slide 1
                                    • Geometric Design ndash Basic Principles
                                    • GEOMETRIC DESIGN ndash Course Heads
                                    • Slide 4
                                    • Curves
                                    • Horizontal Curves
                                    • Design Elements
                                    • Slide 8
                                    • Slide 9
                                    • Slide 10
                                    • Slide 11
                                    • Horizontal Curves
                                    • Slide 13
                                    • Slide 14
                                    • Slide 15
                                    • Slide 16
                                    • Slide 17
                                    • Slide 18
                                    • Horizontal Curve Sight Distance
                                    • Slide 20
                                    • Slide 21
                                    • Slide 22
                                    • Slide 23
                                    • Slide 24
                                    • Slide 25
                                    • TRANSITIONS Superelevation Spiral Curves
                                    • Superelevation
                                    • Image
                                    • Superelevation Transitioning
                                    • Slide 30
                                    • Attainment of Superelevation - General
                                    • Tangent Runout Section
                                    • Superelevation Runoff Section
                                    • Slide 34
                                    • Slide 35
                                    • Slide 36
                                    • Slide 37
                                    • Slide 38
                                    • Slide 39
                                    • Slide 40
                                    • Slide 41
                                    • Attainment Location - WHERE
                                    • Minimum Length of Runoff for curve
                                    • Minimum Length of Tangent Runout
                                    • Length of Superelevation Runoff
                                    • Relative Gradient (G)
                                    • Maximum Relative Gradient (G)
                                    • Multilane Adjustment
                                    • Length of Superelevation Runoff Example
                                    • Slide 50
                                    • Tangent runout length Example continued
                                    • Slide 52
                                    • Spiral Curve Transitions
                                    • Slide 54
                                    • Spirals
                                    • Minimum Length of Spiral
                                    • Slide 57
                                    • Maximum Length of Spiral
                                    • Length of Spiral
                                    • Slide 60
                                    • Slide 61
                                    • Slide 62
                                    • Slide 63
                                    • Attainment of Superelevation on spiral curves
                                    • Slide 65
                                    • Slide 66
                                    • Slide 67
                                    • Slide 68
                                    • Slide 69

                                      Horizontal Curve Sight Distance

                                      Horizontal Curve Sight Distance

                                      Curves Minimum Radius

                                      Rmin = ____V2____

                                      15 (e + f) where Rmin is the minimum radius in feet

                                      V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                                      Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                      and graphed in Green Book) and design speed

                                      bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                      bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                      bull f decreases as speed increases (less tire pavement contact)

                                      Curves Max e is controlled by 4 factors

                                      bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                      influenced by high super elevation rates Max e

                                      bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                      bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                      bull For consistency use a single rate within a project or on a highway

                                      Curves

                                      Curves

                                      TRANSITIONSTRANSITIONS

                                      SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                      TRANSITIONSTRANSITIONS

                                      SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                      Superelevation

                                      Image

                                      httptechalivemtuedumodulesmodule0003Superelevationhtm

                                      Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                      design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                      In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                      Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                      Superelevation Although superelevation is advantageous for traffic

                                      operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                      Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                      Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                      Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                      Attainment of Superelevation - General

                                      bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                      bull Change in pavement slope should be consistent over a distance

                                      Tangent Runout Section Superelevation Runoff Section bull Methods

                                      bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                      Tangent Runout Section

                                      Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                      For rotation about centerline

                                      Superelevation Runoff Section

                                      Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                      For undivided highways with cross-section rotated about centerline

                                      Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                      transition from a normal crown section which is accomplished by rotating the pavement

                                      The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                      Cross section (-a-) is the normal crown section where the transitioning begins

                                      Cross section (-b-) is reached by rotating half the pavement until it is level

                                      Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                      Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                      Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                      Superelevation Transitioning Rotation about the centerline profile of traveled way

                                      This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                      Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                      Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                      This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                      Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                      The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                      39

                                      40

                                      Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                      Same as point E of GB

                                      Attainment Location - WHERE

                                      Superelevation must be attained over a length that includes the tangent and the curve

                                      Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                      Super runoff is all attained in Spiral if used

                                      Minimum Length of Runoff for curve

                                      Lr based on drainage and aesthetics

                                      rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                      current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                      Minimum Length of Tangent Runout

                                      Lt = eNC x Lr

                                      ed

                                      where

                                      eNC = normal cross slope rate ()

                                      ed = design superelevation rate

                                      Lr = minimum length of superelevation runoff (ft)

                                      (Result is the edge slope is same as for Runoff segment)

                                      Length of Superelevation Runoff

                                      α = multilane adjustment factor adjusts for total width

                                      r

                                      Relative Gradient (G)

                                      Maximum longitudinal slope Depends on design speed higher speed =

                                      gentler slope

                                      For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                      Maximum Relative Gradient (G)

                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                      Multilane Adjustment

                                      Runout and runoff must be adjusted for multilane rotation

                                      See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                      Length of Superelevation Runoff Example

                                      For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                      Lr = 12eα

                                      G

                                      50

                                      Lr = 12eα = (12) (004) (15)

                                      G 05

                                      Lr = 144 feet

                                      Tangent runout length Example continued

                                      Lt = (eNC ed ) x Lr

                                      as defined previously if NC = 2

                                      Tangent runout for the example is

                                      LT = 2 4 144rsquo = 72 feet

                                      52

                                      From previous example speed = 50 mph e = 4

                                      From chart runoff = 144 feet same as from calculation

                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                      Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                      leave a horizontal curve

                                      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                      Spirals Advantages

                                      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                      Provides location for superelevation runoff (not part on tangentcurve)

                                      Provides transition in width when horizontal curve is widened

                                      Aesthetic

                                      Minimum Length of Spiral

                                      Possible Equations

                                      Larger of (1) L = 315 V3

                                      RC

                                      Where

                                      L = minimum length of spiral (ft)

                                      V = speed (mph)

                                      R = curve radius (ft)

                                      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                      Minimum Length of Spiral

                                      Or (2) L = (24pminR)12

                                      Where

                                      L = minimum length of spiral (ft)

                                      R = curve radius (ft)

                                      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                      Maximum Length of Spiral

                                      L = (24pmaxR)12

                                      Where

                                      L = maximum length of spiral (ft)

                                      R = curve radius (ft)

                                      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                      Length of Spiralo AASHTO also provides recommended spiral lengths

                                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                      o Design Note For construction purposes round your designs to a reasonable values eg

                                      Ls = 147 feet round it to

                                      Ls = 150 feet

                                      Source Iowa DOT Design Manual

                                      SPIRAL TERMINOLOGY

                                      Source Iowa DOT Design Manual

                                      Source Iowa DOT Design Manual

                                      Source Iowa DOT Design Manual

                                      Attainment of Superelevationon spiral curves

                                      See sketches that follow

                                      Normal Crown (DOT ndash pt A)

                                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                                      65Source Iowa DOT Standard Road Plans RP-2

                                      With Spirals

                                      Same as point E of GB

                                      With Spirals

                                      Tangent runout (A to B)

                                      With Spirals

                                      Removal of crown

                                      With Spirals

                                      Transition of superelevation

                                      Full superelevation

                                      69

                                      • Slide 1
                                      • Geometric Design ndash Basic Principles
                                      • GEOMETRIC DESIGN ndash Course Heads
                                      • Slide 4
                                      • Curves
                                      • Horizontal Curves
                                      • Design Elements
                                      • Slide 8
                                      • Slide 9
                                      • Slide 10
                                      • Slide 11
                                      • Horizontal Curves
                                      • Slide 13
                                      • Slide 14
                                      • Slide 15
                                      • Slide 16
                                      • Slide 17
                                      • Slide 18
                                      • Horizontal Curve Sight Distance
                                      • Slide 20
                                      • Slide 21
                                      • Slide 22
                                      • Slide 23
                                      • Slide 24
                                      • Slide 25
                                      • TRANSITIONS Superelevation Spiral Curves
                                      • Superelevation
                                      • Image
                                      • Superelevation Transitioning
                                      • Slide 30
                                      • Attainment of Superelevation - General
                                      • Tangent Runout Section
                                      • Superelevation Runoff Section
                                      • Slide 34
                                      • Slide 35
                                      • Slide 36
                                      • Slide 37
                                      • Slide 38
                                      • Slide 39
                                      • Slide 40
                                      • Slide 41
                                      • Attainment Location - WHERE
                                      • Minimum Length of Runoff for curve
                                      • Minimum Length of Tangent Runout
                                      • Length of Superelevation Runoff
                                      • Relative Gradient (G)
                                      • Maximum Relative Gradient (G)
                                      • Multilane Adjustment
                                      • Length of Superelevation Runoff Example
                                      • Slide 50
                                      • Tangent runout length Example continued
                                      • Slide 52
                                      • Spiral Curve Transitions
                                      • Slide 54
                                      • Spirals
                                      • Minimum Length of Spiral
                                      • Slide 57
                                      • Maximum Length of Spiral
                                      • Length of Spiral
                                      • Slide 60
                                      • Slide 61
                                      • Slide 62
                                      • Slide 63
                                      • Attainment of Superelevation on spiral curves
                                      • Slide 65
                                      • Slide 66
                                      • Slide 67
                                      • Slide 68
                                      • Slide 69

                                        Horizontal Curve Sight Distance

                                        Curves Minimum Radius

                                        Rmin = ____V2____

                                        15 (e + f) where Rmin is the minimum radius in feet

                                        V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                                        Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                        and graphed in Green Book) and design speed

                                        bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                        bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                        bull f decreases as speed increases (less tire pavement contact)

                                        Curves Max e is controlled by 4 factors

                                        bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                        influenced by high super elevation rates Max e

                                        bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                        bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                        bull For consistency use a single rate within a project or on a highway

                                        Curves

                                        Curves

                                        TRANSITIONSTRANSITIONS

                                        SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                        TRANSITIONSTRANSITIONS

                                        SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                        Superelevation

                                        Image

                                        httptechalivemtuedumodulesmodule0003Superelevationhtm

                                        Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                        design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                        In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                        Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                        Superelevation Although superelevation is advantageous for traffic

                                        operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                        Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                        Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                        Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                        Attainment of Superelevation - General

                                        bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                        bull Change in pavement slope should be consistent over a distance

                                        Tangent Runout Section Superelevation Runoff Section bull Methods

                                        bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                        Tangent Runout Section

                                        Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                        For rotation about centerline

                                        Superelevation Runoff Section

                                        Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                        For undivided highways with cross-section rotated about centerline

                                        Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                        transition from a normal crown section which is accomplished by rotating the pavement

                                        The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                        Cross section (-a-) is the normal crown section where the transitioning begins

                                        Cross section (-b-) is reached by rotating half the pavement until it is level

                                        Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                        Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                        Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                        Superelevation Transitioning Rotation about the centerline profile of traveled way

                                        This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                        Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                        Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                        This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                        Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                        The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                        39

                                        40

                                        Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                        Same as point E of GB

                                        Attainment Location - WHERE

                                        Superelevation must be attained over a length that includes the tangent and the curve

                                        Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                        Super runoff is all attained in Spiral if used

                                        Minimum Length of Runoff for curve

                                        Lr based on drainage and aesthetics

                                        rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                        current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                        Minimum Length of Tangent Runout

                                        Lt = eNC x Lr

                                        ed

                                        where

                                        eNC = normal cross slope rate ()

                                        ed = design superelevation rate

                                        Lr = minimum length of superelevation runoff (ft)

                                        (Result is the edge slope is same as for Runoff segment)

                                        Length of Superelevation Runoff

                                        α = multilane adjustment factor adjusts for total width

                                        r

                                        Relative Gradient (G)

                                        Maximum longitudinal slope Depends on design speed higher speed =

                                        gentler slope

                                        For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                        Maximum Relative Gradient (G)

                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                        Multilane Adjustment

                                        Runout and runoff must be adjusted for multilane rotation

                                        See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                        Length of Superelevation Runoff Example

                                        For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                        Lr = 12eα

                                        G

                                        50

                                        Lr = 12eα = (12) (004) (15)

                                        G 05

                                        Lr = 144 feet

                                        Tangent runout length Example continued

                                        Lt = (eNC ed ) x Lr

                                        as defined previously if NC = 2

                                        Tangent runout for the example is

                                        LT = 2 4 144rsquo = 72 feet

                                        52

                                        From previous example speed = 50 mph e = 4

                                        From chart runoff = 144 feet same as from calculation

                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                        Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                        leave a horizontal curve

                                        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                        Spirals Advantages

                                        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                        Provides location for superelevation runoff (not part on tangentcurve)

                                        Provides transition in width when horizontal curve is widened

                                        Aesthetic

                                        Minimum Length of Spiral

                                        Possible Equations

                                        Larger of (1) L = 315 V3

                                        RC

                                        Where

                                        L = minimum length of spiral (ft)

                                        V = speed (mph)

                                        R = curve radius (ft)

                                        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                        Minimum Length of Spiral

                                        Or (2) L = (24pminR)12

                                        Where

                                        L = minimum length of spiral (ft)

                                        R = curve radius (ft)

                                        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                        Maximum Length of Spiral

                                        L = (24pmaxR)12

                                        Where

                                        L = maximum length of spiral (ft)

                                        R = curve radius (ft)

                                        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                        Length of Spiralo AASHTO also provides recommended spiral lengths

                                        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                        o Design Note For construction purposes round your designs to a reasonable values eg

                                        Ls = 147 feet round it to

                                        Ls = 150 feet

                                        Source Iowa DOT Design Manual

                                        SPIRAL TERMINOLOGY

                                        Source Iowa DOT Design Manual

                                        Source Iowa DOT Design Manual

                                        Source Iowa DOT Design Manual

                                        Attainment of Superelevationon spiral curves

                                        See sketches that follow

                                        Normal Crown (DOT ndash pt A)

                                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                                        65Source Iowa DOT Standard Road Plans RP-2

                                        With Spirals

                                        Same as point E of GB

                                        With Spirals

                                        Tangent runout (A to B)

                                        With Spirals

                                        Removal of crown

                                        With Spirals

                                        Transition of superelevation

                                        Full superelevation

                                        69

                                        • Slide 1
                                        • Geometric Design ndash Basic Principles
                                        • GEOMETRIC DESIGN ndash Course Heads
                                        • Slide 4
                                        • Curves
                                        • Horizontal Curves
                                        • Design Elements
                                        • Slide 8
                                        • Slide 9
                                        • Slide 10
                                        • Slide 11
                                        • Horizontal Curves
                                        • Slide 13
                                        • Slide 14
                                        • Slide 15
                                        • Slide 16
                                        • Slide 17
                                        • Slide 18
                                        • Horizontal Curve Sight Distance
                                        • Slide 20
                                        • Slide 21
                                        • Slide 22
                                        • Slide 23
                                        • Slide 24
                                        • Slide 25
                                        • TRANSITIONS Superelevation Spiral Curves
                                        • Superelevation
                                        • Image
                                        • Superelevation Transitioning
                                        • Slide 30
                                        • Attainment of Superelevation - General
                                        • Tangent Runout Section
                                        • Superelevation Runoff Section
                                        • Slide 34
                                        • Slide 35
                                        • Slide 36
                                        • Slide 37
                                        • Slide 38
                                        • Slide 39
                                        • Slide 40
                                        • Slide 41
                                        • Attainment Location - WHERE
                                        • Minimum Length of Runoff for curve
                                        • Minimum Length of Tangent Runout
                                        • Length of Superelevation Runoff
                                        • Relative Gradient (G)
                                        • Maximum Relative Gradient (G)
                                        • Multilane Adjustment
                                        • Length of Superelevation Runoff Example
                                        • Slide 50
                                        • Tangent runout length Example continued
                                        • Slide 52
                                        • Spiral Curve Transitions
                                        • Slide 54
                                        • Spirals
                                        • Minimum Length of Spiral
                                        • Slide 57
                                        • Maximum Length of Spiral
                                        • Length of Spiral
                                        • Slide 60
                                        • Slide 61
                                        • Slide 62
                                        • Slide 63
                                        • Attainment of Superelevation on spiral curves
                                        • Slide 65
                                        • Slide 66
                                        • Slide 67
                                        • Slide 68
                                        • Slide 69

                                          Curves Minimum Radius

                                          Rmin = ____V2____

                                          15 (e + f) where Rmin is the minimum radius in feet

                                          V = velocity (mph) e = superelevation f = friction 15 = gravity and unit conversion

                                          Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                          and graphed in Green Book) and design speed

                                          bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                          bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                          bull f decreases as speed increases (less tire pavement contact)

                                          Curves Max e is controlled by 4 factors

                                          bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                          influenced by high super elevation rates Max e

                                          bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                          bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                          bull For consistency use a single rate within a project or on a highway

                                          Curves

                                          Curves

                                          TRANSITIONSTRANSITIONS

                                          SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                          TRANSITIONSTRANSITIONS

                                          SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                          Superelevation

                                          Image

                                          httptechalivemtuedumodulesmodule0003Superelevationhtm

                                          Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                          design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                          In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                          Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                          Superelevation Although superelevation is advantageous for traffic

                                          operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                          Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                          Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                          Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                          Attainment of Superelevation - General

                                          bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                          bull Change in pavement slope should be consistent over a distance

                                          Tangent Runout Section Superelevation Runoff Section bull Methods

                                          bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                          Tangent Runout Section

                                          Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                          For rotation about centerline

                                          Superelevation Runoff Section

                                          Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                          For undivided highways with cross-section rotated about centerline

                                          Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                          transition from a normal crown section which is accomplished by rotating the pavement

                                          The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                          Cross section (-a-) is the normal crown section where the transitioning begins

                                          Cross section (-b-) is reached by rotating half the pavement until it is level

                                          Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                          Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                          Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                          Superelevation Transitioning Rotation about the centerline profile of traveled way

                                          This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                          Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                          Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                          This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                          Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                          The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                          39

                                          40

                                          Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                          Same as point E of GB

                                          Attainment Location - WHERE

                                          Superelevation must be attained over a length that includes the tangent and the curve

                                          Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                          Super runoff is all attained in Spiral if used

                                          Minimum Length of Runoff for curve

                                          Lr based on drainage and aesthetics

                                          rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                          current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                          Minimum Length of Tangent Runout

                                          Lt = eNC x Lr

                                          ed

                                          where

                                          eNC = normal cross slope rate ()

                                          ed = design superelevation rate

                                          Lr = minimum length of superelevation runoff (ft)

                                          (Result is the edge slope is same as for Runoff segment)

                                          Length of Superelevation Runoff

                                          α = multilane adjustment factor adjusts for total width

                                          r

                                          Relative Gradient (G)

                                          Maximum longitudinal slope Depends on design speed higher speed =

                                          gentler slope

                                          For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                          Maximum Relative Gradient (G)

                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                          Multilane Adjustment

                                          Runout and runoff must be adjusted for multilane rotation

                                          See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                          Length of Superelevation Runoff Example

                                          For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                          Lr = 12eα

                                          G

                                          50

                                          Lr = 12eα = (12) (004) (15)

                                          G 05

                                          Lr = 144 feet

                                          Tangent runout length Example continued

                                          Lt = (eNC ed ) x Lr

                                          as defined previously if NC = 2

                                          Tangent runout for the example is

                                          LT = 2 4 144rsquo = 72 feet

                                          52

                                          From previous example speed = 50 mph e = 4

                                          From chart runoff = 144 feet same as from calculation

                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                          Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                          leave a horizontal curve

                                          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                          Spirals Advantages

                                          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                          Provides location for superelevation runoff (not part on tangentcurve)

                                          Provides transition in width when horizontal curve is widened

                                          Aesthetic

                                          Minimum Length of Spiral

                                          Possible Equations

                                          Larger of (1) L = 315 V3

                                          RC

                                          Where

                                          L = minimum length of spiral (ft)

                                          V = speed (mph)

                                          R = curve radius (ft)

                                          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                          Minimum Length of Spiral

                                          Or (2) L = (24pminR)12

                                          Where

                                          L = minimum length of spiral (ft)

                                          R = curve radius (ft)

                                          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                          Maximum Length of Spiral

                                          L = (24pmaxR)12

                                          Where

                                          L = maximum length of spiral (ft)

                                          R = curve radius (ft)

                                          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                          Length of Spiralo AASHTO also provides recommended spiral lengths

                                          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                          o Design Note For construction purposes round your designs to a reasonable values eg

                                          Ls = 147 feet round it to

                                          Ls = 150 feet

                                          Source Iowa DOT Design Manual

                                          SPIRAL TERMINOLOGY

                                          Source Iowa DOT Design Manual

                                          Source Iowa DOT Design Manual

                                          Source Iowa DOT Design Manual

                                          Attainment of Superelevationon spiral curves

                                          See sketches that follow

                                          Normal Crown (DOT ndash pt A)

                                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                                          65Source Iowa DOT Standard Road Plans RP-2

                                          With Spirals

                                          Same as point E of GB

                                          With Spirals

                                          Tangent runout (A to B)

                                          With Spirals

                                          Removal of crown

                                          With Spirals

                                          Transition of superelevation

                                          Full superelevation

                                          69

                                          • Slide 1
                                          • Geometric Design ndash Basic Principles
                                          • GEOMETRIC DESIGN ndash Course Heads
                                          • Slide 4
                                          • Curves
                                          • Horizontal Curves
                                          • Design Elements
                                          • Slide 8
                                          • Slide 9
                                          • Slide 10
                                          • Slide 11
                                          • Horizontal Curves
                                          • Slide 13
                                          • Slide 14
                                          • Slide 15
                                          • Slide 16
                                          • Slide 17
                                          • Slide 18
                                          • Horizontal Curve Sight Distance
                                          • Slide 20
                                          • Slide 21
                                          • Slide 22
                                          • Slide 23
                                          • Slide 24
                                          • Slide 25
                                          • TRANSITIONS Superelevation Spiral Curves
                                          • Superelevation
                                          • Image
                                          • Superelevation Transitioning
                                          • Slide 30
                                          • Attainment of Superelevation - General
                                          • Tangent Runout Section
                                          • Superelevation Runoff Section
                                          • Slide 34
                                          • Slide 35
                                          • Slide 36
                                          • Slide 37
                                          • Slide 38
                                          • Slide 39
                                          • Slide 40
                                          • Slide 41
                                          • Attainment Location - WHERE
                                          • Minimum Length of Runoff for curve
                                          • Minimum Length of Tangent Runout
                                          • Length of Superelevation Runoff
                                          • Relative Gradient (G)
                                          • Maximum Relative Gradient (G)
                                          • Multilane Adjustment
                                          • Length of Superelevation Runoff Example
                                          • Slide 50
                                          • Tangent runout length Example continued
                                          • Slide 52
                                          • Spiral Curve Transitions
                                          • Slide 54
                                          • Spirals
                                          • Minimum Length of Spiral
                                          • Slide 57
                                          • Maximum Length of Spiral
                                          • Length of Spiral
                                          • Slide 60
                                          • Slide 61
                                          • Slide 62
                                          • Slide 63
                                          • Attainment of Superelevation on spiral curves
                                          • Slide 65
                                          • Slide 66
                                          • Slide 67
                                          • Slide 68
                                          • Slide 69

                                            Curvesbull Rmin uses max e and max f (defined by AASHTO DOT

                                            and graphed in Green Book) and design speed

                                            bull f is a function of speed roadway surface weather condition tire condition and based on comfort ndash drivers brake make sudden lane changes and change position within a lane when acceleration around a curve becomes ldquouncomfortablerdquo

                                            bull AASHTO 05 20mph with new tires and wet pavement to 035 60mph

                                            bull f decreases as speed increases (less tire pavement contact)

                                            Curves Max e is controlled by 4 factors

                                            bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                            influenced by high super elevation rates Max e

                                            bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                            bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                            bull For consistency use a single rate within a project or on a highway

                                            Curves

                                            Curves

                                            TRANSITIONSTRANSITIONS

                                            SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                            TRANSITIONSTRANSITIONS

                                            SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                            Superelevation

                                            Image

                                            httptechalivemtuedumodulesmodule0003Superelevationhtm

                                            Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                            design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                            In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                            Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                            Superelevation Although superelevation is advantageous for traffic

                                            operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                            Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                            Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                            Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                            Attainment of Superelevation - General

                                            bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                            bull Change in pavement slope should be consistent over a distance

                                            Tangent Runout Section Superelevation Runoff Section bull Methods

                                            bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                            Tangent Runout Section

                                            Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                            For rotation about centerline

                                            Superelevation Runoff Section

                                            Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                            For undivided highways with cross-section rotated about centerline

                                            Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                            transition from a normal crown section which is accomplished by rotating the pavement

                                            The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                            Cross section (-a-) is the normal crown section where the transitioning begins

                                            Cross section (-b-) is reached by rotating half the pavement until it is level

                                            Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                            Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                            Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                            Superelevation Transitioning Rotation about the centerline profile of traveled way

                                            This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                            Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                            Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                            This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                            Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                            The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                            39

                                            40

                                            Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                            Same as point E of GB

                                            Attainment Location - WHERE

                                            Superelevation must be attained over a length that includes the tangent and the curve

                                            Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                            Super runoff is all attained in Spiral if used

                                            Minimum Length of Runoff for curve

                                            Lr based on drainage and aesthetics

                                            rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                            current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                            Minimum Length of Tangent Runout

                                            Lt = eNC x Lr

                                            ed

                                            where

                                            eNC = normal cross slope rate ()

                                            ed = design superelevation rate

                                            Lr = minimum length of superelevation runoff (ft)

                                            (Result is the edge slope is same as for Runoff segment)

                                            Length of Superelevation Runoff

                                            α = multilane adjustment factor adjusts for total width

                                            r

                                            Relative Gradient (G)

                                            Maximum longitudinal slope Depends on design speed higher speed =

                                            gentler slope

                                            For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                            Maximum Relative Gradient (G)

                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                            Multilane Adjustment

                                            Runout and runoff must be adjusted for multilane rotation

                                            See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                            Length of Superelevation Runoff Example

                                            For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                            Lr = 12eα

                                            G

                                            50

                                            Lr = 12eα = (12) (004) (15)

                                            G 05

                                            Lr = 144 feet

                                            Tangent runout length Example continued

                                            Lt = (eNC ed ) x Lr

                                            as defined previously if NC = 2

                                            Tangent runout for the example is

                                            LT = 2 4 144rsquo = 72 feet

                                            52

                                            From previous example speed = 50 mph e = 4

                                            From chart runoff = 144 feet same as from calculation

                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                            Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                            Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                            leave a horizontal curve

                                            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                            Spirals Advantages

                                            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                            Provides location for superelevation runoff (not part on tangentcurve)

                                            Provides transition in width when horizontal curve is widened

                                            Aesthetic

                                            Minimum Length of Spiral

                                            Possible Equations

                                            Larger of (1) L = 315 V3

                                            RC

                                            Where

                                            L = minimum length of spiral (ft)

                                            V = speed (mph)

                                            R = curve radius (ft)

                                            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                            Minimum Length of Spiral

                                            Or (2) L = (24pminR)12

                                            Where

                                            L = minimum length of spiral (ft)

                                            R = curve radius (ft)

                                            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                            Maximum Length of Spiral

                                            L = (24pmaxR)12

                                            Where

                                            L = maximum length of spiral (ft)

                                            R = curve radius (ft)

                                            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                            Length of Spiralo AASHTO also provides recommended spiral lengths

                                            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                            o Design Note For construction purposes round your designs to a reasonable values eg

                                            Ls = 147 feet round it to

                                            Ls = 150 feet

                                            Source Iowa DOT Design Manual

                                            SPIRAL TERMINOLOGY

                                            Source Iowa DOT Design Manual

                                            Source Iowa DOT Design Manual

                                            Source Iowa DOT Design Manual

                                            Attainment of Superelevationon spiral curves

                                            See sketches that follow

                                            Normal Crown (DOT ndash pt A)

                                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                                            65Source Iowa DOT Standard Road Plans RP-2

                                            With Spirals

                                            Same as point E of GB

                                            With Spirals

                                            Tangent runout (A to B)

                                            With Spirals

                                            Removal of crown

                                            With Spirals

                                            Transition of superelevation

                                            Full superelevation

                                            69

                                            • Slide 1
                                            • Geometric Design ndash Basic Principles
                                            • GEOMETRIC DESIGN ndash Course Heads
                                            • Slide 4
                                            • Curves
                                            • Horizontal Curves
                                            • Design Elements
                                            • Slide 8
                                            • Slide 9
                                            • Slide 10
                                            • Slide 11
                                            • Horizontal Curves
                                            • Slide 13
                                            • Slide 14
                                            • Slide 15
                                            • Slide 16
                                            • Slide 17
                                            • Slide 18
                                            • Horizontal Curve Sight Distance
                                            • Slide 20
                                            • Slide 21
                                            • Slide 22
                                            • Slide 23
                                            • Slide 24
                                            • Slide 25
                                            • TRANSITIONS Superelevation Spiral Curves
                                            • Superelevation
                                            • Image
                                            • Superelevation Transitioning
                                            • Slide 30
                                            • Attainment of Superelevation - General
                                            • Tangent Runout Section
                                            • Superelevation Runoff Section
                                            • Slide 34
                                            • Slide 35
                                            • Slide 36
                                            • Slide 37
                                            • Slide 38
                                            • Slide 39
                                            • Slide 40
                                            • Slide 41
                                            • Attainment Location - WHERE
                                            • Minimum Length of Runoff for curve
                                            • Minimum Length of Tangent Runout
                                            • Length of Superelevation Runoff
                                            • Relative Gradient (G)
                                            • Maximum Relative Gradient (G)
                                            • Multilane Adjustment
                                            • Length of Superelevation Runoff Example
                                            • Slide 50
                                            • Tangent runout length Example continued
                                            • Slide 52
                                            • Spiral Curve Transitions
                                            • Slide 54
                                            • Spirals
                                            • Minimum Length of Spiral
                                            • Slide 57
                                            • Maximum Length of Spiral
                                            • Length of Spiral
                                            • Slide 60
                                            • Slide 61
                                            • Slide 62
                                            • Slide 63
                                            • Attainment of Superelevation on spiral curves
                                            • Slide 65
                                            • Slide 66
                                            • Slide 67
                                            • Slide 68
                                            • Slide 69

                                              Curves Max e is controlled by 4 factors

                                              bull Climate conditions (amount of ice and snow)bull Terrain (flat rolling mountainous)bull Type of area (rural or urban)bull Frequency of slow moving vehicles who might be

                                              influenced by high super elevation rates Max e

                                              bull Highest in common use = 10 12 with no ice and snow on low volume gravel-surfaced roads

                                              bull 8 is logical maximum to minimize slipping by stopped vehicles considering snow and ice

                                              bull For consistency use a single rate within a project or on a highway

                                              Curves

                                              Curves

                                              TRANSITIONSTRANSITIONS

                                              SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                              TRANSITIONSTRANSITIONS

                                              SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                              Superelevation

                                              Image

                                              httptechalivemtuedumodulesmodule0003Superelevationhtm

                                              Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                              design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                              In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                              Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                              Superelevation Although superelevation is advantageous for traffic

                                              operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                              Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                              Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                              Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                              Attainment of Superelevation - General

                                              bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                              bull Change in pavement slope should be consistent over a distance

                                              Tangent Runout Section Superelevation Runoff Section bull Methods

                                              bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                              Tangent Runout Section

                                              Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                              For rotation about centerline

                                              Superelevation Runoff Section

                                              Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                              For undivided highways with cross-section rotated about centerline

                                              Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                              transition from a normal crown section which is accomplished by rotating the pavement

                                              The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                              Cross section (-a-) is the normal crown section where the transitioning begins

                                              Cross section (-b-) is reached by rotating half the pavement until it is level

                                              Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                              Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                              Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                              Superelevation Transitioning Rotation about the centerline profile of traveled way

                                              This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                              Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                              Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                              This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                              Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                              The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                              39

                                              40

                                              Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                              Same as point E of GB

                                              Attainment Location - WHERE

                                              Superelevation must be attained over a length that includes the tangent and the curve

                                              Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                              Super runoff is all attained in Spiral if used

                                              Minimum Length of Runoff for curve

                                              Lr based on drainage and aesthetics

                                              rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                              current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                              Minimum Length of Tangent Runout

                                              Lt = eNC x Lr

                                              ed

                                              where

                                              eNC = normal cross slope rate ()

                                              ed = design superelevation rate

                                              Lr = minimum length of superelevation runoff (ft)

                                              (Result is the edge slope is same as for Runoff segment)

                                              Length of Superelevation Runoff

                                              α = multilane adjustment factor adjusts for total width

                                              r

                                              Relative Gradient (G)

                                              Maximum longitudinal slope Depends on design speed higher speed =

                                              gentler slope

                                              For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                              Maximum Relative Gradient (G)

                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                              Multilane Adjustment

                                              Runout and runoff must be adjusted for multilane rotation

                                              See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                              Length of Superelevation Runoff Example

                                              For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                              Lr = 12eα

                                              G

                                              50

                                              Lr = 12eα = (12) (004) (15)

                                              G 05

                                              Lr = 144 feet

                                              Tangent runout length Example continued

                                              Lt = (eNC ed ) x Lr

                                              as defined previously if NC = 2

                                              Tangent runout for the example is

                                              LT = 2 4 144rsquo = 72 feet

                                              52

                                              From previous example speed = 50 mph e = 4

                                              From chart runoff = 144 feet same as from calculation

                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                              Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                              Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                              leave a horizontal curve

                                              Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                              Spirals Advantages

                                              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                              Provides location for superelevation runoff (not part on tangentcurve)

                                              Provides transition in width when horizontal curve is widened

                                              Aesthetic

                                              Minimum Length of Spiral

                                              Possible Equations

                                              Larger of (1) L = 315 V3

                                              RC

                                              Where

                                              L = minimum length of spiral (ft)

                                              V = speed (mph)

                                              R = curve radius (ft)

                                              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                              Minimum Length of Spiral

                                              Or (2) L = (24pminR)12

                                              Where

                                              L = minimum length of spiral (ft)

                                              R = curve radius (ft)

                                              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                              Maximum Length of Spiral

                                              L = (24pmaxR)12

                                              Where

                                              L = maximum length of spiral (ft)

                                              R = curve radius (ft)

                                              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                              Length of Spiralo AASHTO also provides recommended spiral lengths

                                              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                              o Design Note For construction purposes round your designs to a reasonable values eg

                                              Ls = 147 feet round it to

                                              Ls = 150 feet

                                              Source Iowa DOT Design Manual

                                              SPIRAL TERMINOLOGY

                                              Source Iowa DOT Design Manual

                                              Source Iowa DOT Design Manual

                                              Source Iowa DOT Design Manual

                                              Attainment of Superelevationon spiral curves

                                              See sketches that follow

                                              Normal Crown (DOT ndash pt A)

                                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                                              65Source Iowa DOT Standard Road Plans RP-2

                                              With Spirals

                                              Same as point E of GB

                                              With Spirals

                                              Tangent runout (A to B)

                                              With Spirals

                                              Removal of crown

                                              With Spirals

                                              Transition of superelevation

                                              Full superelevation

                                              69

                                              • Slide 1
                                              • Geometric Design ndash Basic Principles
                                              • GEOMETRIC DESIGN ndash Course Heads
                                              • Slide 4
                                              • Curves
                                              • Horizontal Curves
                                              • Design Elements
                                              • Slide 8
                                              • Slide 9
                                              • Slide 10
                                              • Slide 11
                                              • Horizontal Curves
                                              • Slide 13
                                              • Slide 14
                                              • Slide 15
                                              • Slide 16
                                              • Slide 17
                                              • Slide 18
                                              • Horizontal Curve Sight Distance
                                              • Slide 20
                                              • Slide 21
                                              • Slide 22
                                              • Slide 23
                                              • Slide 24
                                              • Slide 25
                                              • TRANSITIONS Superelevation Spiral Curves
                                              • Superelevation
                                              • Image
                                              • Superelevation Transitioning
                                              • Slide 30
                                              • Attainment of Superelevation - General
                                              • Tangent Runout Section
                                              • Superelevation Runoff Section
                                              • Slide 34
                                              • Slide 35
                                              • Slide 36
                                              • Slide 37
                                              • Slide 38
                                              • Slide 39
                                              • Slide 40
                                              • Slide 41
                                              • Attainment Location - WHERE
                                              • Minimum Length of Runoff for curve
                                              • Minimum Length of Tangent Runout
                                              • Length of Superelevation Runoff
                                              • Relative Gradient (G)
                                              • Maximum Relative Gradient (G)
                                              • Multilane Adjustment
                                              • Length of Superelevation Runoff Example
                                              • Slide 50
                                              • Tangent runout length Example continued
                                              • Slide 52
                                              • Spiral Curve Transitions
                                              • Slide 54
                                              • Spirals
                                              • Minimum Length of Spiral
                                              • Slide 57
                                              • Maximum Length of Spiral
                                              • Length of Spiral
                                              • Slide 60
                                              • Slide 61
                                              • Slide 62
                                              • Slide 63
                                              • Attainment of Superelevation on spiral curves
                                              • Slide 65
                                              • Slide 66
                                              • Slide 67
                                              • Slide 68
                                              • Slide 69

                                                Curves

                                                Curves

                                                TRANSITIONSTRANSITIONS

                                                SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                                TRANSITIONSTRANSITIONS

                                                SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                                Superelevation

                                                Image

                                                httptechalivemtuedumodulesmodule0003Superelevationhtm

                                                Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                                design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                                In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                                Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                                Superelevation Although superelevation is advantageous for traffic

                                                operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                Attainment of Superelevation - General

                                                bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                bull Change in pavement slope should be consistent over a distance

                                                Tangent Runout Section Superelevation Runoff Section bull Methods

                                                bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                Tangent Runout Section

                                                Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                For rotation about centerline

                                                Superelevation Runoff Section

                                                Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                For undivided highways with cross-section rotated about centerline

                                                Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                transition from a normal crown section which is accomplished by rotating the pavement

                                                The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                Cross section (-a-) is the normal crown section where the transitioning begins

                                                Cross section (-b-) is reached by rotating half the pavement until it is level

                                                Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                39

                                                40

                                                Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                Same as point E of GB

                                                Attainment Location - WHERE

                                                Superelevation must be attained over a length that includes the tangent and the curve

                                                Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                Super runoff is all attained in Spiral if used

                                                Minimum Length of Runoff for curve

                                                Lr based on drainage and aesthetics

                                                rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                Minimum Length of Tangent Runout

                                                Lt = eNC x Lr

                                                ed

                                                where

                                                eNC = normal cross slope rate ()

                                                ed = design superelevation rate

                                                Lr = minimum length of superelevation runoff (ft)

                                                (Result is the edge slope is same as for Runoff segment)

                                                Length of Superelevation Runoff

                                                α = multilane adjustment factor adjusts for total width

                                                r

                                                Relative Gradient (G)

                                                Maximum longitudinal slope Depends on design speed higher speed =

                                                gentler slope

                                                For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                Maximum Relative Gradient (G)

                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                Multilane Adjustment

                                                Runout and runoff must be adjusted for multilane rotation

                                                See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                Length of Superelevation Runoff Example

                                                For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                Lr = 12eα

                                                G

                                                50

                                                Lr = 12eα = (12) (004) (15)

                                                G 05

                                                Lr = 144 feet

                                                Tangent runout length Example continued

                                                Lt = (eNC ed ) x Lr

                                                as defined previously if NC = 2

                                                Tangent runout for the example is

                                                LT = 2 4 144rsquo = 72 feet

                                                52

                                                From previous example speed = 50 mph e = 4

                                                From chart runoff = 144 feet same as from calculation

                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                leave a horizontal curve

                                                Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                Spirals Advantages

                                                Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                Provides location for superelevation runoff (not part on tangentcurve)

                                                Provides transition in width when horizontal curve is widened

                                                Aesthetic

                                                Minimum Length of Spiral

                                                Possible Equations

                                                Larger of (1) L = 315 V3

                                                RC

                                                Where

                                                L = minimum length of spiral (ft)

                                                V = speed (mph)

                                                R = curve radius (ft)

                                                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                Minimum Length of Spiral

                                                Or (2) L = (24pminR)12

                                                Where

                                                L = minimum length of spiral (ft)

                                                R = curve radius (ft)

                                                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                Maximum Length of Spiral

                                                L = (24pmaxR)12

                                                Where

                                                L = maximum length of spiral (ft)

                                                R = curve radius (ft)

                                                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                Length of Spiralo AASHTO also provides recommended spiral lengths

                                                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                o Design Note For construction purposes round your designs to a reasonable values eg

                                                Ls = 147 feet round it to

                                                Ls = 150 feet

                                                Source Iowa DOT Design Manual

                                                SPIRAL TERMINOLOGY

                                                Source Iowa DOT Design Manual

                                                Source Iowa DOT Design Manual

                                                Source Iowa DOT Design Manual

                                                Attainment of Superelevationon spiral curves

                                                See sketches that follow

                                                Normal Crown (DOT ndash pt A)

                                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                65Source Iowa DOT Standard Road Plans RP-2

                                                With Spirals

                                                Same as point E of GB

                                                With Spirals

                                                Tangent runout (A to B)

                                                With Spirals

                                                Removal of crown

                                                With Spirals

                                                Transition of superelevation

                                                Full superelevation

                                                69

                                                • Slide 1
                                                • Geometric Design ndash Basic Principles
                                                • GEOMETRIC DESIGN ndash Course Heads
                                                • Slide 4
                                                • Curves
                                                • Horizontal Curves
                                                • Design Elements
                                                • Slide 8
                                                • Slide 9
                                                • Slide 10
                                                • Slide 11
                                                • Horizontal Curves
                                                • Slide 13
                                                • Slide 14
                                                • Slide 15
                                                • Slide 16
                                                • Slide 17
                                                • Slide 18
                                                • Horizontal Curve Sight Distance
                                                • Slide 20
                                                • Slide 21
                                                • Slide 22
                                                • Slide 23
                                                • Slide 24
                                                • Slide 25
                                                • TRANSITIONS Superelevation Spiral Curves
                                                • Superelevation
                                                • Image
                                                • Superelevation Transitioning
                                                • Slide 30
                                                • Attainment of Superelevation - General
                                                • Tangent Runout Section
                                                • Superelevation Runoff Section
                                                • Slide 34
                                                • Slide 35
                                                • Slide 36
                                                • Slide 37
                                                • Slide 38
                                                • Slide 39
                                                • Slide 40
                                                • Slide 41
                                                • Attainment Location - WHERE
                                                • Minimum Length of Runoff for curve
                                                • Minimum Length of Tangent Runout
                                                • Length of Superelevation Runoff
                                                • Relative Gradient (G)
                                                • Maximum Relative Gradient (G)
                                                • Multilane Adjustment
                                                • Length of Superelevation Runoff Example
                                                • Slide 50
                                                • Tangent runout length Example continued
                                                • Slide 52
                                                • Spiral Curve Transitions
                                                • Slide 54
                                                • Spirals
                                                • Minimum Length of Spiral
                                                • Slide 57
                                                • Maximum Length of Spiral
                                                • Length of Spiral
                                                • Slide 60
                                                • Slide 61
                                                • Slide 62
                                                • Slide 63
                                                • Attainment of Superelevation on spiral curves
                                                • Slide 65
                                                • Slide 66
                                                • Slide 67
                                                • Slide 68
                                                • Slide 69

                                                  Curves

                                                  TRANSITIONSTRANSITIONS

                                                  SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                                  TRANSITIONSTRANSITIONS

                                                  SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                                  Superelevation

                                                  Image

                                                  httptechalivemtuedumodulesmodule0003Superelevationhtm

                                                  Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                                  design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                                  In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                                  Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                                  Superelevation Although superelevation is advantageous for traffic

                                                  operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                  Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                  Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                  Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                  Attainment of Superelevation - General

                                                  bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                  bull Change in pavement slope should be consistent over a distance

                                                  Tangent Runout Section Superelevation Runoff Section bull Methods

                                                  bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                  Tangent Runout Section

                                                  Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                  For rotation about centerline

                                                  Superelevation Runoff Section

                                                  Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                  For undivided highways with cross-section rotated about centerline

                                                  Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                  transition from a normal crown section which is accomplished by rotating the pavement

                                                  The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                  Cross section (-a-) is the normal crown section where the transitioning begins

                                                  Cross section (-b-) is reached by rotating half the pavement until it is level

                                                  Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                  Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                  Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                  Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                  This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                  Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                  Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                  This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                  Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                  The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                  39

                                                  40

                                                  Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                  Same as point E of GB

                                                  Attainment Location - WHERE

                                                  Superelevation must be attained over a length that includes the tangent and the curve

                                                  Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                  Super runoff is all attained in Spiral if used

                                                  Minimum Length of Runoff for curve

                                                  Lr based on drainage and aesthetics

                                                  rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                  current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                  Minimum Length of Tangent Runout

                                                  Lt = eNC x Lr

                                                  ed

                                                  where

                                                  eNC = normal cross slope rate ()

                                                  ed = design superelevation rate

                                                  Lr = minimum length of superelevation runoff (ft)

                                                  (Result is the edge slope is same as for Runoff segment)

                                                  Length of Superelevation Runoff

                                                  α = multilane adjustment factor adjusts for total width

                                                  r

                                                  Relative Gradient (G)

                                                  Maximum longitudinal slope Depends on design speed higher speed =

                                                  gentler slope

                                                  For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                  Maximum Relative Gradient (G)

                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                  Multilane Adjustment

                                                  Runout and runoff must be adjusted for multilane rotation

                                                  See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                  Length of Superelevation Runoff Example

                                                  For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                  Lr = 12eα

                                                  G

                                                  50

                                                  Lr = 12eα = (12) (004) (15)

                                                  G 05

                                                  Lr = 144 feet

                                                  Tangent runout length Example continued

                                                  Lt = (eNC ed ) x Lr

                                                  as defined previously if NC = 2

                                                  Tangent runout for the example is

                                                  LT = 2 4 144rsquo = 72 feet

                                                  52

                                                  From previous example speed = 50 mph e = 4

                                                  From chart runoff = 144 feet same as from calculation

                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                  Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                  Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                  leave a horizontal curve

                                                  Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                  Spirals Advantages

                                                  Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                  Provides location for superelevation runoff (not part on tangentcurve)

                                                  Provides transition in width when horizontal curve is widened

                                                  Aesthetic

                                                  Minimum Length of Spiral

                                                  Possible Equations

                                                  Larger of (1) L = 315 V3

                                                  RC

                                                  Where

                                                  L = minimum length of spiral (ft)

                                                  V = speed (mph)

                                                  R = curve radius (ft)

                                                  C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                  Minimum Length of Spiral

                                                  Or (2) L = (24pminR)12

                                                  Where

                                                  L = minimum length of spiral (ft)

                                                  R = curve radius (ft)

                                                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                  Maximum Length of Spiral

                                                  L = (24pmaxR)12

                                                  Where

                                                  L = maximum length of spiral (ft)

                                                  R = curve radius (ft)

                                                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                  Length of Spiralo AASHTO also provides recommended spiral lengths

                                                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                  o Design Note For construction purposes round your designs to a reasonable values eg

                                                  Ls = 147 feet round it to

                                                  Ls = 150 feet

                                                  Source Iowa DOT Design Manual

                                                  SPIRAL TERMINOLOGY

                                                  Source Iowa DOT Design Manual

                                                  Source Iowa DOT Design Manual

                                                  Source Iowa DOT Design Manual

                                                  Attainment of Superelevationon spiral curves

                                                  See sketches that follow

                                                  Normal Crown (DOT ndash pt A)

                                                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                  65Source Iowa DOT Standard Road Plans RP-2

                                                  With Spirals

                                                  Same as point E of GB

                                                  With Spirals

                                                  Tangent runout (A to B)

                                                  With Spirals

                                                  Removal of crown

                                                  With Spirals

                                                  Transition of superelevation

                                                  Full superelevation

                                                  69

                                                  • Slide 1
                                                  • Geometric Design ndash Basic Principles
                                                  • GEOMETRIC DESIGN ndash Course Heads
                                                  • Slide 4
                                                  • Curves
                                                  • Horizontal Curves
                                                  • Design Elements
                                                  • Slide 8
                                                  • Slide 9
                                                  • Slide 10
                                                  • Slide 11
                                                  • Horizontal Curves
                                                  • Slide 13
                                                  • Slide 14
                                                  • Slide 15
                                                  • Slide 16
                                                  • Slide 17
                                                  • Slide 18
                                                  • Horizontal Curve Sight Distance
                                                  • Slide 20
                                                  • Slide 21
                                                  • Slide 22
                                                  • Slide 23
                                                  • Slide 24
                                                  • Slide 25
                                                  • TRANSITIONS Superelevation Spiral Curves
                                                  • Superelevation
                                                  • Image
                                                  • Superelevation Transitioning
                                                  • Slide 30
                                                  • Attainment of Superelevation - General
                                                  • Tangent Runout Section
                                                  • Superelevation Runoff Section
                                                  • Slide 34
                                                  • Slide 35
                                                  • Slide 36
                                                  • Slide 37
                                                  • Slide 38
                                                  • Slide 39
                                                  • Slide 40
                                                  • Slide 41
                                                  • Attainment Location - WHERE
                                                  • Minimum Length of Runoff for curve
                                                  • Minimum Length of Tangent Runout
                                                  • Length of Superelevation Runoff
                                                  • Relative Gradient (G)
                                                  • Maximum Relative Gradient (G)
                                                  • Multilane Adjustment
                                                  • Length of Superelevation Runoff Example
                                                  • Slide 50
                                                  • Tangent runout length Example continued
                                                  • Slide 52
                                                  • Spiral Curve Transitions
                                                  • Slide 54
                                                  • Spirals
                                                  • Minimum Length of Spiral
                                                  • Slide 57
                                                  • Maximum Length of Spiral
                                                  • Length of Spiral
                                                  • Slide 60
                                                  • Slide 61
                                                  • Slide 62
                                                  • Slide 63
                                                  • Attainment of Superelevation on spiral curves
                                                  • Slide 65
                                                  • Slide 66
                                                  • Slide 67
                                                  • Slide 68
                                                  • Slide 69

                                                    TRANSITIONSTRANSITIONS

                                                    SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                                    TRANSITIONSTRANSITIONS

                                                    SuperelevationSuperelevationSpiral CurvesSpiral Curves

                                                    Superelevation

                                                    Image

                                                    httptechalivemtuedumodulesmodule0003Superelevationhtm

                                                    Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                                    design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                                    In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                                    Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                                    Superelevation Although superelevation is advantageous for traffic

                                                    operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                    Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                    Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                    Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                    Attainment of Superelevation - General

                                                    bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                    bull Change in pavement slope should be consistent over a distance

                                                    Tangent Runout Section Superelevation Runoff Section bull Methods

                                                    bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                    Tangent Runout Section

                                                    Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                    For rotation about centerline

                                                    Superelevation Runoff Section

                                                    Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                    For undivided highways with cross-section rotated about centerline

                                                    Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                    transition from a normal crown section which is accomplished by rotating the pavement

                                                    The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                    Cross section (-a-) is the normal crown section where the transitioning begins

                                                    Cross section (-b-) is reached by rotating half the pavement until it is level

                                                    Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                    Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                    Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                    Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                    This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                    Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                    Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                    This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                    Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                    The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                    39

                                                    40

                                                    Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                    Same as point E of GB

                                                    Attainment Location - WHERE

                                                    Superelevation must be attained over a length that includes the tangent and the curve

                                                    Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                    Super runoff is all attained in Spiral if used

                                                    Minimum Length of Runoff for curve

                                                    Lr based on drainage and aesthetics

                                                    rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                    current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                    Minimum Length of Tangent Runout

                                                    Lt = eNC x Lr

                                                    ed

                                                    where

                                                    eNC = normal cross slope rate ()

                                                    ed = design superelevation rate

                                                    Lr = minimum length of superelevation runoff (ft)

                                                    (Result is the edge slope is same as for Runoff segment)

                                                    Length of Superelevation Runoff

                                                    α = multilane adjustment factor adjusts for total width

                                                    r

                                                    Relative Gradient (G)

                                                    Maximum longitudinal slope Depends on design speed higher speed =

                                                    gentler slope

                                                    For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                    Maximum Relative Gradient (G)

                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                    Multilane Adjustment

                                                    Runout and runoff must be adjusted for multilane rotation

                                                    See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                    Length of Superelevation Runoff Example

                                                    For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                    Lr = 12eα

                                                    G

                                                    50

                                                    Lr = 12eα = (12) (004) (15)

                                                    G 05

                                                    Lr = 144 feet

                                                    Tangent runout length Example continued

                                                    Lt = (eNC ed ) x Lr

                                                    as defined previously if NC = 2

                                                    Tangent runout for the example is

                                                    LT = 2 4 144rsquo = 72 feet

                                                    52

                                                    From previous example speed = 50 mph e = 4

                                                    From chart runoff = 144 feet same as from calculation

                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                    Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                    leave a horizontal curve

                                                    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                    Spirals Advantages

                                                    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                    Provides location for superelevation runoff (not part on tangentcurve)

                                                    Provides transition in width when horizontal curve is widened

                                                    Aesthetic

                                                    Minimum Length of Spiral

                                                    Possible Equations

                                                    Larger of (1) L = 315 V3

                                                    RC

                                                    Where

                                                    L = minimum length of spiral (ft)

                                                    V = speed (mph)

                                                    R = curve radius (ft)

                                                    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                    Minimum Length of Spiral

                                                    Or (2) L = (24pminR)12

                                                    Where

                                                    L = minimum length of spiral (ft)

                                                    R = curve radius (ft)

                                                    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                    Maximum Length of Spiral

                                                    L = (24pmaxR)12

                                                    Where

                                                    L = maximum length of spiral (ft)

                                                    R = curve radius (ft)

                                                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                    Length of Spiralo AASHTO also provides recommended spiral lengths

                                                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                    o Design Note For construction purposes round your designs to a reasonable values eg

                                                    Ls = 147 feet round it to

                                                    Ls = 150 feet

                                                    Source Iowa DOT Design Manual

                                                    SPIRAL TERMINOLOGY

                                                    Source Iowa DOT Design Manual

                                                    Source Iowa DOT Design Manual

                                                    Source Iowa DOT Design Manual

                                                    Attainment of Superelevationon spiral curves

                                                    See sketches that follow

                                                    Normal Crown (DOT ndash pt A)

                                                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                    65Source Iowa DOT Standard Road Plans RP-2

                                                    With Spirals

                                                    Same as point E of GB

                                                    With Spirals

                                                    Tangent runout (A to B)

                                                    With Spirals

                                                    Removal of crown

                                                    With Spirals

                                                    Transition of superelevation

                                                    Full superelevation

                                                    69

                                                    • Slide 1
                                                    • Geometric Design ndash Basic Principles
                                                    • GEOMETRIC DESIGN ndash Course Heads
                                                    • Slide 4
                                                    • Curves
                                                    • Horizontal Curves
                                                    • Design Elements
                                                    • Slide 8
                                                    • Slide 9
                                                    • Slide 10
                                                    • Slide 11
                                                    • Horizontal Curves
                                                    • Slide 13
                                                    • Slide 14
                                                    • Slide 15
                                                    • Slide 16
                                                    • Slide 17
                                                    • Slide 18
                                                    • Horizontal Curve Sight Distance
                                                    • Slide 20
                                                    • Slide 21
                                                    • Slide 22
                                                    • Slide 23
                                                    • Slide 24
                                                    • Slide 25
                                                    • TRANSITIONS Superelevation Spiral Curves
                                                    • Superelevation
                                                    • Image
                                                    • Superelevation Transitioning
                                                    • Slide 30
                                                    • Attainment of Superelevation - General
                                                    • Tangent Runout Section
                                                    • Superelevation Runoff Section
                                                    • Slide 34
                                                    • Slide 35
                                                    • Slide 36
                                                    • Slide 37
                                                    • Slide 38
                                                    • Slide 39
                                                    • Slide 40
                                                    • Slide 41
                                                    • Attainment Location - WHERE
                                                    • Minimum Length of Runoff for curve
                                                    • Minimum Length of Tangent Runout
                                                    • Length of Superelevation Runoff
                                                    • Relative Gradient (G)
                                                    • Maximum Relative Gradient (G)
                                                    • Multilane Adjustment
                                                    • Length of Superelevation Runoff Example
                                                    • Slide 50
                                                    • Tangent runout length Example continued
                                                    • Slide 52
                                                    • Spiral Curve Transitions
                                                    • Slide 54
                                                    • Spirals
                                                    • Minimum Length of Spiral
                                                    • Slide 57
                                                    • Maximum Length of Spiral
                                                    • Length of Spiral
                                                    • Slide 60
                                                    • Slide 61
                                                    • Slide 62
                                                    • Slide 63
                                                    • Attainment of Superelevation on spiral curves
                                                    • Slide 65
                                                    • Slide 66
                                                    • Slide 67
                                                    • Slide 68
                                                    • Slide 69

                                                      Superelevation

                                                      Image

                                                      httptechalivemtuedumodulesmodule0003Superelevationhtm

                                                      Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                                      design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                                      In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                                      Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                                      Superelevation Although superelevation is advantageous for traffic

                                                      operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                      Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                      Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                      Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                      Attainment of Superelevation - General

                                                      bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                      bull Change in pavement slope should be consistent over a distance

                                                      Tangent Runout Section Superelevation Runoff Section bull Methods

                                                      bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                      Tangent Runout Section

                                                      Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                      For rotation about centerline

                                                      Superelevation Runoff Section

                                                      Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                      For undivided highways with cross-section rotated about centerline

                                                      Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                      transition from a normal crown section which is accomplished by rotating the pavement

                                                      The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                      Cross section (-a-) is the normal crown section where the transitioning begins

                                                      Cross section (-b-) is reached by rotating half the pavement until it is level

                                                      Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                      Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                      Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                      Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                      This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                      Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                      Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                      This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                      Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                      The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                      39

                                                      40

                                                      Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                      Same as point E of GB

                                                      Attainment Location - WHERE

                                                      Superelevation must be attained over a length that includes the tangent and the curve

                                                      Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                      Super runoff is all attained in Spiral if used

                                                      Minimum Length of Runoff for curve

                                                      Lr based on drainage and aesthetics

                                                      rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                      current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                      Minimum Length of Tangent Runout

                                                      Lt = eNC x Lr

                                                      ed

                                                      where

                                                      eNC = normal cross slope rate ()

                                                      ed = design superelevation rate

                                                      Lr = minimum length of superelevation runoff (ft)

                                                      (Result is the edge slope is same as for Runoff segment)

                                                      Length of Superelevation Runoff

                                                      α = multilane adjustment factor adjusts for total width

                                                      r

                                                      Relative Gradient (G)

                                                      Maximum longitudinal slope Depends on design speed higher speed =

                                                      gentler slope

                                                      For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                      Maximum Relative Gradient (G)

                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                      Multilane Adjustment

                                                      Runout and runoff must be adjusted for multilane rotation

                                                      See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                      Length of Superelevation Runoff Example

                                                      For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                      Lr = 12eα

                                                      G

                                                      50

                                                      Lr = 12eα = (12) (004) (15)

                                                      G 05

                                                      Lr = 144 feet

                                                      Tangent runout length Example continued

                                                      Lt = (eNC ed ) x Lr

                                                      as defined previously if NC = 2

                                                      Tangent runout for the example is

                                                      LT = 2 4 144rsquo = 72 feet

                                                      52

                                                      From previous example speed = 50 mph e = 4

                                                      From chart runoff = 144 feet same as from calculation

                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                      Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                      leave a horizontal curve

                                                      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                      Spirals Advantages

                                                      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                      Provides location for superelevation runoff (not part on tangentcurve)

                                                      Provides transition in width when horizontal curve is widened

                                                      Aesthetic

                                                      Minimum Length of Spiral

                                                      Possible Equations

                                                      Larger of (1) L = 315 V3

                                                      RC

                                                      Where

                                                      L = minimum length of spiral (ft)

                                                      V = speed (mph)

                                                      R = curve radius (ft)

                                                      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                      Minimum Length of Spiral

                                                      Or (2) L = (24pminR)12

                                                      Where

                                                      L = minimum length of spiral (ft)

                                                      R = curve radius (ft)

                                                      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                      Maximum Length of Spiral

                                                      L = (24pmaxR)12

                                                      Where

                                                      L = maximum length of spiral (ft)

                                                      R = curve radius (ft)

                                                      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                      Length of Spiralo AASHTO also provides recommended spiral lengths

                                                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                      o Design Note For construction purposes round your designs to a reasonable values eg

                                                      Ls = 147 feet round it to

                                                      Ls = 150 feet

                                                      Source Iowa DOT Design Manual

                                                      SPIRAL TERMINOLOGY

                                                      Source Iowa DOT Design Manual

                                                      Source Iowa DOT Design Manual

                                                      Source Iowa DOT Design Manual

                                                      Attainment of Superelevationon spiral curves

                                                      See sketches that follow

                                                      Normal Crown (DOT ndash pt A)

                                                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                      65Source Iowa DOT Standard Road Plans RP-2

                                                      With Spirals

                                                      Same as point E of GB

                                                      With Spirals

                                                      Tangent runout (A to B)

                                                      With Spirals

                                                      Removal of crown

                                                      With Spirals

                                                      Transition of superelevation

                                                      Full superelevation

                                                      69

                                                      • Slide 1
                                                      • Geometric Design ndash Basic Principles
                                                      • GEOMETRIC DESIGN ndash Course Heads
                                                      • Slide 4
                                                      • Curves
                                                      • Horizontal Curves
                                                      • Design Elements
                                                      • Slide 8
                                                      • Slide 9
                                                      • Slide 10
                                                      • Slide 11
                                                      • Horizontal Curves
                                                      • Slide 13
                                                      • Slide 14
                                                      • Slide 15
                                                      • Slide 16
                                                      • Slide 17
                                                      • Slide 18
                                                      • Horizontal Curve Sight Distance
                                                      • Slide 20
                                                      • Slide 21
                                                      • Slide 22
                                                      • Slide 23
                                                      • Slide 24
                                                      • Slide 25
                                                      • TRANSITIONS Superelevation Spiral Curves
                                                      • Superelevation
                                                      • Image
                                                      • Superelevation Transitioning
                                                      • Slide 30
                                                      • Attainment of Superelevation - General
                                                      • Tangent Runout Section
                                                      • Superelevation Runoff Section
                                                      • Slide 34
                                                      • Slide 35
                                                      • Slide 36
                                                      • Slide 37
                                                      • Slide 38
                                                      • Slide 39
                                                      • Slide 40
                                                      • Slide 41
                                                      • Attainment Location - WHERE
                                                      • Minimum Length of Runoff for curve
                                                      • Minimum Length of Tangent Runout
                                                      • Length of Superelevation Runoff
                                                      • Relative Gradient (G)
                                                      • Maximum Relative Gradient (G)
                                                      • Multilane Adjustment
                                                      • Length of Superelevation Runoff Example
                                                      • Slide 50
                                                      • Tangent runout length Example continued
                                                      • Slide 52
                                                      • Spiral Curve Transitions
                                                      • Slide 54
                                                      • Spirals
                                                      • Minimum Length of Spiral
                                                      • Slide 57
                                                      • Maximum Length of Spiral
                                                      • Length of Spiral
                                                      • Slide 60
                                                      • Slide 61
                                                      • Slide 62
                                                      • Slide 63
                                                      • Attainment of Superelevation on spiral curves
                                                      • Slide 65
                                                      • Slide 66
                                                      • Slide 67
                                                      • Slide 68
                                                      • Slide 69

                                                        Image

                                                        httptechalivemtuedumodulesmodule0003Superelevationhtm

                                                        Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                                        design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                                        In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                                        Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                                        Superelevation Although superelevation is advantageous for traffic

                                                        operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                        Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                        Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                        Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                        Attainment of Superelevation - General

                                                        bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                        bull Change in pavement slope should be consistent over a distance

                                                        Tangent Runout Section Superelevation Runoff Section bull Methods

                                                        bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                        Tangent Runout Section

                                                        Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                        For rotation about centerline

                                                        Superelevation Runoff Section

                                                        Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                        For undivided highways with cross-section rotated about centerline

                                                        Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                        transition from a normal crown section which is accomplished by rotating the pavement

                                                        The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                        Cross section (-a-) is the normal crown section where the transitioning begins

                                                        Cross section (-b-) is reached by rotating half the pavement until it is level

                                                        Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                        Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                        Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                        Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                        This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                        Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                        Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                        This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                        Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                        The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                        39

                                                        40

                                                        Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                        Same as point E of GB

                                                        Attainment Location - WHERE

                                                        Superelevation must be attained over a length that includes the tangent and the curve

                                                        Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                        Super runoff is all attained in Spiral if used

                                                        Minimum Length of Runoff for curve

                                                        Lr based on drainage and aesthetics

                                                        rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                        current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                        Minimum Length of Tangent Runout

                                                        Lt = eNC x Lr

                                                        ed

                                                        where

                                                        eNC = normal cross slope rate ()

                                                        ed = design superelevation rate

                                                        Lr = minimum length of superelevation runoff (ft)

                                                        (Result is the edge slope is same as for Runoff segment)

                                                        Length of Superelevation Runoff

                                                        α = multilane adjustment factor adjusts for total width

                                                        r

                                                        Relative Gradient (G)

                                                        Maximum longitudinal slope Depends on design speed higher speed =

                                                        gentler slope

                                                        For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                        Maximum Relative Gradient (G)

                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                        Multilane Adjustment

                                                        Runout and runoff must be adjusted for multilane rotation

                                                        See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                        Length of Superelevation Runoff Example

                                                        For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                        Lr = 12eα

                                                        G

                                                        50

                                                        Lr = 12eα = (12) (004) (15)

                                                        G 05

                                                        Lr = 144 feet

                                                        Tangent runout length Example continued

                                                        Lt = (eNC ed ) x Lr

                                                        as defined previously if NC = 2

                                                        Tangent runout for the example is

                                                        LT = 2 4 144rsquo = 72 feet

                                                        52

                                                        From previous example speed = 50 mph e = 4

                                                        From chart runoff = 144 feet same as from calculation

                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                        Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                        leave a horizontal curve

                                                        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                        Spirals Advantages

                                                        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                        Provides location for superelevation runoff (not part on tangentcurve)

                                                        Provides transition in width when horizontal curve is widened

                                                        Aesthetic

                                                        Minimum Length of Spiral

                                                        Possible Equations

                                                        Larger of (1) L = 315 V3

                                                        RC

                                                        Where

                                                        L = minimum length of spiral (ft)

                                                        V = speed (mph)

                                                        R = curve radius (ft)

                                                        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                        Minimum Length of Spiral

                                                        Or (2) L = (24pminR)12

                                                        Where

                                                        L = minimum length of spiral (ft)

                                                        R = curve radius (ft)

                                                        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                        Maximum Length of Spiral

                                                        L = (24pmaxR)12

                                                        Where

                                                        L = maximum length of spiral (ft)

                                                        R = curve radius (ft)

                                                        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                        Length of Spiralo AASHTO also provides recommended spiral lengths

                                                        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                        o Design Note For construction purposes round your designs to a reasonable values eg

                                                        Ls = 147 feet round it to

                                                        Ls = 150 feet

                                                        Source Iowa DOT Design Manual

                                                        SPIRAL TERMINOLOGY

                                                        Source Iowa DOT Design Manual

                                                        Source Iowa DOT Design Manual

                                                        Source Iowa DOT Design Manual

                                                        Attainment of Superelevationon spiral curves

                                                        See sketches that follow

                                                        Normal Crown (DOT ndash pt A)

                                                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                        65Source Iowa DOT Standard Road Plans RP-2

                                                        With Spirals

                                                        Same as point E of GB

                                                        With Spirals

                                                        Tangent runout (A to B)

                                                        With Spirals

                                                        Removal of crown

                                                        With Spirals

                                                        Transition of superelevation

                                                        Full superelevation

                                                        69

                                                        • Slide 1
                                                        • Geometric Design ndash Basic Principles
                                                        • GEOMETRIC DESIGN ndash Course Heads
                                                        • Slide 4
                                                        • Curves
                                                        • Horizontal Curves
                                                        • Design Elements
                                                        • Slide 8
                                                        • Slide 9
                                                        • Slide 10
                                                        • Slide 11
                                                        • Horizontal Curves
                                                        • Slide 13
                                                        • Slide 14
                                                        • Slide 15
                                                        • Slide 16
                                                        • Slide 17
                                                        • Slide 18
                                                        • Horizontal Curve Sight Distance
                                                        • Slide 20
                                                        • Slide 21
                                                        • Slide 22
                                                        • Slide 23
                                                        • Slide 24
                                                        • Slide 25
                                                        • TRANSITIONS Superelevation Spiral Curves
                                                        • Superelevation
                                                        • Image
                                                        • Superelevation Transitioning
                                                        • Slide 30
                                                        • Attainment of Superelevation - General
                                                        • Tangent Runout Section
                                                        • Superelevation Runoff Section
                                                        • Slide 34
                                                        • Slide 35
                                                        • Slide 36
                                                        • Slide 37
                                                        • Slide 38
                                                        • Slide 39
                                                        • Slide 40
                                                        • Slide 41
                                                        • Attainment Location - WHERE
                                                        • Minimum Length of Runoff for curve
                                                        • Minimum Length of Tangent Runout
                                                        • Length of Superelevation Runoff
                                                        • Relative Gradient (G)
                                                        • Maximum Relative Gradient (G)
                                                        • Multilane Adjustment
                                                        • Length of Superelevation Runoff Example
                                                        • Slide 50
                                                        • Tangent runout length Example continued
                                                        • Slide 52
                                                        • Spiral Curve Transitions
                                                        • Slide 54
                                                        • Spirals
                                                        • Minimum Length of Spiral
                                                        • Slide 57
                                                        • Maximum Length of Spiral
                                                        • Length of Spiral
                                                        • Slide 60
                                                        • Slide 61
                                                        • Slide 62
                                                        • Slide 63
                                                        • Attainment of Superelevation on spiral curves
                                                        • Slide 65
                                                        • Slide 66
                                                        • Slide 67
                                                        • Slide 68
                                                        • Slide 69

                                                          Superelevation Transitioning Incorporating superelevation into a roadwayrsquos

                                                          design may help avoid roadside obstacles that might otherwise be impacted by the alignment

                                                          In contrast superelevation may not be desirable for low-speed roadways to help limit excessive speeds or in urban settings to limit impacts to abutting uses or drainage systems and utilities

                                                          Moreover superelevation may not be desirable when considering pedestrian or bicycle accommodations along the roadway segment Like other roadway design elements designers must consider the trade-offs of introducing superelevation in a roadwayrsquos design

                                                          Superelevation Although superelevation is advantageous for traffic

                                                          operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                          Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                          Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                          Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                          Attainment of Superelevation - General

                                                          bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                          bull Change in pavement slope should be consistent over a distance

                                                          Tangent Runout Section Superelevation Runoff Section bull Methods

                                                          bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                          Tangent Runout Section

                                                          Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                          For rotation about centerline

                                                          Superelevation Runoff Section

                                                          Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                          For undivided highways with cross-section rotated about centerline

                                                          Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                          transition from a normal crown section which is accomplished by rotating the pavement

                                                          The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                          Cross section (-a-) is the normal crown section where the transitioning begins

                                                          Cross section (-b-) is reached by rotating half the pavement until it is level

                                                          Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                          Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                          Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                          Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                          This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                          Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                          Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                          This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                          Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                          The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                          39

                                                          40

                                                          Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                          Same as point E of GB

                                                          Attainment Location - WHERE

                                                          Superelevation must be attained over a length that includes the tangent and the curve

                                                          Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                          Super runoff is all attained in Spiral if used

                                                          Minimum Length of Runoff for curve

                                                          Lr based on drainage and aesthetics

                                                          rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                          current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                          Minimum Length of Tangent Runout

                                                          Lt = eNC x Lr

                                                          ed

                                                          where

                                                          eNC = normal cross slope rate ()

                                                          ed = design superelevation rate

                                                          Lr = minimum length of superelevation runoff (ft)

                                                          (Result is the edge slope is same as for Runoff segment)

                                                          Length of Superelevation Runoff

                                                          α = multilane adjustment factor adjusts for total width

                                                          r

                                                          Relative Gradient (G)

                                                          Maximum longitudinal slope Depends on design speed higher speed =

                                                          gentler slope

                                                          For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                          Maximum Relative Gradient (G)

                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                          Multilane Adjustment

                                                          Runout and runoff must be adjusted for multilane rotation

                                                          See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                          Length of Superelevation Runoff Example

                                                          For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                          Lr = 12eα

                                                          G

                                                          50

                                                          Lr = 12eα = (12) (004) (15)

                                                          G 05

                                                          Lr = 144 feet

                                                          Tangent runout length Example continued

                                                          Lt = (eNC ed ) x Lr

                                                          as defined previously if NC = 2

                                                          Tangent runout for the example is

                                                          LT = 2 4 144rsquo = 72 feet

                                                          52

                                                          From previous example speed = 50 mph e = 4

                                                          From chart runoff = 144 feet same as from calculation

                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                          Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                          leave a horizontal curve

                                                          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                          Spirals Advantages

                                                          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                          Provides location for superelevation runoff (not part on tangentcurve)

                                                          Provides transition in width when horizontal curve is widened

                                                          Aesthetic

                                                          Minimum Length of Spiral

                                                          Possible Equations

                                                          Larger of (1) L = 315 V3

                                                          RC

                                                          Where

                                                          L = minimum length of spiral (ft)

                                                          V = speed (mph)

                                                          R = curve radius (ft)

                                                          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                          Minimum Length of Spiral

                                                          Or (2) L = (24pminR)12

                                                          Where

                                                          L = minimum length of spiral (ft)

                                                          R = curve radius (ft)

                                                          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                          Maximum Length of Spiral

                                                          L = (24pmaxR)12

                                                          Where

                                                          L = maximum length of spiral (ft)

                                                          R = curve radius (ft)

                                                          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                          Length of Spiralo AASHTO also provides recommended spiral lengths

                                                          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                          o Design Note For construction purposes round your designs to a reasonable values eg

                                                          Ls = 147 feet round it to

                                                          Ls = 150 feet

                                                          Source Iowa DOT Design Manual

                                                          SPIRAL TERMINOLOGY

                                                          Source Iowa DOT Design Manual

                                                          Source Iowa DOT Design Manual

                                                          Source Iowa DOT Design Manual

                                                          Attainment of Superelevationon spiral curves

                                                          See sketches that follow

                                                          Normal Crown (DOT ndash pt A)

                                                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                          65Source Iowa DOT Standard Road Plans RP-2

                                                          With Spirals

                                                          Same as point E of GB

                                                          With Spirals

                                                          Tangent runout (A to B)

                                                          With Spirals

                                                          Removal of crown

                                                          With Spirals

                                                          Transition of superelevation

                                                          Full superelevation

                                                          69

                                                          • Slide 1
                                                          • Geometric Design ndash Basic Principles
                                                          • GEOMETRIC DESIGN ndash Course Heads
                                                          • Slide 4
                                                          • Curves
                                                          • Horizontal Curves
                                                          • Design Elements
                                                          • Slide 8
                                                          • Slide 9
                                                          • Slide 10
                                                          • Slide 11
                                                          • Horizontal Curves
                                                          • Slide 13
                                                          • Slide 14
                                                          • Slide 15
                                                          • Slide 16
                                                          • Slide 17
                                                          • Slide 18
                                                          • Horizontal Curve Sight Distance
                                                          • Slide 20
                                                          • Slide 21
                                                          • Slide 22
                                                          • Slide 23
                                                          • Slide 24
                                                          • Slide 25
                                                          • TRANSITIONS Superelevation Spiral Curves
                                                          • Superelevation
                                                          • Image
                                                          • Superelevation Transitioning
                                                          • Slide 30
                                                          • Attainment of Superelevation - General
                                                          • Tangent Runout Section
                                                          • Superelevation Runoff Section
                                                          • Slide 34
                                                          • Slide 35
                                                          • Slide 36
                                                          • Slide 37
                                                          • Slide 38
                                                          • Slide 39
                                                          • Slide 40
                                                          • Slide 41
                                                          • Attainment Location - WHERE
                                                          • Minimum Length of Runoff for curve
                                                          • Minimum Length of Tangent Runout
                                                          • Length of Superelevation Runoff
                                                          • Relative Gradient (G)
                                                          • Maximum Relative Gradient (G)
                                                          • Multilane Adjustment
                                                          • Length of Superelevation Runoff Example
                                                          • Slide 50
                                                          • Tangent runout length Example continued
                                                          • Slide 52
                                                          • Spiral Curve Transitions
                                                          • Slide 54
                                                          • Spirals
                                                          • Minimum Length of Spiral
                                                          • Slide 57
                                                          • Maximum Length of Spiral
                                                          • Length of Spiral
                                                          • Slide 60
                                                          • Slide 61
                                                          • Slide 62
                                                          • Slide 63
                                                          • Attainment of Superelevation on spiral curves
                                                          • Slide 65
                                                          • Slide 66
                                                          • Slide 67
                                                          • Slide 68
                                                          • Slide 69

                                                            Superelevation Although superelevation is advantageous for traffic

                                                            operation various factors often combine to make its use impractical in many built-up areas (such as Suburban High Intensity Suburban Town Centers and Urban Areas)

                                                            Such factors include wide pavement areas the need to meet the grade of adjacent property surface drainage considerations and frequency of cross streets alleys and driveways

                                                            Therefore horizontal curves on low-speed roadways in urban areas may be designed without superelevation counteracting the centrifugal force solely with side friction

                                                            Designing without superelevation is often a suitable design practice for low-speed roadways (below 35 mph) or roadways in urban developed settings

                                                            Attainment of Superelevation - General

                                                            bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                            bull Change in pavement slope should be consistent over a distance

                                                            Tangent Runout Section Superelevation Runoff Section bull Methods

                                                            bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                            Tangent Runout Section

                                                            Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                            For rotation about centerline

                                                            Superelevation Runoff Section

                                                            Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                            For undivided highways with cross-section rotated about centerline

                                                            Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                            transition from a normal crown section which is accomplished by rotating the pavement

                                                            The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                            Cross section (-a-) is the normal crown section where the transitioning begins

                                                            Cross section (-b-) is reached by rotating half the pavement until it is level

                                                            Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                            Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                            Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                            Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                            This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                            Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                            Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                            This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                            Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                            The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                            39

                                                            40

                                                            Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                            Same as point E of GB

                                                            Attainment Location - WHERE

                                                            Superelevation must be attained over a length that includes the tangent and the curve

                                                            Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                            Super runoff is all attained in Spiral if used

                                                            Minimum Length of Runoff for curve

                                                            Lr based on drainage and aesthetics

                                                            rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                            current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                            Minimum Length of Tangent Runout

                                                            Lt = eNC x Lr

                                                            ed

                                                            where

                                                            eNC = normal cross slope rate ()

                                                            ed = design superelevation rate

                                                            Lr = minimum length of superelevation runoff (ft)

                                                            (Result is the edge slope is same as for Runoff segment)

                                                            Length of Superelevation Runoff

                                                            α = multilane adjustment factor adjusts for total width

                                                            r

                                                            Relative Gradient (G)

                                                            Maximum longitudinal slope Depends on design speed higher speed =

                                                            gentler slope

                                                            For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                            Maximum Relative Gradient (G)

                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                            Multilane Adjustment

                                                            Runout and runoff must be adjusted for multilane rotation

                                                            See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                            Length of Superelevation Runoff Example

                                                            For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                            Lr = 12eα

                                                            G

                                                            50

                                                            Lr = 12eα = (12) (004) (15)

                                                            G 05

                                                            Lr = 144 feet

                                                            Tangent runout length Example continued

                                                            Lt = (eNC ed ) x Lr

                                                            as defined previously if NC = 2

                                                            Tangent runout for the example is

                                                            LT = 2 4 144rsquo = 72 feet

                                                            52

                                                            From previous example speed = 50 mph e = 4

                                                            From chart runoff = 144 feet same as from calculation

                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                            Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                            Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                            leave a horizontal curve

                                                            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                            Spirals Advantages

                                                            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                            Provides location for superelevation runoff (not part on tangentcurve)

                                                            Provides transition in width when horizontal curve is widened

                                                            Aesthetic

                                                            Minimum Length of Spiral

                                                            Possible Equations

                                                            Larger of (1) L = 315 V3

                                                            RC

                                                            Where

                                                            L = minimum length of spiral (ft)

                                                            V = speed (mph)

                                                            R = curve radius (ft)

                                                            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                            Minimum Length of Spiral

                                                            Or (2) L = (24pminR)12

                                                            Where

                                                            L = minimum length of spiral (ft)

                                                            R = curve radius (ft)

                                                            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                            Maximum Length of Spiral

                                                            L = (24pmaxR)12

                                                            Where

                                                            L = maximum length of spiral (ft)

                                                            R = curve radius (ft)

                                                            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                            Length of Spiralo AASHTO also provides recommended spiral lengths

                                                            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                            o Design Note For construction purposes round your designs to a reasonable values eg

                                                            Ls = 147 feet round it to

                                                            Ls = 150 feet

                                                            Source Iowa DOT Design Manual

                                                            SPIRAL TERMINOLOGY

                                                            Source Iowa DOT Design Manual

                                                            Source Iowa DOT Design Manual

                                                            Source Iowa DOT Design Manual

                                                            Attainment of Superelevationon spiral curves

                                                            See sketches that follow

                                                            Normal Crown (DOT ndash pt A)

                                                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                            65Source Iowa DOT Standard Road Plans RP-2

                                                            With Spirals

                                                            Same as point E of GB

                                                            With Spirals

                                                            Tangent runout (A to B)

                                                            With Spirals

                                                            Removal of crown

                                                            With Spirals

                                                            Transition of superelevation

                                                            Full superelevation

                                                            69

                                                            • Slide 1
                                                            • Geometric Design ndash Basic Principles
                                                            • GEOMETRIC DESIGN ndash Course Heads
                                                            • Slide 4
                                                            • Curves
                                                            • Horizontal Curves
                                                            • Design Elements
                                                            • Slide 8
                                                            • Slide 9
                                                            • Slide 10
                                                            • Slide 11
                                                            • Horizontal Curves
                                                            • Slide 13
                                                            • Slide 14
                                                            • Slide 15
                                                            • Slide 16
                                                            • Slide 17
                                                            • Slide 18
                                                            • Horizontal Curve Sight Distance
                                                            • Slide 20
                                                            • Slide 21
                                                            • Slide 22
                                                            • Slide 23
                                                            • Slide 24
                                                            • Slide 25
                                                            • TRANSITIONS Superelevation Spiral Curves
                                                            • Superelevation
                                                            • Image
                                                            • Superelevation Transitioning
                                                            • Slide 30
                                                            • Attainment of Superelevation - General
                                                            • Tangent Runout Section
                                                            • Superelevation Runoff Section
                                                            • Slide 34
                                                            • Slide 35
                                                            • Slide 36
                                                            • Slide 37
                                                            • Slide 38
                                                            • Slide 39
                                                            • Slide 40
                                                            • Slide 41
                                                            • Attainment Location - WHERE
                                                            • Minimum Length of Runoff for curve
                                                            • Minimum Length of Tangent Runout
                                                            • Length of Superelevation Runoff
                                                            • Relative Gradient (G)
                                                            • Maximum Relative Gradient (G)
                                                            • Multilane Adjustment
                                                            • Length of Superelevation Runoff Example
                                                            • Slide 50
                                                            • Tangent runout length Example continued
                                                            • Slide 52
                                                            • Spiral Curve Transitions
                                                            • Slide 54
                                                            • Spirals
                                                            • Minimum Length of Spiral
                                                            • Slide 57
                                                            • Maximum Length of Spiral
                                                            • Length of Spiral
                                                            • Slide 60
                                                            • Slide 61
                                                            • Slide 62
                                                            • Slide 63
                                                            • Attainment of Superelevation on spiral curves
                                                            • Slide 65
                                                            • Slide 66
                                                            • Slide 67
                                                            • Slide 68
                                                            • Slide 69

                                                              Attainment of Superelevation - General

                                                              bull Must be done gradually over a distance without appreciable reduction in speed or safety and with comfort

                                                              bull Change in pavement slope should be consistent over a distance

                                                              Tangent Runout Section Superelevation Runoff Section bull Methods

                                                              bull Rotate pavement about centerline bull Rotate about inner edge of pavement bull Rotate about outside edge of pavement

                                                              Tangent Runout Section

                                                              Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                              For rotation about centerline

                                                              Superelevation Runoff Section

                                                              Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                              For undivided highways with cross-section rotated about centerline

                                                              Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                              transition from a normal crown section which is accomplished by rotating the pavement

                                                              The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                              Cross section (-a-) is the normal crown section where the transitioning begins

                                                              Cross section (-b-) is reached by rotating half the pavement until it is level

                                                              Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                              Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                              Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                              Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                              This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                              Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                              Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                              This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                              Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                              The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                              39

                                                              40

                                                              Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                              Same as point E of GB

                                                              Attainment Location - WHERE

                                                              Superelevation must be attained over a length that includes the tangent and the curve

                                                              Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                              Super runoff is all attained in Spiral if used

                                                              Minimum Length of Runoff for curve

                                                              Lr based on drainage and aesthetics

                                                              rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                              current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                              Minimum Length of Tangent Runout

                                                              Lt = eNC x Lr

                                                              ed

                                                              where

                                                              eNC = normal cross slope rate ()

                                                              ed = design superelevation rate

                                                              Lr = minimum length of superelevation runoff (ft)

                                                              (Result is the edge slope is same as for Runoff segment)

                                                              Length of Superelevation Runoff

                                                              α = multilane adjustment factor adjusts for total width

                                                              r

                                                              Relative Gradient (G)

                                                              Maximum longitudinal slope Depends on design speed higher speed =

                                                              gentler slope

                                                              For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                              Maximum Relative Gradient (G)

                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                              Multilane Adjustment

                                                              Runout and runoff must be adjusted for multilane rotation

                                                              See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                              Length of Superelevation Runoff Example

                                                              For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                              Lr = 12eα

                                                              G

                                                              50

                                                              Lr = 12eα = (12) (004) (15)

                                                              G 05

                                                              Lr = 144 feet

                                                              Tangent runout length Example continued

                                                              Lt = (eNC ed ) x Lr

                                                              as defined previously if NC = 2

                                                              Tangent runout for the example is

                                                              LT = 2 4 144rsquo = 72 feet

                                                              52

                                                              From previous example speed = 50 mph e = 4

                                                              From chart runoff = 144 feet same as from calculation

                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                              Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                              Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                              leave a horizontal curve

                                                              Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                              Spirals Advantages

                                                              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                              Provides location for superelevation runoff (not part on tangentcurve)

                                                              Provides transition in width when horizontal curve is widened

                                                              Aesthetic

                                                              Minimum Length of Spiral

                                                              Possible Equations

                                                              Larger of (1) L = 315 V3

                                                              RC

                                                              Where

                                                              L = minimum length of spiral (ft)

                                                              V = speed (mph)

                                                              R = curve radius (ft)

                                                              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                              Minimum Length of Spiral

                                                              Or (2) L = (24pminR)12

                                                              Where

                                                              L = minimum length of spiral (ft)

                                                              R = curve radius (ft)

                                                              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                              Maximum Length of Spiral

                                                              L = (24pmaxR)12

                                                              Where

                                                              L = maximum length of spiral (ft)

                                                              R = curve radius (ft)

                                                              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                              Length of Spiralo AASHTO also provides recommended spiral lengths

                                                              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                              o Design Note For construction purposes round your designs to a reasonable values eg

                                                              Ls = 147 feet round it to

                                                              Ls = 150 feet

                                                              Source Iowa DOT Design Manual

                                                              SPIRAL TERMINOLOGY

                                                              Source Iowa DOT Design Manual

                                                              Source Iowa DOT Design Manual

                                                              Source Iowa DOT Design Manual

                                                              Attainment of Superelevationon spiral curves

                                                              See sketches that follow

                                                              Normal Crown (DOT ndash pt A)

                                                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                              65Source Iowa DOT Standard Road Plans RP-2

                                                              With Spirals

                                                              Same as point E of GB

                                                              With Spirals

                                                              Tangent runout (A to B)

                                                              With Spirals

                                                              Removal of crown

                                                              With Spirals

                                                              Transition of superelevation

                                                              Full superelevation

                                                              69

                                                              • Slide 1
                                                              • Geometric Design ndash Basic Principles
                                                              • GEOMETRIC DESIGN ndash Course Heads
                                                              • Slide 4
                                                              • Curves
                                                              • Horizontal Curves
                                                              • Design Elements
                                                              • Slide 8
                                                              • Slide 9
                                                              • Slide 10
                                                              • Slide 11
                                                              • Horizontal Curves
                                                              • Slide 13
                                                              • Slide 14
                                                              • Slide 15
                                                              • Slide 16
                                                              • Slide 17
                                                              • Slide 18
                                                              • Horizontal Curve Sight Distance
                                                              • Slide 20
                                                              • Slide 21
                                                              • Slide 22
                                                              • Slide 23
                                                              • Slide 24
                                                              • Slide 25
                                                              • TRANSITIONS Superelevation Spiral Curves
                                                              • Superelevation
                                                              • Image
                                                              • Superelevation Transitioning
                                                              • Slide 30
                                                              • Attainment of Superelevation - General
                                                              • Tangent Runout Section
                                                              • Superelevation Runoff Section
                                                              • Slide 34
                                                              • Slide 35
                                                              • Slide 36
                                                              • Slide 37
                                                              • Slide 38
                                                              • Slide 39
                                                              • Slide 40
                                                              • Slide 41
                                                              • Attainment Location - WHERE
                                                              • Minimum Length of Runoff for curve
                                                              • Minimum Length of Tangent Runout
                                                              • Length of Superelevation Runoff
                                                              • Relative Gradient (G)
                                                              • Maximum Relative Gradient (G)
                                                              • Multilane Adjustment
                                                              • Length of Superelevation Runoff Example
                                                              • Slide 50
                                                              • Tangent runout length Example continued
                                                              • Slide 52
                                                              • Spiral Curve Transitions
                                                              • Slide 54
                                                              • Spirals
                                                              • Minimum Length of Spiral
                                                              • Slide 57
                                                              • Maximum Length of Spiral
                                                              • Length of Spiral
                                                              • Slide 60
                                                              • Slide 61
                                                              • Slide 62
                                                              • Slide 63
                                                              • Attainment of Superelevation on spiral curves
                                                              • Slide 65
                                                              • Slide 66
                                                              • Slide 67
                                                              • Slide 68
                                                              • Slide 69

                                                                Tangent Runout Section

                                                                Length of roadway needed to accomplish a change in outside-lane cross slope from normal cross slope rate to zero

                                                                For rotation about centerline

                                                                Superelevation Runoff Section

                                                                Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                                For undivided highways with cross-section rotated about centerline

                                                                Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                                transition from a normal crown section which is accomplished by rotating the pavement

                                                                The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                                Cross section (-a-) is the normal crown section where the transitioning begins

                                                                Cross section (-b-) is reached by rotating half the pavement until it is level

                                                                Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                                Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                                Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                                This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                                Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                                Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                39

                                                                40

                                                                Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                Same as point E of GB

                                                                Attainment Location - WHERE

                                                                Superelevation must be attained over a length that includes the tangent and the curve

                                                                Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                Super runoff is all attained in Spiral if used

                                                                Minimum Length of Runoff for curve

                                                                Lr based on drainage and aesthetics

                                                                rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                Minimum Length of Tangent Runout

                                                                Lt = eNC x Lr

                                                                ed

                                                                where

                                                                eNC = normal cross slope rate ()

                                                                ed = design superelevation rate

                                                                Lr = minimum length of superelevation runoff (ft)

                                                                (Result is the edge slope is same as for Runoff segment)

                                                                Length of Superelevation Runoff

                                                                α = multilane adjustment factor adjusts for total width

                                                                r

                                                                Relative Gradient (G)

                                                                Maximum longitudinal slope Depends on design speed higher speed =

                                                                gentler slope

                                                                For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                Maximum Relative Gradient (G)

                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                Multilane Adjustment

                                                                Runout and runoff must be adjusted for multilane rotation

                                                                See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                Length of Superelevation Runoff Example

                                                                For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                Lr = 12eα

                                                                G

                                                                50

                                                                Lr = 12eα = (12) (004) (15)

                                                                G 05

                                                                Lr = 144 feet

                                                                Tangent runout length Example continued

                                                                Lt = (eNC ed ) x Lr

                                                                as defined previously if NC = 2

                                                                Tangent runout for the example is

                                                                LT = 2 4 144rsquo = 72 feet

                                                                52

                                                                From previous example speed = 50 mph e = 4

                                                                From chart runoff = 144 feet same as from calculation

                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                leave a horizontal curve

                                                                Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                Spirals Advantages

                                                                Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                Provides location for superelevation runoff (not part on tangentcurve)

                                                                Provides transition in width when horizontal curve is widened

                                                                Aesthetic

                                                                Minimum Length of Spiral

                                                                Possible Equations

                                                                Larger of (1) L = 315 V3

                                                                RC

                                                                Where

                                                                L = minimum length of spiral (ft)

                                                                V = speed (mph)

                                                                R = curve radius (ft)

                                                                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                Minimum Length of Spiral

                                                                Or (2) L = (24pminR)12

                                                                Where

                                                                L = minimum length of spiral (ft)

                                                                R = curve radius (ft)

                                                                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                Maximum Length of Spiral

                                                                L = (24pmaxR)12

                                                                Where

                                                                L = maximum length of spiral (ft)

                                                                R = curve radius (ft)

                                                                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                o Design Note For construction purposes round your designs to a reasonable values eg

                                                                Ls = 147 feet round it to

                                                                Ls = 150 feet

                                                                Source Iowa DOT Design Manual

                                                                SPIRAL TERMINOLOGY

                                                                Source Iowa DOT Design Manual

                                                                Source Iowa DOT Design Manual

                                                                Source Iowa DOT Design Manual

                                                                Attainment of Superelevationon spiral curves

                                                                See sketches that follow

                                                                Normal Crown (DOT ndash pt A)

                                                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                65Source Iowa DOT Standard Road Plans RP-2

                                                                With Spirals

                                                                Same as point E of GB

                                                                With Spirals

                                                                Tangent runout (A to B)

                                                                With Spirals

                                                                Removal of crown

                                                                With Spirals

                                                                Transition of superelevation

                                                                Full superelevation

                                                                69

                                                                • Slide 1
                                                                • Geometric Design ndash Basic Principles
                                                                • GEOMETRIC DESIGN ndash Course Heads
                                                                • Slide 4
                                                                • Curves
                                                                • Horizontal Curves
                                                                • Design Elements
                                                                • Slide 8
                                                                • Slide 9
                                                                • Slide 10
                                                                • Slide 11
                                                                • Horizontal Curves
                                                                • Slide 13
                                                                • Slide 14
                                                                • Slide 15
                                                                • Slide 16
                                                                • Slide 17
                                                                • Slide 18
                                                                • Horizontal Curve Sight Distance
                                                                • Slide 20
                                                                • Slide 21
                                                                • Slide 22
                                                                • Slide 23
                                                                • Slide 24
                                                                • Slide 25
                                                                • TRANSITIONS Superelevation Spiral Curves
                                                                • Superelevation
                                                                • Image
                                                                • Superelevation Transitioning
                                                                • Slide 30
                                                                • Attainment of Superelevation - General
                                                                • Tangent Runout Section
                                                                • Superelevation Runoff Section
                                                                • Slide 34
                                                                • Slide 35
                                                                • Slide 36
                                                                • Slide 37
                                                                • Slide 38
                                                                • Slide 39
                                                                • Slide 40
                                                                • Slide 41
                                                                • Attainment Location - WHERE
                                                                • Minimum Length of Runoff for curve
                                                                • Minimum Length of Tangent Runout
                                                                • Length of Superelevation Runoff
                                                                • Relative Gradient (G)
                                                                • Maximum Relative Gradient (G)
                                                                • Multilane Adjustment
                                                                • Length of Superelevation Runoff Example
                                                                • Slide 50
                                                                • Tangent runout length Example continued
                                                                • Slide 52
                                                                • Spiral Curve Transitions
                                                                • Slide 54
                                                                • Spirals
                                                                • Minimum Length of Spiral
                                                                • Slide 57
                                                                • Maximum Length of Spiral
                                                                • Length of Spiral
                                                                • Slide 60
                                                                • Slide 61
                                                                • Slide 62
                                                                • Slide 63
                                                                • Attainment of Superelevation on spiral curves
                                                                • Slide 65
                                                                • Slide 66
                                                                • Slide 67
                                                                • Slide 68
                                                                • Slide 69

                                                                  Superelevation Runoff Section

                                                                  Length of roadway needed to accomplish a change in outside-lane cross slope from 0 to full superelevation or vice versa

                                                                  For undivided highways with cross-section rotated about centerline

                                                                  Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                                  transition from a normal crown section which is accomplished by rotating the pavement

                                                                  The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                                  Cross section (-a-) is the normal crown section where the transitioning begins

                                                                  Cross section (-b-) is reached by rotating half the pavement until it is level

                                                                  Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                                  Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                                  Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                  Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                                  This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                                  Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                                  Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                  This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                  Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                  The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                  39

                                                                  40

                                                                  Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                  Same as point E of GB

                                                                  Attainment Location - WHERE

                                                                  Superelevation must be attained over a length that includes the tangent and the curve

                                                                  Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                  Super runoff is all attained in Spiral if used

                                                                  Minimum Length of Runoff for curve

                                                                  Lr based on drainage and aesthetics

                                                                  rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                  current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                  Minimum Length of Tangent Runout

                                                                  Lt = eNC x Lr

                                                                  ed

                                                                  where

                                                                  eNC = normal cross slope rate ()

                                                                  ed = design superelevation rate

                                                                  Lr = minimum length of superelevation runoff (ft)

                                                                  (Result is the edge slope is same as for Runoff segment)

                                                                  Length of Superelevation Runoff

                                                                  α = multilane adjustment factor adjusts for total width

                                                                  r

                                                                  Relative Gradient (G)

                                                                  Maximum longitudinal slope Depends on design speed higher speed =

                                                                  gentler slope

                                                                  For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                  Maximum Relative Gradient (G)

                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                  Multilane Adjustment

                                                                  Runout and runoff must be adjusted for multilane rotation

                                                                  See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                  Length of Superelevation Runoff Example

                                                                  For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                  Lr = 12eα

                                                                  G

                                                                  50

                                                                  Lr = 12eα = (12) (004) (15)

                                                                  G 05

                                                                  Lr = 144 feet

                                                                  Tangent runout length Example continued

                                                                  Lt = (eNC ed ) x Lr

                                                                  as defined previously if NC = 2

                                                                  Tangent runout for the example is

                                                                  LT = 2 4 144rsquo = 72 feet

                                                                  52

                                                                  From previous example speed = 50 mph e = 4

                                                                  From chart runoff = 144 feet same as from calculation

                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                  Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                  Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                  leave a horizontal curve

                                                                  Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                  Spirals Advantages

                                                                  Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                  Provides location for superelevation runoff (not part on tangentcurve)

                                                                  Provides transition in width when horizontal curve is widened

                                                                  Aesthetic

                                                                  Minimum Length of Spiral

                                                                  Possible Equations

                                                                  Larger of (1) L = 315 V3

                                                                  RC

                                                                  Where

                                                                  L = minimum length of spiral (ft)

                                                                  V = speed (mph)

                                                                  R = curve radius (ft)

                                                                  C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                  Minimum Length of Spiral

                                                                  Or (2) L = (24pminR)12

                                                                  Where

                                                                  L = minimum length of spiral (ft)

                                                                  R = curve radius (ft)

                                                                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                  Maximum Length of Spiral

                                                                  L = (24pmaxR)12

                                                                  Where

                                                                  L = maximum length of spiral (ft)

                                                                  R = curve radius (ft)

                                                                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                  Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                  o Design Note For construction purposes round your designs to a reasonable values eg

                                                                  Ls = 147 feet round it to

                                                                  Ls = 150 feet

                                                                  Source Iowa DOT Design Manual

                                                                  SPIRAL TERMINOLOGY

                                                                  Source Iowa DOT Design Manual

                                                                  Source Iowa DOT Design Manual

                                                                  Source Iowa DOT Design Manual

                                                                  Attainment of Superelevationon spiral curves

                                                                  See sketches that follow

                                                                  Normal Crown (DOT ndash pt A)

                                                                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                  65Source Iowa DOT Standard Road Plans RP-2

                                                                  With Spirals

                                                                  Same as point E of GB

                                                                  With Spirals

                                                                  Tangent runout (A to B)

                                                                  With Spirals

                                                                  Removal of crown

                                                                  With Spirals

                                                                  Transition of superelevation

                                                                  Full superelevation

                                                                  69

                                                                  • Slide 1
                                                                  • Geometric Design ndash Basic Principles
                                                                  • GEOMETRIC DESIGN ndash Course Heads
                                                                  • Slide 4
                                                                  • Curves
                                                                  • Horizontal Curves
                                                                  • Design Elements
                                                                  • Slide 8
                                                                  • Slide 9
                                                                  • Slide 10
                                                                  • Slide 11
                                                                  • Horizontal Curves
                                                                  • Slide 13
                                                                  • Slide 14
                                                                  • Slide 15
                                                                  • Slide 16
                                                                  • Slide 17
                                                                  • Slide 18
                                                                  • Horizontal Curve Sight Distance
                                                                  • Slide 20
                                                                  • Slide 21
                                                                  • Slide 22
                                                                  • Slide 23
                                                                  • Slide 24
                                                                  • Slide 25
                                                                  • TRANSITIONS Superelevation Spiral Curves
                                                                  • Superelevation
                                                                  • Image
                                                                  • Superelevation Transitioning
                                                                  • Slide 30
                                                                  • Attainment of Superelevation - General
                                                                  • Tangent Runout Section
                                                                  • Superelevation Runoff Section
                                                                  • Slide 34
                                                                  • Slide 35
                                                                  • Slide 36
                                                                  • Slide 37
                                                                  • Slide 38
                                                                  • Slide 39
                                                                  • Slide 40
                                                                  • Slide 41
                                                                  • Attainment Location - WHERE
                                                                  • Minimum Length of Runoff for curve
                                                                  • Minimum Length of Tangent Runout
                                                                  • Length of Superelevation Runoff
                                                                  • Relative Gradient (G)
                                                                  • Maximum Relative Gradient (G)
                                                                  • Multilane Adjustment
                                                                  • Length of Superelevation Runoff Example
                                                                  • Slide 50
                                                                  • Tangent runout length Example continued
                                                                  • Slide 52
                                                                  • Spiral Curve Transitions
                                                                  • Slide 54
                                                                  • Spirals
                                                                  • Minimum Length of Spiral
                                                                  • Slide 57
                                                                  • Maximum Length of Spiral
                                                                  • Length of Spiral
                                                                  • Slide 60
                                                                  • Slide 61
                                                                  • Slide 62
                                                                  • Slide 63
                                                                  • Attainment of Superelevation on spiral curves
                                                                  • Slide 65
                                                                  • Slide 66
                                                                  • Slide 67
                                                                  • Slide 68
                                                                  • Slide 69

                                                                    Superelevation Transitioning The development of superelevation on a horizontal curve requires a

                                                                    transition from a normal crown section which is accomplished by rotating the pavement

                                                                    The pavement may be rotated about the centerline or either edge of the travel lanes Five basic cross section controls mdash (-a-) through (-e-) superelevation

                                                                    Cross section (-a-) is the normal crown section where the transitioning begins

                                                                    Cross section (-b-) is reached by rotating half the pavement until it is level

                                                                    Cross section (-c-) is attained by continuing to rotate the same half of pavement until a plane section is attained across the entire pavement section at a cross slope equal to the normal crown slope

                                                                    Cross section (-d-) is the rate of the cross slope at any intermediate cross section between (-c-) and (-e-) is proportional to the distance from Cross section (-e-)

                                                                    Cross section (-e-) is achieved by further rotation of the planar section the entire pavement section to attain the full superelevation at a cross slope equal to (e)

                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                    Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                                    This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                                    Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                                    Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                    This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                    Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                    The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                    39

                                                                    40

                                                                    Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                    Same as point E of GB

                                                                    Attainment Location - WHERE

                                                                    Superelevation must be attained over a length that includes the tangent and the curve

                                                                    Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                    Super runoff is all attained in Spiral if used

                                                                    Minimum Length of Runoff for curve

                                                                    Lr based on drainage and aesthetics

                                                                    rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                    current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                    Minimum Length of Tangent Runout

                                                                    Lt = eNC x Lr

                                                                    ed

                                                                    where

                                                                    eNC = normal cross slope rate ()

                                                                    ed = design superelevation rate

                                                                    Lr = minimum length of superelevation runoff (ft)

                                                                    (Result is the edge slope is same as for Runoff segment)

                                                                    Length of Superelevation Runoff

                                                                    α = multilane adjustment factor adjusts for total width

                                                                    r

                                                                    Relative Gradient (G)

                                                                    Maximum longitudinal slope Depends on design speed higher speed =

                                                                    gentler slope

                                                                    For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                    Maximum Relative Gradient (G)

                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                    Multilane Adjustment

                                                                    Runout and runoff must be adjusted for multilane rotation

                                                                    See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                    Length of Superelevation Runoff Example

                                                                    For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                    Lr = 12eα

                                                                    G

                                                                    50

                                                                    Lr = 12eα = (12) (004) (15)

                                                                    G 05

                                                                    Lr = 144 feet

                                                                    Tangent runout length Example continued

                                                                    Lt = (eNC ed ) x Lr

                                                                    as defined previously if NC = 2

                                                                    Tangent runout for the example is

                                                                    LT = 2 4 144rsquo = 72 feet

                                                                    52

                                                                    From previous example speed = 50 mph e = 4

                                                                    From chart runoff = 144 feet same as from calculation

                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                    Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                    leave a horizontal curve

                                                                    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                    Spirals Advantages

                                                                    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                    Provides location for superelevation runoff (not part on tangentcurve)

                                                                    Provides transition in width when horizontal curve is widened

                                                                    Aesthetic

                                                                    Minimum Length of Spiral

                                                                    Possible Equations

                                                                    Larger of (1) L = 315 V3

                                                                    RC

                                                                    Where

                                                                    L = minimum length of spiral (ft)

                                                                    V = speed (mph)

                                                                    R = curve radius (ft)

                                                                    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                    Minimum Length of Spiral

                                                                    Or (2) L = (24pminR)12

                                                                    Where

                                                                    L = minimum length of spiral (ft)

                                                                    R = curve radius (ft)

                                                                    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                    Maximum Length of Spiral

                                                                    L = (24pmaxR)12

                                                                    Where

                                                                    L = maximum length of spiral (ft)

                                                                    R = curve radius (ft)

                                                                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                    Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                    o Design Note For construction purposes round your designs to a reasonable values eg

                                                                    Ls = 147 feet round it to

                                                                    Ls = 150 feet

                                                                    Source Iowa DOT Design Manual

                                                                    SPIRAL TERMINOLOGY

                                                                    Source Iowa DOT Design Manual

                                                                    Source Iowa DOT Design Manual

                                                                    Source Iowa DOT Design Manual

                                                                    Attainment of Superelevationon spiral curves

                                                                    See sketches that follow

                                                                    Normal Crown (DOT ndash pt A)

                                                                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                    65Source Iowa DOT Standard Road Plans RP-2

                                                                    With Spirals

                                                                    Same as point E of GB

                                                                    With Spirals

                                                                    Tangent runout (A to B)

                                                                    With Spirals

                                                                    Removal of crown

                                                                    With Spirals

                                                                    Transition of superelevation

                                                                    Full superelevation

                                                                    69

                                                                    • Slide 1
                                                                    • Geometric Design ndash Basic Principles
                                                                    • GEOMETRIC DESIGN ndash Course Heads
                                                                    • Slide 4
                                                                    • Curves
                                                                    • Horizontal Curves
                                                                    • Design Elements
                                                                    • Slide 8
                                                                    • Slide 9
                                                                    • Slide 10
                                                                    • Slide 11
                                                                    • Horizontal Curves
                                                                    • Slide 13
                                                                    • Slide 14
                                                                    • Slide 15
                                                                    • Slide 16
                                                                    • Slide 17
                                                                    • Slide 18
                                                                    • Horizontal Curve Sight Distance
                                                                    • Slide 20
                                                                    • Slide 21
                                                                    • Slide 22
                                                                    • Slide 23
                                                                    • Slide 24
                                                                    • Slide 25
                                                                    • TRANSITIONS Superelevation Spiral Curves
                                                                    • Superelevation
                                                                    • Image
                                                                    • Superelevation Transitioning
                                                                    • Slide 30
                                                                    • Attainment of Superelevation - General
                                                                    • Tangent Runout Section
                                                                    • Superelevation Runoff Section
                                                                    • Slide 34
                                                                    • Slide 35
                                                                    • Slide 36
                                                                    • Slide 37
                                                                    • Slide 38
                                                                    • Slide 39
                                                                    • Slide 40
                                                                    • Slide 41
                                                                    • Attainment Location - WHERE
                                                                    • Minimum Length of Runoff for curve
                                                                    • Minimum Length of Tangent Runout
                                                                    • Length of Superelevation Runoff
                                                                    • Relative Gradient (G)
                                                                    • Maximum Relative Gradient (G)
                                                                    • Multilane Adjustment
                                                                    • Length of Superelevation Runoff Example
                                                                    • Slide 50
                                                                    • Tangent runout length Example continued
                                                                    • Slide 52
                                                                    • Spiral Curve Transitions
                                                                    • Slide 54
                                                                    • Spirals
                                                                    • Minimum Length of Spiral
                                                                    • Slide 57
                                                                    • Maximum Length of Spiral
                                                                    • Length of Spiral
                                                                    • Slide 60
                                                                    • Slide 61
                                                                    • Slide 62
                                                                    • Slide 63
                                                                    • Attainment of Superelevation on spiral curves
                                                                    • Slide 65
                                                                    • Slide 66
                                                                    • Slide 67
                                                                    • Slide 68
                                                                    • Slide 69

                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                      Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                                      This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                                      Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                                      Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                      This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                      Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                      The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                      39

                                                                      40

                                                                      Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                      Same as point E of GB

                                                                      Attainment Location - WHERE

                                                                      Superelevation must be attained over a length that includes the tangent and the curve

                                                                      Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                      Super runoff is all attained in Spiral if used

                                                                      Minimum Length of Runoff for curve

                                                                      Lr based on drainage and aesthetics

                                                                      rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                      current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                      Minimum Length of Tangent Runout

                                                                      Lt = eNC x Lr

                                                                      ed

                                                                      where

                                                                      eNC = normal cross slope rate ()

                                                                      ed = design superelevation rate

                                                                      Lr = minimum length of superelevation runoff (ft)

                                                                      (Result is the edge slope is same as for Runoff segment)

                                                                      Length of Superelevation Runoff

                                                                      α = multilane adjustment factor adjusts for total width

                                                                      r

                                                                      Relative Gradient (G)

                                                                      Maximum longitudinal slope Depends on design speed higher speed =

                                                                      gentler slope

                                                                      For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                      Maximum Relative Gradient (G)

                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                      Multilane Adjustment

                                                                      Runout and runoff must be adjusted for multilane rotation

                                                                      See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                      Length of Superelevation Runoff Example

                                                                      For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                      Lr = 12eα

                                                                      G

                                                                      50

                                                                      Lr = 12eα = (12) (004) (15)

                                                                      G 05

                                                                      Lr = 144 feet

                                                                      Tangent runout length Example continued

                                                                      Lt = (eNC ed ) x Lr

                                                                      as defined previously if NC = 2

                                                                      Tangent runout for the example is

                                                                      LT = 2 4 144rsquo = 72 feet

                                                                      52

                                                                      From previous example speed = 50 mph e = 4

                                                                      From chart runoff = 144 feet same as from calculation

                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                      Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                      leave a horizontal curve

                                                                      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                      Spirals Advantages

                                                                      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                      Provides location for superelevation runoff (not part on tangentcurve)

                                                                      Provides transition in width when horizontal curve is widened

                                                                      Aesthetic

                                                                      Minimum Length of Spiral

                                                                      Possible Equations

                                                                      Larger of (1) L = 315 V3

                                                                      RC

                                                                      Where

                                                                      L = minimum length of spiral (ft)

                                                                      V = speed (mph)

                                                                      R = curve radius (ft)

                                                                      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                      Minimum Length of Spiral

                                                                      Or (2) L = (24pminR)12

                                                                      Where

                                                                      L = minimum length of spiral (ft)

                                                                      R = curve radius (ft)

                                                                      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                      Maximum Length of Spiral

                                                                      L = (24pmaxR)12

                                                                      Where

                                                                      L = maximum length of spiral (ft)

                                                                      R = curve radius (ft)

                                                                      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                      Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                      o Design Note For construction purposes round your designs to a reasonable values eg

                                                                      Ls = 147 feet round it to

                                                                      Ls = 150 feet

                                                                      Source Iowa DOT Design Manual

                                                                      SPIRAL TERMINOLOGY

                                                                      Source Iowa DOT Design Manual

                                                                      Source Iowa DOT Design Manual

                                                                      Source Iowa DOT Design Manual

                                                                      Attainment of Superelevationon spiral curves

                                                                      See sketches that follow

                                                                      Normal Crown (DOT ndash pt A)

                                                                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                      65Source Iowa DOT Standard Road Plans RP-2

                                                                      With Spirals

                                                                      Same as point E of GB

                                                                      With Spirals

                                                                      Tangent runout (A to B)

                                                                      With Spirals

                                                                      Removal of crown

                                                                      With Spirals

                                                                      Transition of superelevation

                                                                      Full superelevation

                                                                      69

                                                                      • Slide 1
                                                                      • Geometric Design ndash Basic Principles
                                                                      • GEOMETRIC DESIGN ndash Course Heads
                                                                      • Slide 4
                                                                      • Curves
                                                                      • Horizontal Curves
                                                                      • Design Elements
                                                                      • Slide 8
                                                                      • Slide 9
                                                                      • Slide 10
                                                                      • Slide 11
                                                                      • Horizontal Curves
                                                                      • Slide 13
                                                                      • Slide 14
                                                                      • Slide 15
                                                                      • Slide 16
                                                                      • Slide 17
                                                                      • Slide 18
                                                                      • Horizontal Curve Sight Distance
                                                                      • Slide 20
                                                                      • Slide 21
                                                                      • Slide 22
                                                                      • Slide 23
                                                                      • Slide 24
                                                                      • Slide 25
                                                                      • TRANSITIONS Superelevation Spiral Curves
                                                                      • Superelevation
                                                                      • Image
                                                                      • Superelevation Transitioning
                                                                      • Slide 30
                                                                      • Attainment of Superelevation - General
                                                                      • Tangent Runout Section
                                                                      • Superelevation Runoff Section
                                                                      • Slide 34
                                                                      • Slide 35
                                                                      • Slide 36
                                                                      • Slide 37
                                                                      • Slide 38
                                                                      • Slide 39
                                                                      • Slide 40
                                                                      • Slide 41
                                                                      • Attainment Location - WHERE
                                                                      • Minimum Length of Runoff for curve
                                                                      • Minimum Length of Tangent Runout
                                                                      • Length of Superelevation Runoff
                                                                      • Relative Gradient (G)
                                                                      • Maximum Relative Gradient (G)
                                                                      • Multilane Adjustment
                                                                      • Length of Superelevation Runoff Example
                                                                      • Slide 50
                                                                      • Tangent runout length Example continued
                                                                      • Slide 52
                                                                      • Spiral Curve Transitions
                                                                      • Slide 54
                                                                      • Spirals
                                                                      • Minimum Length of Spiral
                                                                      • Slide 57
                                                                      • Maximum Length of Spiral
                                                                      • Length of Spiral
                                                                      • Slide 60
                                                                      • Slide 61
                                                                      • Slide 62
                                                                      • Slide 63
                                                                      • Attainment of Superelevation on spiral curves
                                                                      • Slide 65
                                                                      • Slide 66
                                                                      • Slide 67
                                                                      • Slide 68
                                                                      • Slide 69

                                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                        Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                                        This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                                        Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                                        Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                        This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                        Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                        The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                        39

                                                                        40

                                                                        Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                        Same as point E of GB

                                                                        Attainment Location - WHERE

                                                                        Superelevation must be attained over a length that includes the tangent and the curve

                                                                        Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                        Super runoff is all attained in Spiral if used

                                                                        Minimum Length of Runoff for curve

                                                                        Lr based on drainage and aesthetics

                                                                        rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                        current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                        Minimum Length of Tangent Runout

                                                                        Lt = eNC x Lr

                                                                        ed

                                                                        where

                                                                        eNC = normal cross slope rate ()

                                                                        ed = design superelevation rate

                                                                        Lr = minimum length of superelevation runoff (ft)

                                                                        (Result is the edge slope is same as for Runoff segment)

                                                                        Length of Superelevation Runoff

                                                                        α = multilane adjustment factor adjusts for total width

                                                                        r

                                                                        Relative Gradient (G)

                                                                        Maximum longitudinal slope Depends on design speed higher speed =

                                                                        gentler slope

                                                                        For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                        Maximum Relative Gradient (G)

                                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                        Multilane Adjustment

                                                                        Runout and runoff must be adjusted for multilane rotation

                                                                        See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                        Length of Superelevation Runoff Example

                                                                        For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                        Lr = 12eα

                                                                        G

                                                                        50

                                                                        Lr = 12eα = (12) (004) (15)

                                                                        G 05

                                                                        Lr = 144 feet

                                                                        Tangent runout length Example continued

                                                                        Lt = (eNC ed ) x Lr

                                                                        as defined previously if NC = 2

                                                                        Tangent runout for the example is

                                                                        LT = 2 4 144rsquo = 72 feet

                                                                        52

                                                                        From previous example speed = 50 mph e = 4

                                                                        From chart runoff = 144 feet same as from calculation

                                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                        Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                        leave a horizontal curve

                                                                        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                        Spirals Advantages

                                                                        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                        Provides location for superelevation runoff (not part on tangentcurve)

                                                                        Provides transition in width when horizontal curve is widened

                                                                        Aesthetic

                                                                        Minimum Length of Spiral

                                                                        Possible Equations

                                                                        Larger of (1) L = 315 V3

                                                                        RC

                                                                        Where

                                                                        L = minimum length of spiral (ft)

                                                                        V = speed (mph)

                                                                        R = curve radius (ft)

                                                                        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                        Minimum Length of Spiral

                                                                        Or (2) L = (24pminR)12

                                                                        Where

                                                                        L = minimum length of spiral (ft)

                                                                        R = curve radius (ft)

                                                                        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                        Maximum Length of Spiral

                                                                        L = (24pmaxR)12

                                                                        Where

                                                                        L = maximum length of spiral (ft)

                                                                        R = curve radius (ft)

                                                                        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                        Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                        o Design Note For construction purposes round your designs to a reasonable values eg

                                                                        Ls = 147 feet round it to

                                                                        Ls = 150 feet

                                                                        Source Iowa DOT Design Manual

                                                                        SPIRAL TERMINOLOGY

                                                                        Source Iowa DOT Design Manual

                                                                        Source Iowa DOT Design Manual

                                                                        Source Iowa DOT Design Manual

                                                                        Attainment of Superelevationon spiral curves

                                                                        See sketches that follow

                                                                        Normal Crown (DOT ndash pt A)

                                                                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                        65Source Iowa DOT Standard Road Plans RP-2

                                                                        With Spirals

                                                                        Same as point E of GB

                                                                        With Spirals

                                                                        Tangent runout (A to B)

                                                                        With Spirals

                                                                        Removal of crown

                                                                        With Spirals

                                                                        Transition of superelevation

                                                                        Full superelevation

                                                                        69

                                                                        • Slide 1
                                                                        • Geometric Design ndash Basic Principles
                                                                        • GEOMETRIC DESIGN ndash Course Heads
                                                                        • Slide 4
                                                                        • Curves
                                                                        • Horizontal Curves
                                                                        • Design Elements
                                                                        • Slide 8
                                                                        • Slide 9
                                                                        • Slide 10
                                                                        • Slide 11
                                                                        • Horizontal Curves
                                                                        • Slide 13
                                                                        • Slide 14
                                                                        • Slide 15
                                                                        • Slide 16
                                                                        • Slide 17
                                                                        • Slide 18
                                                                        • Horizontal Curve Sight Distance
                                                                        • Slide 20
                                                                        • Slide 21
                                                                        • Slide 22
                                                                        • Slide 23
                                                                        • Slide 24
                                                                        • Slide 25
                                                                        • TRANSITIONS Superelevation Spiral Curves
                                                                        • Superelevation
                                                                        • Image
                                                                        • Superelevation Transitioning
                                                                        • Slide 30
                                                                        • Attainment of Superelevation - General
                                                                        • Tangent Runout Section
                                                                        • Superelevation Runoff Section
                                                                        • Slide 34
                                                                        • Slide 35
                                                                        • Slide 36
                                                                        • Slide 37
                                                                        • Slide 38
                                                                        • Slide 39
                                                                        • Slide 40
                                                                        • Slide 41
                                                                        • Attainment Location - WHERE
                                                                        • Minimum Length of Runoff for curve
                                                                        • Minimum Length of Tangent Runout
                                                                        • Length of Superelevation Runoff
                                                                        • Relative Gradient (G)
                                                                        • Maximum Relative Gradient (G)
                                                                        • Multilane Adjustment
                                                                        • Length of Superelevation Runoff Example
                                                                        • Slide 50
                                                                        • Tangent runout length Example continued
                                                                        • Slide 52
                                                                        • Spiral Curve Transitions
                                                                        • Slide 54
                                                                        • Spirals
                                                                        • Minimum Length of Spiral
                                                                        • Slide 57
                                                                        • Maximum Length of Spiral
                                                                        • Length of Spiral
                                                                        • Slide 60
                                                                        • Slide 61
                                                                        • Slide 62
                                                                        • Slide 63
                                                                        • Attainment of Superelevation on spiral curves
                                                                        • Slide 65
                                                                        • Slide 66
                                                                        • Slide 67
                                                                        • Slide 68
                                                                        • Slide 69

                                                                          Superelevation Transitioning Rotation about the centerline profile of traveled way

                                                                          This is generally the preferred method for two lane and undivided multilane roadways and when the elevations of the outside of roadway must be held within critical limits such as in an urban area to minimize the impact on adjacent properties This is also the method that distorts the edge line profiles the least

                                                                          Rotation about the inside-edge profile of traveled way This is generally the preferred method when the lower edge profile is of concern such as when the profile is flat and the inside edge of the roadway needs to be controlled for drainage purposes This method is suitable for ramps

                                                                          Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                          This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                          Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                          The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                          39

                                                                          40

                                                                          Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                          Same as point E of GB

                                                                          Attainment Location - WHERE

                                                                          Superelevation must be attained over a length that includes the tangent and the curve

                                                                          Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                          Super runoff is all attained in Spiral if used

                                                                          Minimum Length of Runoff for curve

                                                                          Lr based on drainage and aesthetics

                                                                          rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                          current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                          Minimum Length of Tangent Runout

                                                                          Lt = eNC x Lr

                                                                          ed

                                                                          where

                                                                          eNC = normal cross slope rate ()

                                                                          ed = design superelevation rate

                                                                          Lr = minimum length of superelevation runoff (ft)

                                                                          (Result is the edge slope is same as for Runoff segment)

                                                                          Length of Superelevation Runoff

                                                                          α = multilane adjustment factor adjusts for total width

                                                                          r

                                                                          Relative Gradient (G)

                                                                          Maximum longitudinal slope Depends on design speed higher speed =

                                                                          gentler slope

                                                                          For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                          Maximum Relative Gradient (G)

                                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                          Multilane Adjustment

                                                                          Runout and runoff must be adjusted for multilane rotation

                                                                          See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                          Length of Superelevation Runoff Example

                                                                          For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                          Lr = 12eα

                                                                          G

                                                                          50

                                                                          Lr = 12eα = (12) (004) (15)

                                                                          G 05

                                                                          Lr = 144 feet

                                                                          Tangent runout length Example continued

                                                                          Lt = (eNC ed ) x Lr

                                                                          as defined previously if NC = 2

                                                                          Tangent runout for the example is

                                                                          LT = 2 4 144rsquo = 72 feet

                                                                          52

                                                                          From previous example speed = 50 mph e = 4

                                                                          From chart runoff = 144 feet same as from calculation

                                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                          Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                          leave a horizontal curve

                                                                          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                          Spirals Advantages

                                                                          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                          Provides location for superelevation runoff (not part on tangentcurve)

                                                                          Provides transition in width when horizontal curve is widened

                                                                          Aesthetic

                                                                          Minimum Length of Spiral

                                                                          Possible Equations

                                                                          Larger of (1) L = 315 V3

                                                                          RC

                                                                          Where

                                                                          L = minimum length of spiral (ft)

                                                                          V = speed (mph)

                                                                          R = curve radius (ft)

                                                                          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                          Minimum Length of Spiral

                                                                          Or (2) L = (24pminR)12

                                                                          Where

                                                                          L = minimum length of spiral (ft)

                                                                          R = curve radius (ft)

                                                                          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                          Maximum Length of Spiral

                                                                          L = (24pmaxR)12

                                                                          Where

                                                                          L = maximum length of spiral (ft)

                                                                          R = curve radius (ft)

                                                                          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                          Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                          o Design Note For construction purposes round your designs to a reasonable values eg

                                                                          Ls = 147 feet round it to

                                                                          Ls = 150 feet

                                                                          Source Iowa DOT Design Manual

                                                                          SPIRAL TERMINOLOGY

                                                                          Source Iowa DOT Design Manual

                                                                          Source Iowa DOT Design Manual

                                                                          Source Iowa DOT Design Manual

                                                                          Attainment of Superelevationon spiral curves

                                                                          See sketches that follow

                                                                          Normal Crown (DOT ndash pt A)

                                                                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                          65Source Iowa DOT Standard Road Plans RP-2

                                                                          With Spirals

                                                                          Same as point E of GB

                                                                          With Spirals

                                                                          Tangent runout (A to B)

                                                                          With Spirals

                                                                          Removal of crown

                                                                          With Spirals

                                                                          Transition of superelevation

                                                                          Full superelevation

                                                                          69

                                                                          • Slide 1
                                                                          • Geometric Design ndash Basic Principles
                                                                          • GEOMETRIC DESIGN ndash Course Heads
                                                                          • Slide 4
                                                                          • Curves
                                                                          • Horizontal Curves
                                                                          • Design Elements
                                                                          • Slide 8
                                                                          • Slide 9
                                                                          • Slide 10
                                                                          • Slide 11
                                                                          • Horizontal Curves
                                                                          • Slide 13
                                                                          • Slide 14
                                                                          • Slide 15
                                                                          • Slide 16
                                                                          • Slide 17
                                                                          • Slide 18
                                                                          • Horizontal Curve Sight Distance
                                                                          • Slide 20
                                                                          • Slide 21
                                                                          • Slide 22
                                                                          • Slide 23
                                                                          • Slide 24
                                                                          • Slide 25
                                                                          • TRANSITIONS Superelevation Spiral Curves
                                                                          • Superelevation
                                                                          • Image
                                                                          • Superelevation Transitioning
                                                                          • Slide 30
                                                                          • Attainment of Superelevation - General
                                                                          • Tangent Runout Section
                                                                          • Superelevation Runoff Section
                                                                          • Slide 34
                                                                          • Slide 35
                                                                          • Slide 36
                                                                          • Slide 37
                                                                          • Slide 38
                                                                          • Slide 39
                                                                          • Slide 40
                                                                          • Slide 41
                                                                          • Attainment Location - WHERE
                                                                          • Minimum Length of Runoff for curve
                                                                          • Minimum Length of Tangent Runout
                                                                          • Length of Superelevation Runoff
                                                                          • Relative Gradient (G)
                                                                          • Maximum Relative Gradient (G)
                                                                          • Multilane Adjustment
                                                                          • Length of Superelevation Runoff Example
                                                                          • Slide 50
                                                                          • Tangent runout length Example continued
                                                                          • Slide 52
                                                                          • Spiral Curve Transitions
                                                                          • Slide 54
                                                                          • Spirals
                                                                          • Minimum Length of Spiral
                                                                          • Slide 57
                                                                          • Maximum Length of Spiral
                                                                          • Length of Spiral
                                                                          • Slide 60
                                                                          • Slide 61
                                                                          • Slide 62
                                                                          • Slide 63
                                                                          • Attainment of Superelevation on spiral curves
                                                                          • Slide 65
                                                                          • Slide 66
                                                                          • Slide 67
                                                                          • Slide 68
                                                                          • Slide 69

                                                                            Superelevation Transitioning Rotation about the outside-edge profile of traveled way

                                                                            This method is similar to inside edge rotation except that the change is effected below the outside-edge profile instead of above the inside edge profile This method is used when the higher edge profile is critical such as on divided highways where the median edge profiles are held

                                                                            Rotation about the outside-edge profile of traveled way when the roadway has a straight cross-slope at the beginning of transition (-a-)

                                                                            The outside-edge rotation is shown because this point is most often used for rotation of two-lane one-way roadways with profile along the median edge of traveled way or for the traveled way having a typical straight cross-slope

                                                                            39

                                                                            40

                                                                            Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                            Same as point E of GB

                                                                            Attainment Location - WHERE

                                                                            Superelevation must be attained over a length that includes the tangent and the curve

                                                                            Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                            Super runoff is all attained in Spiral if used

                                                                            Minimum Length of Runoff for curve

                                                                            Lr based on drainage and aesthetics

                                                                            rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                            current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                            Minimum Length of Tangent Runout

                                                                            Lt = eNC x Lr

                                                                            ed

                                                                            where

                                                                            eNC = normal cross slope rate ()

                                                                            ed = design superelevation rate

                                                                            Lr = minimum length of superelevation runoff (ft)

                                                                            (Result is the edge slope is same as for Runoff segment)

                                                                            Length of Superelevation Runoff

                                                                            α = multilane adjustment factor adjusts for total width

                                                                            r

                                                                            Relative Gradient (G)

                                                                            Maximum longitudinal slope Depends on design speed higher speed =

                                                                            gentler slope

                                                                            For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                            Maximum Relative Gradient (G)

                                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                            Multilane Adjustment

                                                                            Runout and runoff must be adjusted for multilane rotation

                                                                            See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                            Length of Superelevation Runoff Example

                                                                            For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                            Lr = 12eα

                                                                            G

                                                                            50

                                                                            Lr = 12eα = (12) (004) (15)

                                                                            G 05

                                                                            Lr = 144 feet

                                                                            Tangent runout length Example continued

                                                                            Lt = (eNC ed ) x Lr

                                                                            as defined previously if NC = 2

                                                                            Tangent runout for the example is

                                                                            LT = 2 4 144rsquo = 72 feet

                                                                            52

                                                                            From previous example speed = 50 mph e = 4

                                                                            From chart runoff = 144 feet same as from calculation

                                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                            Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                            Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                            leave a horizontal curve

                                                                            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                            Spirals Advantages

                                                                            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                            Provides location for superelevation runoff (not part on tangentcurve)

                                                                            Provides transition in width when horizontal curve is widened

                                                                            Aesthetic

                                                                            Minimum Length of Spiral

                                                                            Possible Equations

                                                                            Larger of (1) L = 315 V3

                                                                            RC

                                                                            Where

                                                                            L = minimum length of spiral (ft)

                                                                            V = speed (mph)

                                                                            R = curve radius (ft)

                                                                            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                            Minimum Length of Spiral

                                                                            Or (2) L = (24pminR)12

                                                                            Where

                                                                            L = minimum length of spiral (ft)

                                                                            R = curve radius (ft)

                                                                            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                            Maximum Length of Spiral

                                                                            L = (24pmaxR)12

                                                                            Where

                                                                            L = maximum length of spiral (ft)

                                                                            R = curve radius (ft)

                                                                            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                            Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                            o Design Note For construction purposes round your designs to a reasonable values eg

                                                                            Ls = 147 feet round it to

                                                                            Ls = 150 feet

                                                                            Source Iowa DOT Design Manual

                                                                            SPIRAL TERMINOLOGY

                                                                            Source Iowa DOT Design Manual

                                                                            Source Iowa DOT Design Manual

                                                                            Source Iowa DOT Design Manual

                                                                            Attainment of Superelevationon spiral curves

                                                                            See sketches that follow

                                                                            Normal Crown (DOT ndash pt A)

                                                                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                            65Source Iowa DOT Standard Road Plans RP-2

                                                                            With Spirals

                                                                            Same as point E of GB

                                                                            With Spirals

                                                                            Tangent runout (A to B)

                                                                            With Spirals

                                                                            Removal of crown

                                                                            With Spirals

                                                                            Transition of superelevation

                                                                            Full superelevation

                                                                            69

                                                                            • Slide 1
                                                                            • Geometric Design ndash Basic Principles
                                                                            • GEOMETRIC DESIGN ndash Course Heads
                                                                            • Slide 4
                                                                            • Curves
                                                                            • Horizontal Curves
                                                                            • Design Elements
                                                                            • Slide 8
                                                                            • Slide 9
                                                                            • Slide 10
                                                                            • Slide 11
                                                                            • Horizontal Curves
                                                                            • Slide 13
                                                                            • Slide 14
                                                                            • Slide 15
                                                                            • Slide 16
                                                                            • Slide 17
                                                                            • Slide 18
                                                                            • Horizontal Curve Sight Distance
                                                                            • Slide 20
                                                                            • Slide 21
                                                                            • Slide 22
                                                                            • Slide 23
                                                                            • Slide 24
                                                                            • Slide 25
                                                                            • TRANSITIONS Superelevation Spiral Curves
                                                                            • Superelevation
                                                                            • Image
                                                                            • Superelevation Transitioning
                                                                            • Slide 30
                                                                            • Attainment of Superelevation - General
                                                                            • Tangent Runout Section
                                                                            • Superelevation Runoff Section
                                                                            • Slide 34
                                                                            • Slide 35
                                                                            • Slide 36
                                                                            • Slide 37
                                                                            • Slide 38
                                                                            • Slide 39
                                                                            • Slide 40
                                                                            • Slide 41
                                                                            • Attainment Location - WHERE
                                                                            • Minimum Length of Runoff for curve
                                                                            • Minimum Length of Tangent Runout
                                                                            • Length of Superelevation Runoff
                                                                            • Relative Gradient (G)
                                                                            • Maximum Relative Gradient (G)
                                                                            • Multilane Adjustment
                                                                            • Length of Superelevation Runoff Example
                                                                            • Slide 50
                                                                            • Tangent runout length Example continued
                                                                            • Slide 52
                                                                            • Spiral Curve Transitions
                                                                            • Slide 54
                                                                            • Spirals
                                                                            • Minimum Length of Spiral
                                                                            • Slide 57
                                                                            • Maximum Length of Spiral
                                                                            • Length of Spiral
                                                                            • Slide 60
                                                                            • Slide 61
                                                                            • Slide 62
                                                                            • Slide 63
                                                                            • Attainment of Superelevation on spiral curves
                                                                            • Slide 65
                                                                            • Slide 66
                                                                            • Slide 67
                                                                            • Slide 68
                                                                            • Slide 69

                                                                              39

                                                                              40

                                                                              Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                              Same as point E of GB

                                                                              Attainment Location - WHERE

                                                                              Superelevation must be attained over a length that includes the tangent and the curve

                                                                              Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                              Super runoff is all attained in Spiral if used

                                                                              Minimum Length of Runoff for curve

                                                                              Lr based on drainage and aesthetics

                                                                              rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                              current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                              Minimum Length of Tangent Runout

                                                                              Lt = eNC x Lr

                                                                              ed

                                                                              where

                                                                              eNC = normal cross slope rate ()

                                                                              ed = design superelevation rate

                                                                              Lr = minimum length of superelevation runoff (ft)

                                                                              (Result is the edge slope is same as for Runoff segment)

                                                                              Length of Superelevation Runoff

                                                                              α = multilane adjustment factor adjusts for total width

                                                                              r

                                                                              Relative Gradient (G)

                                                                              Maximum longitudinal slope Depends on design speed higher speed =

                                                                              gentler slope

                                                                              For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                              Maximum Relative Gradient (G)

                                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                              Multilane Adjustment

                                                                              Runout and runoff must be adjusted for multilane rotation

                                                                              See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                              Length of Superelevation Runoff Example

                                                                              For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                              Lr = 12eα

                                                                              G

                                                                              50

                                                                              Lr = 12eα = (12) (004) (15)

                                                                              G 05

                                                                              Lr = 144 feet

                                                                              Tangent runout length Example continued

                                                                              Lt = (eNC ed ) x Lr

                                                                              as defined previously if NC = 2

                                                                              Tangent runout for the example is

                                                                              LT = 2 4 144rsquo = 72 feet

                                                                              52

                                                                              From previous example speed = 50 mph e = 4

                                                                              From chart runoff = 144 feet same as from calculation

                                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                              Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                              Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                              leave a horizontal curve

                                                                              Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                              Spirals Advantages

                                                                              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                              Provides location for superelevation runoff (not part on tangentcurve)

                                                                              Provides transition in width when horizontal curve is widened

                                                                              Aesthetic

                                                                              Minimum Length of Spiral

                                                                              Possible Equations

                                                                              Larger of (1) L = 315 V3

                                                                              RC

                                                                              Where

                                                                              L = minimum length of spiral (ft)

                                                                              V = speed (mph)

                                                                              R = curve radius (ft)

                                                                              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                              Minimum Length of Spiral

                                                                              Or (2) L = (24pminR)12

                                                                              Where

                                                                              L = minimum length of spiral (ft)

                                                                              R = curve radius (ft)

                                                                              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                              Maximum Length of Spiral

                                                                              L = (24pmaxR)12

                                                                              Where

                                                                              L = maximum length of spiral (ft)

                                                                              R = curve radius (ft)

                                                                              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                              Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                              o Design Note For construction purposes round your designs to a reasonable values eg

                                                                              Ls = 147 feet round it to

                                                                              Ls = 150 feet

                                                                              Source Iowa DOT Design Manual

                                                                              SPIRAL TERMINOLOGY

                                                                              Source Iowa DOT Design Manual

                                                                              Source Iowa DOT Design Manual

                                                                              Source Iowa DOT Design Manual

                                                                              Attainment of Superelevationon spiral curves

                                                                              See sketches that follow

                                                                              Normal Crown (DOT ndash pt A)

                                                                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                              65Source Iowa DOT Standard Road Plans RP-2

                                                                              With Spirals

                                                                              Same as point E of GB

                                                                              With Spirals

                                                                              Tangent runout (A to B)

                                                                              With Spirals

                                                                              Removal of crown

                                                                              With Spirals

                                                                              Transition of superelevation

                                                                              Full superelevation

                                                                              69

                                                                              • Slide 1
                                                                              • Geometric Design ndash Basic Principles
                                                                              • GEOMETRIC DESIGN ndash Course Heads
                                                                              • Slide 4
                                                                              • Curves
                                                                              • Horizontal Curves
                                                                              • Design Elements
                                                                              • Slide 8
                                                                              • Slide 9
                                                                              • Slide 10
                                                                              • Slide 11
                                                                              • Horizontal Curves
                                                                              • Slide 13
                                                                              • Slide 14
                                                                              • Slide 15
                                                                              • Slide 16
                                                                              • Slide 17
                                                                              • Slide 18
                                                                              • Horizontal Curve Sight Distance
                                                                              • Slide 20
                                                                              • Slide 21
                                                                              • Slide 22
                                                                              • Slide 23
                                                                              • Slide 24
                                                                              • Slide 25
                                                                              • TRANSITIONS Superelevation Spiral Curves
                                                                              • Superelevation
                                                                              • Image
                                                                              • Superelevation Transitioning
                                                                              • Slide 30
                                                                              • Attainment of Superelevation - General
                                                                              • Tangent Runout Section
                                                                              • Superelevation Runoff Section
                                                                              • Slide 34
                                                                              • Slide 35
                                                                              • Slide 36
                                                                              • Slide 37
                                                                              • Slide 38
                                                                              • Slide 39
                                                                              • Slide 40
                                                                              • Slide 41
                                                                              • Attainment Location - WHERE
                                                                              • Minimum Length of Runoff for curve
                                                                              • Minimum Length of Tangent Runout
                                                                              • Length of Superelevation Runoff
                                                                              • Relative Gradient (G)
                                                                              • Maximum Relative Gradient (G)
                                                                              • Multilane Adjustment
                                                                              • Length of Superelevation Runoff Example
                                                                              • Slide 50
                                                                              • Tangent runout length Example continued
                                                                              • Slide 52
                                                                              • Spiral Curve Transitions
                                                                              • Slide 54
                                                                              • Spirals
                                                                              • Minimum Length of Spiral
                                                                              • Slide 57
                                                                              • Maximum Length of Spiral
                                                                              • Length of Spiral
                                                                              • Slide 60
                                                                              • Slide 61
                                                                              • Slide 62
                                                                              • Slide 63
                                                                              • Attainment of Superelevation on spiral curves
                                                                              • Slide 65
                                                                              • Slide 66
                                                                              • Slide 67
                                                                              • Slide 68
                                                                              • Slide 69

                                                                                40

                                                                                Source CalTrans Design Manual online httpwwwdotcagovhqoppdhdmpdfchp0200pdf

                                                                                Same as point E of GB

                                                                                Attainment Location - WHERE

                                                                                Superelevation must be attained over a length that includes the tangent and the curve

                                                                                Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                                Super runoff is all attained in Spiral if used

                                                                                Minimum Length of Runoff for curve

                                                                                Lr based on drainage and aesthetics

                                                                                rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                                current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                                Minimum Length of Tangent Runout

                                                                                Lt = eNC x Lr

                                                                                ed

                                                                                where

                                                                                eNC = normal cross slope rate ()

                                                                                ed = design superelevation rate

                                                                                Lr = minimum length of superelevation runoff (ft)

                                                                                (Result is the edge slope is same as for Runoff segment)

                                                                                Length of Superelevation Runoff

                                                                                α = multilane adjustment factor adjusts for total width

                                                                                r

                                                                                Relative Gradient (G)

                                                                                Maximum longitudinal slope Depends on design speed higher speed =

                                                                                gentler slope

                                                                                For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                Maximum Relative Gradient (G)

                                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                Multilane Adjustment

                                                                                Runout and runoff must be adjusted for multilane rotation

                                                                                See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                Length of Superelevation Runoff Example

                                                                                For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                Lr = 12eα

                                                                                G

                                                                                50

                                                                                Lr = 12eα = (12) (004) (15)

                                                                                G 05

                                                                                Lr = 144 feet

                                                                                Tangent runout length Example continued

                                                                                Lt = (eNC ed ) x Lr

                                                                                as defined previously if NC = 2

                                                                                Tangent runout for the example is

                                                                                LT = 2 4 144rsquo = 72 feet

                                                                                52

                                                                                From previous example speed = 50 mph e = 4

                                                                                From chart runoff = 144 feet same as from calculation

                                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                leave a horizontal curve

                                                                                Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                Spirals Advantages

                                                                                Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                Provides location for superelevation runoff (not part on tangentcurve)

                                                                                Provides transition in width when horizontal curve is widened

                                                                                Aesthetic

                                                                                Minimum Length of Spiral

                                                                                Possible Equations

                                                                                Larger of (1) L = 315 V3

                                                                                RC

                                                                                Where

                                                                                L = minimum length of spiral (ft)

                                                                                V = speed (mph)

                                                                                R = curve radius (ft)

                                                                                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                Minimum Length of Spiral

                                                                                Or (2) L = (24pminR)12

                                                                                Where

                                                                                L = minimum length of spiral (ft)

                                                                                R = curve radius (ft)

                                                                                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                Maximum Length of Spiral

                                                                                L = (24pmaxR)12

                                                                                Where

                                                                                L = maximum length of spiral (ft)

                                                                                R = curve radius (ft)

                                                                                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                Ls = 147 feet round it to

                                                                                Ls = 150 feet

                                                                                Source Iowa DOT Design Manual

                                                                                SPIRAL TERMINOLOGY

                                                                                Source Iowa DOT Design Manual

                                                                                Source Iowa DOT Design Manual

                                                                                Source Iowa DOT Design Manual

                                                                                Attainment of Superelevationon spiral curves

                                                                                See sketches that follow

                                                                                Normal Crown (DOT ndash pt A)

                                                                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                65Source Iowa DOT Standard Road Plans RP-2

                                                                                With Spirals

                                                                                Same as point E of GB

                                                                                With Spirals

                                                                                Tangent runout (A to B)

                                                                                With Spirals

                                                                                Removal of crown

                                                                                With Spirals

                                                                                Transition of superelevation

                                                                                Full superelevation

                                                                                69

                                                                                • Slide 1
                                                                                • Geometric Design ndash Basic Principles
                                                                                • GEOMETRIC DESIGN ndash Course Heads
                                                                                • Slide 4
                                                                                • Curves
                                                                                • Horizontal Curves
                                                                                • Design Elements
                                                                                • Slide 8
                                                                                • Slide 9
                                                                                • Slide 10
                                                                                • Slide 11
                                                                                • Horizontal Curves
                                                                                • Slide 13
                                                                                • Slide 14
                                                                                • Slide 15
                                                                                • Slide 16
                                                                                • Slide 17
                                                                                • Slide 18
                                                                                • Horizontal Curve Sight Distance
                                                                                • Slide 20
                                                                                • Slide 21
                                                                                • Slide 22
                                                                                • Slide 23
                                                                                • Slide 24
                                                                                • Slide 25
                                                                                • TRANSITIONS Superelevation Spiral Curves
                                                                                • Superelevation
                                                                                • Image
                                                                                • Superelevation Transitioning
                                                                                • Slide 30
                                                                                • Attainment of Superelevation - General
                                                                                • Tangent Runout Section
                                                                                • Superelevation Runoff Section
                                                                                • Slide 34
                                                                                • Slide 35
                                                                                • Slide 36
                                                                                • Slide 37
                                                                                • Slide 38
                                                                                • Slide 39
                                                                                • Slide 40
                                                                                • Slide 41
                                                                                • Attainment Location - WHERE
                                                                                • Minimum Length of Runoff for curve
                                                                                • Minimum Length of Tangent Runout
                                                                                • Length of Superelevation Runoff
                                                                                • Relative Gradient (G)
                                                                                • Maximum Relative Gradient (G)
                                                                                • Multilane Adjustment
                                                                                • Length of Superelevation Runoff Example
                                                                                • Slide 50
                                                                                • Tangent runout length Example continued
                                                                                • Slide 52
                                                                                • Spiral Curve Transitions
                                                                                • Slide 54
                                                                                • Spirals
                                                                                • Minimum Length of Spiral
                                                                                • Slide 57
                                                                                • Maximum Length of Spiral
                                                                                • Length of Spiral
                                                                                • Slide 60
                                                                                • Slide 61
                                                                                • Slide 62
                                                                                • Slide 63
                                                                                • Attainment of Superelevation on spiral curves
                                                                                • Slide 65
                                                                                • Slide 66
                                                                                • Slide 67
                                                                                • Slide 68
                                                                                • Slide 69

                                                                                  Same as point E of GB

                                                                                  Attainment Location - WHERE

                                                                                  Superelevation must be attained over a length that includes the tangent and the curve

                                                                                  Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                                  Super runoff is all attained in Spiral if used

                                                                                  Minimum Length of Runoff for curve

                                                                                  Lr based on drainage and aesthetics

                                                                                  rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                                  current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                                  Minimum Length of Tangent Runout

                                                                                  Lt = eNC x Lr

                                                                                  ed

                                                                                  where

                                                                                  eNC = normal cross slope rate ()

                                                                                  ed = design superelevation rate

                                                                                  Lr = minimum length of superelevation runoff (ft)

                                                                                  (Result is the edge slope is same as for Runoff segment)

                                                                                  Length of Superelevation Runoff

                                                                                  α = multilane adjustment factor adjusts for total width

                                                                                  r

                                                                                  Relative Gradient (G)

                                                                                  Maximum longitudinal slope Depends on design speed higher speed =

                                                                                  gentler slope

                                                                                  For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                  Maximum Relative Gradient (G)

                                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                  Multilane Adjustment

                                                                                  Runout and runoff must be adjusted for multilane rotation

                                                                                  See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                  Length of Superelevation Runoff Example

                                                                                  For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                  Lr = 12eα

                                                                                  G

                                                                                  50

                                                                                  Lr = 12eα = (12) (004) (15)

                                                                                  G 05

                                                                                  Lr = 144 feet

                                                                                  Tangent runout length Example continued

                                                                                  Lt = (eNC ed ) x Lr

                                                                                  as defined previously if NC = 2

                                                                                  Tangent runout for the example is

                                                                                  LT = 2 4 144rsquo = 72 feet

                                                                                  52

                                                                                  From previous example speed = 50 mph e = 4

                                                                                  From chart runoff = 144 feet same as from calculation

                                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                  Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                  Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                  leave a horizontal curve

                                                                                  Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                  Spirals Advantages

                                                                                  Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                  Provides location for superelevation runoff (not part on tangentcurve)

                                                                                  Provides transition in width when horizontal curve is widened

                                                                                  Aesthetic

                                                                                  Minimum Length of Spiral

                                                                                  Possible Equations

                                                                                  Larger of (1) L = 315 V3

                                                                                  RC

                                                                                  Where

                                                                                  L = minimum length of spiral (ft)

                                                                                  V = speed (mph)

                                                                                  R = curve radius (ft)

                                                                                  C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                  Minimum Length of Spiral

                                                                                  Or (2) L = (24pminR)12

                                                                                  Where

                                                                                  L = minimum length of spiral (ft)

                                                                                  R = curve radius (ft)

                                                                                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                  Maximum Length of Spiral

                                                                                  L = (24pmaxR)12

                                                                                  Where

                                                                                  L = maximum length of spiral (ft)

                                                                                  R = curve radius (ft)

                                                                                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                  Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                  o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                  Ls = 147 feet round it to

                                                                                  Ls = 150 feet

                                                                                  Source Iowa DOT Design Manual

                                                                                  SPIRAL TERMINOLOGY

                                                                                  Source Iowa DOT Design Manual

                                                                                  Source Iowa DOT Design Manual

                                                                                  Source Iowa DOT Design Manual

                                                                                  Attainment of Superelevationon spiral curves

                                                                                  See sketches that follow

                                                                                  Normal Crown (DOT ndash pt A)

                                                                                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                  65Source Iowa DOT Standard Road Plans RP-2

                                                                                  With Spirals

                                                                                  Same as point E of GB

                                                                                  With Spirals

                                                                                  Tangent runout (A to B)

                                                                                  With Spirals

                                                                                  Removal of crown

                                                                                  With Spirals

                                                                                  Transition of superelevation

                                                                                  Full superelevation

                                                                                  69

                                                                                  • Slide 1
                                                                                  • Geometric Design ndash Basic Principles
                                                                                  • GEOMETRIC DESIGN ndash Course Heads
                                                                                  • Slide 4
                                                                                  • Curves
                                                                                  • Horizontal Curves
                                                                                  • Design Elements
                                                                                  • Slide 8
                                                                                  • Slide 9
                                                                                  • Slide 10
                                                                                  • Slide 11
                                                                                  • Horizontal Curves
                                                                                  • Slide 13
                                                                                  • Slide 14
                                                                                  • Slide 15
                                                                                  • Slide 16
                                                                                  • Slide 17
                                                                                  • Slide 18
                                                                                  • Horizontal Curve Sight Distance
                                                                                  • Slide 20
                                                                                  • Slide 21
                                                                                  • Slide 22
                                                                                  • Slide 23
                                                                                  • Slide 24
                                                                                  • Slide 25
                                                                                  • TRANSITIONS Superelevation Spiral Curves
                                                                                  • Superelevation
                                                                                  • Image
                                                                                  • Superelevation Transitioning
                                                                                  • Slide 30
                                                                                  • Attainment of Superelevation - General
                                                                                  • Tangent Runout Section
                                                                                  • Superelevation Runoff Section
                                                                                  • Slide 34
                                                                                  • Slide 35
                                                                                  • Slide 36
                                                                                  • Slide 37
                                                                                  • Slide 38
                                                                                  • Slide 39
                                                                                  • Slide 40
                                                                                  • Slide 41
                                                                                  • Attainment Location - WHERE
                                                                                  • Minimum Length of Runoff for curve
                                                                                  • Minimum Length of Tangent Runout
                                                                                  • Length of Superelevation Runoff
                                                                                  • Relative Gradient (G)
                                                                                  • Maximum Relative Gradient (G)
                                                                                  • Multilane Adjustment
                                                                                  • Length of Superelevation Runoff Example
                                                                                  • Slide 50
                                                                                  • Tangent runout length Example continued
                                                                                  • Slide 52
                                                                                  • Spiral Curve Transitions
                                                                                  • Slide 54
                                                                                  • Spirals
                                                                                  • Minimum Length of Spiral
                                                                                  • Slide 57
                                                                                  • Maximum Length of Spiral
                                                                                  • Length of Spiral
                                                                                  • Slide 60
                                                                                  • Slide 61
                                                                                  • Slide 62
                                                                                  • Slide 63
                                                                                  • Attainment of Superelevation on spiral curves
                                                                                  • Slide 65
                                                                                  • Slide 66
                                                                                  • Slide 67
                                                                                  • Slide 68
                                                                                  • Slide 69

                                                                                    Attainment Location - WHERE

                                                                                    Superelevation must be attained over a length that includes the tangent and the curve

                                                                                    Typical 66 on tangent and 33 on curve of length of runoff if no spiral

                                                                                    Super runoff is all attained in Spiral if used

                                                                                    Minimum Length of Runoff for curve

                                                                                    Lr based on drainage and aesthetics

                                                                                    rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                                    current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                                    Minimum Length of Tangent Runout

                                                                                    Lt = eNC x Lr

                                                                                    ed

                                                                                    where

                                                                                    eNC = normal cross slope rate ()

                                                                                    ed = design superelevation rate

                                                                                    Lr = minimum length of superelevation runoff (ft)

                                                                                    (Result is the edge slope is same as for Runoff segment)

                                                                                    Length of Superelevation Runoff

                                                                                    α = multilane adjustment factor adjusts for total width

                                                                                    r

                                                                                    Relative Gradient (G)

                                                                                    Maximum longitudinal slope Depends on design speed higher speed =

                                                                                    gentler slope

                                                                                    For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                    Maximum Relative Gradient (G)

                                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                    Multilane Adjustment

                                                                                    Runout and runoff must be adjusted for multilane rotation

                                                                                    See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                    Length of Superelevation Runoff Example

                                                                                    For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                    Lr = 12eα

                                                                                    G

                                                                                    50

                                                                                    Lr = 12eα = (12) (004) (15)

                                                                                    G 05

                                                                                    Lr = 144 feet

                                                                                    Tangent runout length Example continued

                                                                                    Lt = (eNC ed ) x Lr

                                                                                    as defined previously if NC = 2

                                                                                    Tangent runout for the example is

                                                                                    LT = 2 4 144rsquo = 72 feet

                                                                                    52

                                                                                    From previous example speed = 50 mph e = 4

                                                                                    From chart runoff = 144 feet same as from calculation

                                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                    Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                    leave a horizontal curve

                                                                                    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                    Spirals Advantages

                                                                                    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                    Provides location for superelevation runoff (not part on tangentcurve)

                                                                                    Provides transition in width when horizontal curve is widened

                                                                                    Aesthetic

                                                                                    Minimum Length of Spiral

                                                                                    Possible Equations

                                                                                    Larger of (1) L = 315 V3

                                                                                    RC

                                                                                    Where

                                                                                    L = minimum length of spiral (ft)

                                                                                    V = speed (mph)

                                                                                    R = curve radius (ft)

                                                                                    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                    Minimum Length of Spiral

                                                                                    Or (2) L = (24pminR)12

                                                                                    Where

                                                                                    L = minimum length of spiral (ft)

                                                                                    R = curve radius (ft)

                                                                                    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                    Maximum Length of Spiral

                                                                                    L = (24pmaxR)12

                                                                                    Where

                                                                                    L = maximum length of spiral (ft)

                                                                                    R = curve radius (ft)

                                                                                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                    Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                    o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                    Ls = 147 feet round it to

                                                                                    Ls = 150 feet

                                                                                    Source Iowa DOT Design Manual

                                                                                    SPIRAL TERMINOLOGY

                                                                                    Source Iowa DOT Design Manual

                                                                                    Source Iowa DOT Design Manual

                                                                                    Source Iowa DOT Design Manual

                                                                                    Attainment of Superelevationon spiral curves

                                                                                    See sketches that follow

                                                                                    Normal Crown (DOT ndash pt A)

                                                                                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                    65Source Iowa DOT Standard Road Plans RP-2

                                                                                    With Spirals

                                                                                    Same as point E of GB

                                                                                    With Spirals

                                                                                    Tangent runout (A to B)

                                                                                    With Spirals

                                                                                    Removal of crown

                                                                                    With Spirals

                                                                                    Transition of superelevation

                                                                                    Full superelevation

                                                                                    69

                                                                                    • Slide 1
                                                                                    • Geometric Design ndash Basic Principles
                                                                                    • GEOMETRIC DESIGN ndash Course Heads
                                                                                    • Slide 4
                                                                                    • Curves
                                                                                    • Horizontal Curves
                                                                                    • Design Elements
                                                                                    • Slide 8
                                                                                    • Slide 9
                                                                                    • Slide 10
                                                                                    • Slide 11
                                                                                    • Horizontal Curves
                                                                                    • Slide 13
                                                                                    • Slide 14
                                                                                    • Slide 15
                                                                                    • Slide 16
                                                                                    • Slide 17
                                                                                    • Slide 18
                                                                                    • Horizontal Curve Sight Distance
                                                                                    • Slide 20
                                                                                    • Slide 21
                                                                                    • Slide 22
                                                                                    • Slide 23
                                                                                    • Slide 24
                                                                                    • Slide 25
                                                                                    • TRANSITIONS Superelevation Spiral Curves
                                                                                    • Superelevation
                                                                                    • Image
                                                                                    • Superelevation Transitioning
                                                                                    • Slide 30
                                                                                    • Attainment of Superelevation - General
                                                                                    • Tangent Runout Section
                                                                                    • Superelevation Runoff Section
                                                                                    • Slide 34
                                                                                    • Slide 35
                                                                                    • Slide 36
                                                                                    • Slide 37
                                                                                    • Slide 38
                                                                                    • Slide 39
                                                                                    • Slide 40
                                                                                    • Slide 41
                                                                                    • Attainment Location - WHERE
                                                                                    • Minimum Length of Runoff for curve
                                                                                    • Minimum Length of Tangent Runout
                                                                                    • Length of Superelevation Runoff
                                                                                    • Relative Gradient (G)
                                                                                    • Maximum Relative Gradient (G)
                                                                                    • Multilane Adjustment
                                                                                    • Length of Superelevation Runoff Example
                                                                                    • Slide 50
                                                                                    • Tangent runout length Example continued
                                                                                    • Slide 52
                                                                                    • Spiral Curve Transitions
                                                                                    • Slide 54
                                                                                    • Spirals
                                                                                    • Minimum Length of Spiral
                                                                                    • Slide 57
                                                                                    • Maximum Length of Spiral
                                                                                    • Length of Spiral
                                                                                    • Slide 60
                                                                                    • Slide 61
                                                                                    • Slide 62
                                                                                    • Slide 63
                                                                                    • Attainment of Superelevation on spiral curves
                                                                                    • Slide 65
                                                                                    • Slide 66
                                                                                    • Slide 67
                                                                                    • Slide 68
                                                                                    • Slide 69

                                                                                      Minimum Length of Runoff for curve

                                                                                      Lr based on drainage and aesthetics

                                                                                      rate of transition of edge line from NC to full Superelevation traditionally taken at 05 (1 foot rise per 200 feet along the road)

                                                                                      current recommendation varies from 035 at 80 mph to 080 for 15 mph (with further adjustments for number of lanes)

                                                                                      Minimum Length of Tangent Runout

                                                                                      Lt = eNC x Lr

                                                                                      ed

                                                                                      where

                                                                                      eNC = normal cross slope rate ()

                                                                                      ed = design superelevation rate

                                                                                      Lr = minimum length of superelevation runoff (ft)

                                                                                      (Result is the edge slope is same as for Runoff segment)

                                                                                      Length of Superelevation Runoff

                                                                                      α = multilane adjustment factor adjusts for total width

                                                                                      r

                                                                                      Relative Gradient (G)

                                                                                      Maximum longitudinal slope Depends on design speed higher speed =

                                                                                      gentler slope

                                                                                      For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                      Maximum Relative Gradient (G)

                                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                      Multilane Adjustment

                                                                                      Runout and runoff must be adjusted for multilane rotation

                                                                                      See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                      Length of Superelevation Runoff Example

                                                                                      For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                      Lr = 12eα

                                                                                      G

                                                                                      50

                                                                                      Lr = 12eα = (12) (004) (15)

                                                                                      G 05

                                                                                      Lr = 144 feet

                                                                                      Tangent runout length Example continued

                                                                                      Lt = (eNC ed ) x Lr

                                                                                      as defined previously if NC = 2

                                                                                      Tangent runout for the example is

                                                                                      LT = 2 4 144rsquo = 72 feet

                                                                                      52

                                                                                      From previous example speed = 50 mph e = 4

                                                                                      From chart runoff = 144 feet same as from calculation

                                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                      Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                      leave a horizontal curve

                                                                                      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                      Spirals Advantages

                                                                                      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                      Provides location for superelevation runoff (not part on tangentcurve)

                                                                                      Provides transition in width when horizontal curve is widened

                                                                                      Aesthetic

                                                                                      Minimum Length of Spiral

                                                                                      Possible Equations

                                                                                      Larger of (1) L = 315 V3

                                                                                      RC

                                                                                      Where

                                                                                      L = minimum length of spiral (ft)

                                                                                      V = speed (mph)

                                                                                      R = curve radius (ft)

                                                                                      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                      Minimum Length of Spiral

                                                                                      Or (2) L = (24pminR)12

                                                                                      Where

                                                                                      L = minimum length of spiral (ft)

                                                                                      R = curve radius (ft)

                                                                                      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                      Maximum Length of Spiral

                                                                                      L = (24pmaxR)12

                                                                                      Where

                                                                                      L = maximum length of spiral (ft)

                                                                                      R = curve radius (ft)

                                                                                      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                      Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                      o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                      Ls = 147 feet round it to

                                                                                      Ls = 150 feet

                                                                                      Source Iowa DOT Design Manual

                                                                                      SPIRAL TERMINOLOGY

                                                                                      Source Iowa DOT Design Manual

                                                                                      Source Iowa DOT Design Manual

                                                                                      Source Iowa DOT Design Manual

                                                                                      Attainment of Superelevationon spiral curves

                                                                                      See sketches that follow

                                                                                      Normal Crown (DOT ndash pt A)

                                                                                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                      65Source Iowa DOT Standard Road Plans RP-2

                                                                                      With Spirals

                                                                                      Same as point E of GB

                                                                                      With Spirals

                                                                                      Tangent runout (A to B)

                                                                                      With Spirals

                                                                                      Removal of crown

                                                                                      With Spirals

                                                                                      Transition of superelevation

                                                                                      Full superelevation

                                                                                      69

                                                                                      • Slide 1
                                                                                      • Geometric Design ndash Basic Principles
                                                                                      • GEOMETRIC DESIGN ndash Course Heads
                                                                                      • Slide 4
                                                                                      • Curves
                                                                                      • Horizontal Curves
                                                                                      • Design Elements
                                                                                      • Slide 8
                                                                                      • Slide 9
                                                                                      • Slide 10
                                                                                      • Slide 11
                                                                                      • Horizontal Curves
                                                                                      • Slide 13
                                                                                      • Slide 14
                                                                                      • Slide 15
                                                                                      • Slide 16
                                                                                      • Slide 17
                                                                                      • Slide 18
                                                                                      • Horizontal Curve Sight Distance
                                                                                      • Slide 20
                                                                                      • Slide 21
                                                                                      • Slide 22
                                                                                      • Slide 23
                                                                                      • Slide 24
                                                                                      • Slide 25
                                                                                      • TRANSITIONS Superelevation Spiral Curves
                                                                                      • Superelevation
                                                                                      • Image
                                                                                      • Superelevation Transitioning
                                                                                      • Slide 30
                                                                                      • Attainment of Superelevation - General
                                                                                      • Tangent Runout Section
                                                                                      • Superelevation Runoff Section
                                                                                      • Slide 34
                                                                                      • Slide 35
                                                                                      • Slide 36
                                                                                      • Slide 37
                                                                                      • Slide 38
                                                                                      • Slide 39
                                                                                      • Slide 40
                                                                                      • Slide 41
                                                                                      • Attainment Location - WHERE
                                                                                      • Minimum Length of Runoff for curve
                                                                                      • Minimum Length of Tangent Runout
                                                                                      • Length of Superelevation Runoff
                                                                                      • Relative Gradient (G)
                                                                                      • Maximum Relative Gradient (G)
                                                                                      • Multilane Adjustment
                                                                                      • Length of Superelevation Runoff Example
                                                                                      • Slide 50
                                                                                      • Tangent runout length Example continued
                                                                                      • Slide 52
                                                                                      • Spiral Curve Transitions
                                                                                      • Slide 54
                                                                                      • Spirals
                                                                                      • Minimum Length of Spiral
                                                                                      • Slide 57
                                                                                      • Maximum Length of Spiral
                                                                                      • Length of Spiral
                                                                                      • Slide 60
                                                                                      • Slide 61
                                                                                      • Slide 62
                                                                                      • Slide 63
                                                                                      • Attainment of Superelevation on spiral curves
                                                                                      • Slide 65
                                                                                      • Slide 66
                                                                                      • Slide 67
                                                                                      • Slide 68
                                                                                      • Slide 69

                                                                                        Minimum Length of Tangent Runout

                                                                                        Lt = eNC x Lr

                                                                                        ed

                                                                                        where

                                                                                        eNC = normal cross slope rate ()

                                                                                        ed = design superelevation rate

                                                                                        Lr = minimum length of superelevation runoff (ft)

                                                                                        (Result is the edge slope is same as for Runoff segment)

                                                                                        Length of Superelevation Runoff

                                                                                        α = multilane adjustment factor adjusts for total width

                                                                                        r

                                                                                        Relative Gradient (G)

                                                                                        Maximum longitudinal slope Depends on design speed higher speed =

                                                                                        gentler slope

                                                                                        For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                        Maximum Relative Gradient (G)

                                                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                        Multilane Adjustment

                                                                                        Runout and runoff must be adjusted for multilane rotation

                                                                                        See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                        Length of Superelevation Runoff Example

                                                                                        For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                        Lr = 12eα

                                                                                        G

                                                                                        50

                                                                                        Lr = 12eα = (12) (004) (15)

                                                                                        G 05

                                                                                        Lr = 144 feet

                                                                                        Tangent runout length Example continued

                                                                                        Lt = (eNC ed ) x Lr

                                                                                        as defined previously if NC = 2

                                                                                        Tangent runout for the example is

                                                                                        LT = 2 4 144rsquo = 72 feet

                                                                                        52

                                                                                        From previous example speed = 50 mph e = 4

                                                                                        From chart runoff = 144 feet same as from calculation

                                                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                        Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                        leave a horizontal curve

                                                                                        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                        Spirals Advantages

                                                                                        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                        Provides location for superelevation runoff (not part on tangentcurve)

                                                                                        Provides transition in width when horizontal curve is widened

                                                                                        Aesthetic

                                                                                        Minimum Length of Spiral

                                                                                        Possible Equations

                                                                                        Larger of (1) L = 315 V3

                                                                                        RC

                                                                                        Where

                                                                                        L = minimum length of spiral (ft)

                                                                                        V = speed (mph)

                                                                                        R = curve radius (ft)

                                                                                        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                        Minimum Length of Spiral

                                                                                        Or (2) L = (24pminR)12

                                                                                        Where

                                                                                        L = minimum length of spiral (ft)

                                                                                        R = curve radius (ft)

                                                                                        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                        Maximum Length of Spiral

                                                                                        L = (24pmaxR)12

                                                                                        Where

                                                                                        L = maximum length of spiral (ft)

                                                                                        R = curve radius (ft)

                                                                                        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                        Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                        o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                        Ls = 147 feet round it to

                                                                                        Ls = 150 feet

                                                                                        Source Iowa DOT Design Manual

                                                                                        SPIRAL TERMINOLOGY

                                                                                        Source Iowa DOT Design Manual

                                                                                        Source Iowa DOT Design Manual

                                                                                        Source Iowa DOT Design Manual

                                                                                        Attainment of Superelevationon spiral curves

                                                                                        See sketches that follow

                                                                                        Normal Crown (DOT ndash pt A)

                                                                                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                        65Source Iowa DOT Standard Road Plans RP-2

                                                                                        With Spirals

                                                                                        Same as point E of GB

                                                                                        With Spirals

                                                                                        Tangent runout (A to B)

                                                                                        With Spirals

                                                                                        Removal of crown

                                                                                        With Spirals

                                                                                        Transition of superelevation

                                                                                        Full superelevation

                                                                                        69

                                                                                        • Slide 1
                                                                                        • Geometric Design ndash Basic Principles
                                                                                        • GEOMETRIC DESIGN ndash Course Heads
                                                                                        • Slide 4
                                                                                        • Curves
                                                                                        • Horizontal Curves
                                                                                        • Design Elements
                                                                                        • Slide 8
                                                                                        • Slide 9
                                                                                        • Slide 10
                                                                                        • Slide 11
                                                                                        • Horizontal Curves
                                                                                        • Slide 13
                                                                                        • Slide 14
                                                                                        • Slide 15
                                                                                        • Slide 16
                                                                                        • Slide 17
                                                                                        • Slide 18
                                                                                        • Horizontal Curve Sight Distance
                                                                                        • Slide 20
                                                                                        • Slide 21
                                                                                        • Slide 22
                                                                                        • Slide 23
                                                                                        • Slide 24
                                                                                        • Slide 25
                                                                                        • TRANSITIONS Superelevation Spiral Curves
                                                                                        • Superelevation
                                                                                        • Image
                                                                                        • Superelevation Transitioning
                                                                                        • Slide 30
                                                                                        • Attainment of Superelevation - General
                                                                                        • Tangent Runout Section
                                                                                        • Superelevation Runoff Section
                                                                                        • Slide 34
                                                                                        • Slide 35
                                                                                        • Slide 36
                                                                                        • Slide 37
                                                                                        • Slide 38
                                                                                        • Slide 39
                                                                                        • Slide 40
                                                                                        • Slide 41
                                                                                        • Attainment Location - WHERE
                                                                                        • Minimum Length of Runoff for curve
                                                                                        • Minimum Length of Tangent Runout
                                                                                        • Length of Superelevation Runoff
                                                                                        • Relative Gradient (G)
                                                                                        • Maximum Relative Gradient (G)
                                                                                        • Multilane Adjustment
                                                                                        • Length of Superelevation Runoff Example
                                                                                        • Slide 50
                                                                                        • Tangent runout length Example continued
                                                                                        • Slide 52
                                                                                        • Spiral Curve Transitions
                                                                                        • Slide 54
                                                                                        • Spirals
                                                                                        • Minimum Length of Spiral
                                                                                        • Slide 57
                                                                                        • Maximum Length of Spiral
                                                                                        • Length of Spiral
                                                                                        • Slide 60
                                                                                        • Slide 61
                                                                                        • Slide 62
                                                                                        • Slide 63
                                                                                        • Attainment of Superelevation on spiral curves
                                                                                        • Slide 65
                                                                                        • Slide 66
                                                                                        • Slide 67
                                                                                        • Slide 68
                                                                                        • Slide 69

                                                                                          Length of Superelevation Runoff

                                                                                          α = multilane adjustment factor adjusts for total width

                                                                                          r

                                                                                          Relative Gradient (G)

                                                                                          Maximum longitudinal slope Depends on design speed higher speed =

                                                                                          gentler slope

                                                                                          For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                          Maximum Relative Gradient (G)

                                                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                          Multilane Adjustment

                                                                                          Runout and runoff must be adjusted for multilane rotation

                                                                                          See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                          Length of Superelevation Runoff Example

                                                                                          For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                          Lr = 12eα

                                                                                          G

                                                                                          50

                                                                                          Lr = 12eα = (12) (004) (15)

                                                                                          G 05

                                                                                          Lr = 144 feet

                                                                                          Tangent runout length Example continued

                                                                                          Lt = (eNC ed ) x Lr

                                                                                          as defined previously if NC = 2

                                                                                          Tangent runout for the example is

                                                                                          LT = 2 4 144rsquo = 72 feet

                                                                                          52

                                                                                          From previous example speed = 50 mph e = 4

                                                                                          From chart runoff = 144 feet same as from calculation

                                                                                          Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                          Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                          leave a horizontal curve

                                                                                          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                          Spirals Advantages

                                                                                          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                          Provides location for superelevation runoff (not part on tangentcurve)

                                                                                          Provides transition in width when horizontal curve is widened

                                                                                          Aesthetic

                                                                                          Minimum Length of Spiral

                                                                                          Possible Equations

                                                                                          Larger of (1) L = 315 V3

                                                                                          RC

                                                                                          Where

                                                                                          L = minimum length of spiral (ft)

                                                                                          V = speed (mph)

                                                                                          R = curve radius (ft)

                                                                                          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                          Minimum Length of Spiral

                                                                                          Or (2) L = (24pminR)12

                                                                                          Where

                                                                                          L = minimum length of spiral (ft)

                                                                                          R = curve radius (ft)

                                                                                          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                          Maximum Length of Spiral

                                                                                          L = (24pmaxR)12

                                                                                          Where

                                                                                          L = maximum length of spiral (ft)

                                                                                          R = curve radius (ft)

                                                                                          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                          Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                          o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                          Ls = 147 feet round it to

                                                                                          Ls = 150 feet

                                                                                          Source Iowa DOT Design Manual

                                                                                          SPIRAL TERMINOLOGY

                                                                                          Source Iowa DOT Design Manual

                                                                                          Source Iowa DOT Design Manual

                                                                                          Source Iowa DOT Design Manual

                                                                                          Attainment of Superelevationon spiral curves

                                                                                          See sketches that follow

                                                                                          Normal Crown (DOT ndash pt A)

                                                                                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                          65Source Iowa DOT Standard Road Plans RP-2

                                                                                          With Spirals

                                                                                          Same as point E of GB

                                                                                          With Spirals

                                                                                          Tangent runout (A to B)

                                                                                          With Spirals

                                                                                          Removal of crown

                                                                                          With Spirals

                                                                                          Transition of superelevation

                                                                                          Full superelevation

                                                                                          69

                                                                                          • Slide 1
                                                                                          • Geometric Design ndash Basic Principles
                                                                                          • GEOMETRIC DESIGN ndash Course Heads
                                                                                          • Slide 4
                                                                                          • Curves
                                                                                          • Horizontal Curves
                                                                                          • Design Elements
                                                                                          • Slide 8
                                                                                          • Slide 9
                                                                                          • Slide 10
                                                                                          • Slide 11
                                                                                          • Horizontal Curves
                                                                                          • Slide 13
                                                                                          • Slide 14
                                                                                          • Slide 15
                                                                                          • Slide 16
                                                                                          • Slide 17
                                                                                          • Slide 18
                                                                                          • Horizontal Curve Sight Distance
                                                                                          • Slide 20
                                                                                          • Slide 21
                                                                                          • Slide 22
                                                                                          • Slide 23
                                                                                          • Slide 24
                                                                                          • Slide 25
                                                                                          • TRANSITIONS Superelevation Spiral Curves
                                                                                          • Superelevation
                                                                                          • Image
                                                                                          • Superelevation Transitioning
                                                                                          • Slide 30
                                                                                          • Attainment of Superelevation - General
                                                                                          • Tangent Runout Section
                                                                                          • Superelevation Runoff Section
                                                                                          • Slide 34
                                                                                          • Slide 35
                                                                                          • Slide 36
                                                                                          • Slide 37
                                                                                          • Slide 38
                                                                                          • Slide 39
                                                                                          • Slide 40
                                                                                          • Slide 41
                                                                                          • Attainment Location - WHERE
                                                                                          • Minimum Length of Runoff for curve
                                                                                          • Minimum Length of Tangent Runout
                                                                                          • Length of Superelevation Runoff
                                                                                          • Relative Gradient (G)
                                                                                          • Maximum Relative Gradient (G)
                                                                                          • Multilane Adjustment
                                                                                          • Length of Superelevation Runoff Example
                                                                                          • Slide 50
                                                                                          • Tangent runout length Example continued
                                                                                          • Slide 52
                                                                                          • Spiral Curve Transitions
                                                                                          • Slide 54
                                                                                          • Spirals
                                                                                          • Minimum Length of Spiral
                                                                                          • Slide 57
                                                                                          • Maximum Length of Spiral
                                                                                          • Length of Spiral
                                                                                          • Slide 60
                                                                                          • Slide 61
                                                                                          • Slide 62
                                                                                          • Slide 63
                                                                                          • Attainment of Superelevation on spiral curves
                                                                                          • Slide 65
                                                                                          • Slide 66
                                                                                          • Slide 67
                                                                                          • Slide 68
                                                                                          • Slide 69

                                                                                            Relative Gradient (G)

                                                                                            Maximum longitudinal slope Depends on design speed higher speed =

                                                                                            gentler slope

                                                                                            For example For 15 mph G = 078 For 80 mph G = 035 See table next page

                                                                                            Maximum Relative Gradient (G)

                                                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                            Multilane Adjustment

                                                                                            Runout and runoff must be adjusted for multilane rotation

                                                                                            See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                            Length of Superelevation Runoff Example

                                                                                            For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                            Lr = 12eα

                                                                                            G

                                                                                            50

                                                                                            Lr = 12eα = (12) (004) (15)

                                                                                            G 05

                                                                                            Lr = 144 feet

                                                                                            Tangent runout length Example continued

                                                                                            Lt = (eNC ed ) x Lr

                                                                                            as defined previously if NC = 2

                                                                                            Tangent runout for the example is

                                                                                            LT = 2 4 144rsquo = 72 feet

                                                                                            52

                                                                                            From previous example speed = 50 mph e = 4

                                                                                            From chart runoff = 144 feet same as from calculation

                                                                                            Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                            Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                            Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                            leave a horizontal curve

                                                                                            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                            Spirals Advantages

                                                                                            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                            Provides location for superelevation runoff (not part on tangentcurve)

                                                                                            Provides transition in width when horizontal curve is widened

                                                                                            Aesthetic

                                                                                            Minimum Length of Spiral

                                                                                            Possible Equations

                                                                                            Larger of (1) L = 315 V3

                                                                                            RC

                                                                                            Where

                                                                                            L = minimum length of spiral (ft)

                                                                                            V = speed (mph)

                                                                                            R = curve radius (ft)

                                                                                            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                            Minimum Length of Spiral

                                                                                            Or (2) L = (24pminR)12

                                                                                            Where

                                                                                            L = minimum length of spiral (ft)

                                                                                            R = curve radius (ft)

                                                                                            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                            Maximum Length of Spiral

                                                                                            L = (24pmaxR)12

                                                                                            Where

                                                                                            L = maximum length of spiral (ft)

                                                                                            R = curve radius (ft)

                                                                                            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                            Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                            o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                            Ls = 147 feet round it to

                                                                                            Ls = 150 feet

                                                                                            Source Iowa DOT Design Manual

                                                                                            SPIRAL TERMINOLOGY

                                                                                            Source Iowa DOT Design Manual

                                                                                            Source Iowa DOT Design Manual

                                                                                            Source Iowa DOT Design Manual

                                                                                            Attainment of Superelevationon spiral curves

                                                                                            See sketches that follow

                                                                                            Normal Crown (DOT ndash pt A)

                                                                                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                            65Source Iowa DOT Standard Road Plans RP-2

                                                                                            With Spirals

                                                                                            Same as point E of GB

                                                                                            With Spirals

                                                                                            Tangent runout (A to B)

                                                                                            With Spirals

                                                                                            Removal of crown

                                                                                            With Spirals

                                                                                            Transition of superelevation

                                                                                            Full superelevation

                                                                                            69

                                                                                            • Slide 1
                                                                                            • Geometric Design ndash Basic Principles
                                                                                            • GEOMETRIC DESIGN ndash Course Heads
                                                                                            • Slide 4
                                                                                            • Curves
                                                                                            • Horizontal Curves
                                                                                            • Design Elements
                                                                                            • Slide 8
                                                                                            • Slide 9
                                                                                            • Slide 10
                                                                                            • Slide 11
                                                                                            • Horizontal Curves
                                                                                            • Slide 13
                                                                                            • Slide 14
                                                                                            • Slide 15
                                                                                            • Slide 16
                                                                                            • Slide 17
                                                                                            • Slide 18
                                                                                            • Horizontal Curve Sight Distance
                                                                                            • Slide 20
                                                                                            • Slide 21
                                                                                            • Slide 22
                                                                                            • Slide 23
                                                                                            • Slide 24
                                                                                            • Slide 25
                                                                                            • TRANSITIONS Superelevation Spiral Curves
                                                                                            • Superelevation
                                                                                            • Image
                                                                                            • Superelevation Transitioning
                                                                                            • Slide 30
                                                                                            • Attainment of Superelevation - General
                                                                                            • Tangent Runout Section
                                                                                            • Superelevation Runoff Section
                                                                                            • Slide 34
                                                                                            • Slide 35
                                                                                            • Slide 36
                                                                                            • Slide 37
                                                                                            • Slide 38
                                                                                            • Slide 39
                                                                                            • Slide 40
                                                                                            • Slide 41
                                                                                            • Attainment Location - WHERE
                                                                                            • Minimum Length of Runoff for curve
                                                                                            • Minimum Length of Tangent Runout
                                                                                            • Length of Superelevation Runoff
                                                                                            • Relative Gradient (G)
                                                                                            • Maximum Relative Gradient (G)
                                                                                            • Multilane Adjustment
                                                                                            • Length of Superelevation Runoff Example
                                                                                            • Slide 50
                                                                                            • Tangent runout length Example continued
                                                                                            • Slide 52
                                                                                            • Spiral Curve Transitions
                                                                                            • Slide 54
                                                                                            • Spirals
                                                                                            • Minimum Length of Spiral
                                                                                            • Slide 57
                                                                                            • Maximum Length of Spiral
                                                                                            • Length of Spiral
                                                                                            • Slide 60
                                                                                            • Slide 61
                                                                                            • Slide 62
                                                                                            • Slide 63
                                                                                            • Attainment of Superelevation on spiral curves
                                                                                            • Slide 65
                                                                                            • Slide 66
                                                                                            • Slide 67
                                                                                            • Slide 68
                                                                                            • Slide 69

                                                                                              Maximum Relative Gradient (G)

                                                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                              Multilane Adjustment

                                                                                              Runout and runoff must be adjusted for multilane rotation

                                                                                              See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                              Length of Superelevation Runoff Example

                                                                                              For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                              Lr = 12eα

                                                                                              G

                                                                                              50

                                                                                              Lr = 12eα = (12) (004) (15)

                                                                                              G 05

                                                                                              Lr = 144 feet

                                                                                              Tangent runout length Example continued

                                                                                              Lt = (eNC ed ) x Lr

                                                                                              as defined previously if NC = 2

                                                                                              Tangent runout for the example is

                                                                                              LT = 2 4 144rsquo = 72 feet

                                                                                              52

                                                                                              From previous example speed = 50 mph e = 4

                                                                                              From chart runoff = 144 feet same as from calculation

                                                                                              Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                              Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                              Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                              leave a horizontal curve

                                                                                              Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                              Spirals Advantages

                                                                                              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                              Provides location for superelevation runoff (not part on tangentcurve)

                                                                                              Provides transition in width when horizontal curve is widened

                                                                                              Aesthetic

                                                                                              Minimum Length of Spiral

                                                                                              Possible Equations

                                                                                              Larger of (1) L = 315 V3

                                                                                              RC

                                                                                              Where

                                                                                              L = minimum length of spiral (ft)

                                                                                              V = speed (mph)

                                                                                              R = curve radius (ft)

                                                                                              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                              Minimum Length of Spiral

                                                                                              Or (2) L = (24pminR)12

                                                                                              Where

                                                                                              L = minimum length of spiral (ft)

                                                                                              R = curve radius (ft)

                                                                                              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                              Maximum Length of Spiral

                                                                                              L = (24pmaxR)12

                                                                                              Where

                                                                                              L = maximum length of spiral (ft)

                                                                                              R = curve radius (ft)

                                                                                              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                              Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                              o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                              Ls = 147 feet round it to

                                                                                              Ls = 150 feet

                                                                                              Source Iowa DOT Design Manual

                                                                                              SPIRAL TERMINOLOGY

                                                                                              Source Iowa DOT Design Manual

                                                                                              Source Iowa DOT Design Manual

                                                                                              Source Iowa DOT Design Manual

                                                                                              Attainment of Superelevationon spiral curves

                                                                                              See sketches that follow

                                                                                              Normal Crown (DOT ndash pt A)

                                                                                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                              65Source Iowa DOT Standard Road Plans RP-2

                                                                                              With Spirals

                                                                                              Same as point E of GB

                                                                                              With Spirals

                                                                                              Tangent runout (A to B)

                                                                                              With Spirals

                                                                                              Removal of crown

                                                                                              With Spirals

                                                                                              Transition of superelevation

                                                                                              Full superelevation

                                                                                              69

                                                                                              • Slide 1
                                                                                              • Geometric Design ndash Basic Principles
                                                                                              • GEOMETRIC DESIGN ndash Course Heads
                                                                                              • Slide 4
                                                                                              • Curves
                                                                                              • Horizontal Curves
                                                                                              • Design Elements
                                                                                              • Slide 8
                                                                                              • Slide 9
                                                                                              • Slide 10
                                                                                              • Slide 11
                                                                                              • Horizontal Curves
                                                                                              • Slide 13
                                                                                              • Slide 14
                                                                                              • Slide 15
                                                                                              • Slide 16
                                                                                              • Slide 17
                                                                                              • Slide 18
                                                                                              • Horizontal Curve Sight Distance
                                                                                              • Slide 20
                                                                                              • Slide 21
                                                                                              • Slide 22
                                                                                              • Slide 23
                                                                                              • Slide 24
                                                                                              • Slide 25
                                                                                              • TRANSITIONS Superelevation Spiral Curves
                                                                                              • Superelevation
                                                                                              • Image
                                                                                              • Superelevation Transitioning
                                                                                              • Slide 30
                                                                                              • Attainment of Superelevation - General
                                                                                              • Tangent Runout Section
                                                                                              • Superelevation Runoff Section
                                                                                              • Slide 34
                                                                                              • Slide 35
                                                                                              • Slide 36
                                                                                              • Slide 37
                                                                                              • Slide 38
                                                                                              • Slide 39
                                                                                              • Slide 40
                                                                                              • Slide 41
                                                                                              • Attainment Location - WHERE
                                                                                              • Minimum Length of Runoff for curve
                                                                                              • Minimum Length of Tangent Runout
                                                                                              • Length of Superelevation Runoff
                                                                                              • Relative Gradient (G)
                                                                                              • Maximum Relative Gradient (G)
                                                                                              • Multilane Adjustment
                                                                                              • Length of Superelevation Runoff Example
                                                                                              • Slide 50
                                                                                              • Tangent runout length Example continued
                                                                                              • Slide 52
                                                                                              • Spiral Curve Transitions
                                                                                              • Slide 54
                                                                                              • Spirals
                                                                                              • Minimum Length of Spiral
                                                                                              • Slide 57
                                                                                              • Maximum Length of Spiral
                                                                                              • Length of Spiral
                                                                                              • Slide 60
                                                                                              • Slide 61
                                                                                              • Slide 62
                                                                                              • Slide 63
                                                                                              • Attainment of Superelevation on spiral curves
                                                                                              • Slide 65
                                                                                              • Slide 66
                                                                                              • Slide 67
                                                                                              • Slide 68
                                                                                              • Slide 69

                                                                                                Multilane Adjustment

                                                                                                Runout and runoff must be adjusted for multilane rotation

                                                                                                See Iowa DOT manual section 2A-2 and Standard Road Plan RP-2

                                                                                                Length of Superelevation Runoff Example

                                                                                                For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                                Lr = 12eα

                                                                                                G

                                                                                                50

                                                                                                Lr = 12eα = (12) (004) (15)

                                                                                                G 05

                                                                                                Lr = 144 feet

                                                                                                Tangent runout length Example continued

                                                                                                Lt = (eNC ed ) x Lr

                                                                                                as defined previously if NC = 2

                                                                                                Tangent runout for the example is

                                                                                                LT = 2 4 144rsquo = 72 feet

                                                                                                52

                                                                                                From previous example speed = 50 mph e = 4

                                                                                                From chart runoff = 144 feet same as from calculation

                                                                                                Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                                Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                                Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                leave a horizontal curve

                                                                                                Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                Spirals Advantages

                                                                                                Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                Provides transition in width when horizontal curve is widened

                                                                                                Aesthetic

                                                                                                Minimum Length of Spiral

                                                                                                Possible Equations

                                                                                                Larger of (1) L = 315 V3

                                                                                                RC

                                                                                                Where

                                                                                                L = minimum length of spiral (ft)

                                                                                                V = speed (mph)

                                                                                                R = curve radius (ft)

                                                                                                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                Minimum Length of Spiral

                                                                                                Or (2) L = (24pminR)12

                                                                                                Where

                                                                                                L = minimum length of spiral (ft)

                                                                                                R = curve radius (ft)

                                                                                                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                Maximum Length of Spiral

                                                                                                L = (24pmaxR)12

                                                                                                Where

                                                                                                L = maximum length of spiral (ft)

                                                                                                R = curve radius (ft)

                                                                                                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                Ls = 147 feet round it to

                                                                                                Ls = 150 feet

                                                                                                Source Iowa DOT Design Manual

                                                                                                SPIRAL TERMINOLOGY

                                                                                                Source Iowa DOT Design Manual

                                                                                                Source Iowa DOT Design Manual

                                                                                                Source Iowa DOT Design Manual

                                                                                                Attainment of Superelevationon spiral curves

                                                                                                See sketches that follow

                                                                                                Normal Crown (DOT ndash pt A)

                                                                                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                65Source Iowa DOT Standard Road Plans RP-2

                                                                                                With Spirals

                                                                                                Same as point E of GB

                                                                                                With Spirals

                                                                                                Tangent runout (A to B)

                                                                                                With Spirals

                                                                                                Removal of crown

                                                                                                With Spirals

                                                                                                Transition of superelevation

                                                                                                Full superelevation

                                                                                                69

                                                                                                • Slide 1
                                                                                                • Geometric Design ndash Basic Principles
                                                                                                • GEOMETRIC DESIGN ndash Course Heads
                                                                                                • Slide 4
                                                                                                • Curves
                                                                                                • Horizontal Curves
                                                                                                • Design Elements
                                                                                                • Slide 8
                                                                                                • Slide 9
                                                                                                • Slide 10
                                                                                                • Slide 11
                                                                                                • Horizontal Curves
                                                                                                • Slide 13
                                                                                                • Slide 14
                                                                                                • Slide 15
                                                                                                • Slide 16
                                                                                                • Slide 17
                                                                                                • Slide 18
                                                                                                • Horizontal Curve Sight Distance
                                                                                                • Slide 20
                                                                                                • Slide 21
                                                                                                • Slide 22
                                                                                                • Slide 23
                                                                                                • Slide 24
                                                                                                • Slide 25
                                                                                                • TRANSITIONS Superelevation Spiral Curves
                                                                                                • Superelevation
                                                                                                • Image
                                                                                                • Superelevation Transitioning
                                                                                                • Slide 30
                                                                                                • Attainment of Superelevation - General
                                                                                                • Tangent Runout Section
                                                                                                • Superelevation Runoff Section
                                                                                                • Slide 34
                                                                                                • Slide 35
                                                                                                • Slide 36
                                                                                                • Slide 37
                                                                                                • Slide 38
                                                                                                • Slide 39
                                                                                                • Slide 40
                                                                                                • Slide 41
                                                                                                • Attainment Location - WHERE
                                                                                                • Minimum Length of Runoff for curve
                                                                                                • Minimum Length of Tangent Runout
                                                                                                • Length of Superelevation Runoff
                                                                                                • Relative Gradient (G)
                                                                                                • Maximum Relative Gradient (G)
                                                                                                • Multilane Adjustment
                                                                                                • Length of Superelevation Runoff Example
                                                                                                • Slide 50
                                                                                                • Tangent runout length Example continued
                                                                                                • Slide 52
                                                                                                • Spiral Curve Transitions
                                                                                                • Slide 54
                                                                                                • Spirals
                                                                                                • Minimum Length of Spiral
                                                                                                • Slide 57
                                                                                                • Maximum Length of Spiral
                                                                                                • Length of Spiral
                                                                                                • Slide 60
                                                                                                • Slide 61
                                                                                                • Slide 62
                                                                                                • Slide 63
                                                                                                • Attainment of Superelevation on spiral curves
                                                                                                • Slide 65
                                                                                                • Slide 66
                                                                                                • Slide 67
                                                                                                • Slide 68
                                                                                                • Slide 69

                                                                                                  Length of Superelevation Runoff Example

                                                                                                  For a 4-lane divided highway with cross-section rotated about centerline design superelevation rate = 4 Design speed is 50 mph What is the minimum length of superelevation runoff (ft)

                                                                                                  Lr = 12eα

                                                                                                  G

                                                                                                  50

                                                                                                  Lr = 12eα = (12) (004) (15)

                                                                                                  G 05

                                                                                                  Lr = 144 feet

                                                                                                  Tangent runout length Example continued

                                                                                                  Lt = (eNC ed ) x Lr

                                                                                                  as defined previously if NC = 2

                                                                                                  Tangent runout for the example is

                                                                                                  LT = 2 4 144rsquo = 72 feet

                                                                                                  52

                                                                                                  From previous example speed = 50 mph e = 4

                                                                                                  From chart runoff = 144 feet same as from calculation

                                                                                                  Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                                  Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                                  Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                  leave a horizontal curve

                                                                                                  Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                  Spirals Advantages

                                                                                                  Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                  Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                  Provides transition in width when horizontal curve is widened

                                                                                                  Aesthetic

                                                                                                  Minimum Length of Spiral

                                                                                                  Possible Equations

                                                                                                  Larger of (1) L = 315 V3

                                                                                                  RC

                                                                                                  Where

                                                                                                  L = minimum length of spiral (ft)

                                                                                                  V = speed (mph)

                                                                                                  R = curve radius (ft)

                                                                                                  C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                  Minimum Length of Spiral

                                                                                                  Or (2) L = (24pminR)12

                                                                                                  Where

                                                                                                  L = minimum length of spiral (ft)

                                                                                                  R = curve radius (ft)

                                                                                                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                  Maximum Length of Spiral

                                                                                                  L = (24pmaxR)12

                                                                                                  Where

                                                                                                  L = maximum length of spiral (ft)

                                                                                                  R = curve radius (ft)

                                                                                                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                  Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                  o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                  Ls = 147 feet round it to

                                                                                                  Ls = 150 feet

                                                                                                  Source Iowa DOT Design Manual

                                                                                                  SPIRAL TERMINOLOGY

                                                                                                  Source Iowa DOT Design Manual

                                                                                                  Source Iowa DOT Design Manual

                                                                                                  Source Iowa DOT Design Manual

                                                                                                  Attainment of Superelevationon spiral curves

                                                                                                  See sketches that follow

                                                                                                  Normal Crown (DOT ndash pt A)

                                                                                                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                  65Source Iowa DOT Standard Road Plans RP-2

                                                                                                  With Spirals

                                                                                                  Same as point E of GB

                                                                                                  With Spirals

                                                                                                  Tangent runout (A to B)

                                                                                                  With Spirals

                                                                                                  Removal of crown

                                                                                                  With Spirals

                                                                                                  Transition of superelevation

                                                                                                  Full superelevation

                                                                                                  69

                                                                                                  • Slide 1
                                                                                                  • Geometric Design ndash Basic Principles
                                                                                                  • GEOMETRIC DESIGN ndash Course Heads
                                                                                                  • Slide 4
                                                                                                  • Curves
                                                                                                  • Horizontal Curves
                                                                                                  • Design Elements
                                                                                                  • Slide 8
                                                                                                  • Slide 9
                                                                                                  • Slide 10
                                                                                                  • Slide 11
                                                                                                  • Horizontal Curves
                                                                                                  • Slide 13
                                                                                                  • Slide 14
                                                                                                  • Slide 15
                                                                                                  • Slide 16
                                                                                                  • Slide 17
                                                                                                  • Slide 18
                                                                                                  • Horizontal Curve Sight Distance
                                                                                                  • Slide 20
                                                                                                  • Slide 21
                                                                                                  • Slide 22
                                                                                                  • Slide 23
                                                                                                  • Slide 24
                                                                                                  • Slide 25
                                                                                                  • TRANSITIONS Superelevation Spiral Curves
                                                                                                  • Superelevation
                                                                                                  • Image
                                                                                                  • Superelevation Transitioning
                                                                                                  • Slide 30
                                                                                                  • Attainment of Superelevation - General
                                                                                                  • Tangent Runout Section
                                                                                                  • Superelevation Runoff Section
                                                                                                  • Slide 34
                                                                                                  • Slide 35
                                                                                                  • Slide 36
                                                                                                  • Slide 37
                                                                                                  • Slide 38
                                                                                                  • Slide 39
                                                                                                  • Slide 40
                                                                                                  • Slide 41
                                                                                                  • Attainment Location - WHERE
                                                                                                  • Minimum Length of Runoff for curve
                                                                                                  • Minimum Length of Tangent Runout
                                                                                                  • Length of Superelevation Runoff
                                                                                                  • Relative Gradient (G)
                                                                                                  • Maximum Relative Gradient (G)
                                                                                                  • Multilane Adjustment
                                                                                                  • Length of Superelevation Runoff Example
                                                                                                  • Slide 50
                                                                                                  • Tangent runout length Example continued
                                                                                                  • Slide 52
                                                                                                  • Spiral Curve Transitions
                                                                                                  • Slide 54
                                                                                                  • Spirals
                                                                                                  • Minimum Length of Spiral
                                                                                                  • Slide 57
                                                                                                  • Maximum Length of Spiral
                                                                                                  • Length of Spiral
                                                                                                  • Slide 60
                                                                                                  • Slide 61
                                                                                                  • Slide 62
                                                                                                  • Slide 63
                                                                                                  • Attainment of Superelevation on spiral curves
                                                                                                  • Slide 65
                                                                                                  • Slide 66
                                                                                                  • Slide 67
                                                                                                  • Slide 68
                                                                                                  • Slide 69

                                                                                                    50

                                                                                                    Lr = 12eα = (12) (004) (15)

                                                                                                    G 05

                                                                                                    Lr = 144 feet

                                                                                                    Tangent runout length Example continued

                                                                                                    Lt = (eNC ed ) x Lr

                                                                                                    as defined previously if NC = 2

                                                                                                    Tangent runout for the example is

                                                                                                    LT = 2 4 144rsquo = 72 feet

                                                                                                    52

                                                                                                    From previous example speed = 50 mph e = 4

                                                                                                    From chart runoff = 144 feet same as from calculation

                                                                                                    Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                                    Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                                    Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                    leave a horizontal curve

                                                                                                    Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                    Spirals Advantages

                                                                                                    Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                    Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                    Provides transition in width when horizontal curve is widened

                                                                                                    Aesthetic

                                                                                                    Minimum Length of Spiral

                                                                                                    Possible Equations

                                                                                                    Larger of (1) L = 315 V3

                                                                                                    RC

                                                                                                    Where

                                                                                                    L = minimum length of spiral (ft)

                                                                                                    V = speed (mph)

                                                                                                    R = curve radius (ft)

                                                                                                    C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                    Minimum Length of Spiral

                                                                                                    Or (2) L = (24pminR)12

                                                                                                    Where

                                                                                                    L = minimum length of spiral (ft)

                                                                                                    R = curve radius (ft)

                                                                                                    pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                    Maximum Length of Spiral

                                                                                                    L = (24pmaxR)12

                                                                                                    Where

                                                                                                    L = maximum length of spiral (ft)

                                                                                                    R = curve radius (ft)

                                                                                                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                    Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                    o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                    Ls = 147 feet round it to

                                                                                                    Ls = 150 feet

                                                                                                    Source Iowa DOT Design Manual

                                                                                                    SPIRAL TERMINOLOGY

                                                                                                    Source Iowa DOT Design Manual

                                                                                                    Source Iowa DOT Design Manual

                                                                                                    Source Iowa DOT Design Manual

                                                                                                    Attainment of Superelevationon spiral curves

                                                                                                    See sketches that follow

                                                                                                    Normal Crown (DOT ndash pt A)

                                                                                                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                    65Source Iowa DOT Standard Road Plans RP-2

                                                                                                    With Spirals

                                                                                                    Same as point E of GB

                                                                                                    With Spirals

                                                                                                    Tangent runout (A to B)

                                                                                                    With Spirals

                                                                                                    Removal of crown

                                                                                                    With Spirals

                                                                                                    Transition of superelevation

                                                                                                    Full superelevation

                                                                                                    69

                                                                                                    • Slide 1
                                                                                                    • Geometric Design ndash Basic Principles
                                                                                                    • GEOMETRIC DESIGN ndash Course Heads
                                                                                                    • Slide 4
                                                                                                    • Curves
                                                                                                    • Horizontal Curves
                                                                                                    • Design Elements
                                                                                                    • Slide 8
                                                                                                    • Slide 9
                                                                                                    • Slide 10
                                                                                                    • Slide 11
                                                                                                    • Horizontal Curves
                                                                                                    • Slide 13
                                                                                                    • Slide 14
                                                                                                    • Slide 15
                                                                                                    • Slide 16
                                                                                                    • Slide 17
                                                                                                    • Slide 18
                                                                                                    • Horizontal Curve Sight Distance
                                                                                                    • Slide 20
                                                                                                    • Slide 21
                                                                                                    • Slide 22
                                                                                                    • Slide 23
                                                                                                    • Slide 24
                                                                                                    • Slide 25
                                                                                                    • TRANSITIONS Superelevation Spiral Curves
                                                                                                    • Superelevation
                                                                                                    • Image
                                                                                                    • Superelevation Transitioning
                                                                                                    • Slide 30
                                                                                                    • Attainment of Superelevation - General
                                                                                                    • Tangent Runout Section
                                                                                                    • Superelevation Runoff Section
                                                                                                    • Slide 34
                                                                                                    • Slide 35
                                                                                                    • Slide 36
                                                                                                    • Slide 37
                                                                                                    • Slide 38
                                                                                                    • Slide 39
                                                                                                    • Slide 40
                                                                                                    • Slide 41
                                                                                                    • Attainment Location - WHERE
                                                                                                    • Minimum Length of Runoff for curve
                                                                                                    • Minimum Length of Tangent Runout
                                                                                                    • Length of Superelevation Runoff
                                                                                                    • Relative Gradient (G)
                                                                                                    • Maximum Relative Gradient (G)
                                                                                                    • Multilane Adjustment
                                                                                                    • Length of Superelevation Runoff Example
                                                                                                    • Slide 50
                                                                                                    • Tangent runout length Example continued
                                                                                                    • Slide 52
                                                                                                    • Spiral Curve Transitions
                                                                                                    • Slide 54
                                                                                                    • Spirals
                                                                                                    • Minimum Length of Spiral
                                                                                                    • Slide 57
                                                                                                    • Maximum Length of Spiral
                                                                                                    • Length of Spiral
                                                                                                    • Slide 60
                                                                                                    • Slide 61
                                                                                                    • Slide 62
                                                                                                    • Slide 63
                                                                                                    • Attainment of Superelevation on spiral curves
                                                                                                    • Slide 65
                                                                                                    • Slide 66
                                                                                                    • Slide 67
                                                                                                    • Slide 68
                                                                                                    • Slide 69

                                                                                                      Tangent runout length Example continued

                                                                                                      Lt = (eNC ed ) x Lr

                                                                                                      as defined previously if NC = 2

                                                                                                      Tangent runout for the example is

                                                                                                      LT = 2 4 144rsquo = 72 feet

                                                                                                      52

                                                                                                      From previous example speed = 50 mph e = 4

                                                                                                      From chart runoff = 144 feet same as from calculation

                                                                                                      Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                                      Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                                      Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                      leave a horizontal curve

                                                                                                      Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                      Spirals Advantages

                                                                                                      Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                      Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                      Provides transition in width when horizontal curve is widened

                                                                                                      Aesthetic

                                                                                                      Minimum Length of Spiral

                                                                                                      Possible Equations

                                                                                                      Larger of (1) L = 315 V3

                                                                                                      RC

                                                                                                      Where

                                                                                                      L = minimum length of spiral (ft)

                                                                                                      V = speed (mph)

                                                                                                      R = curve radius (ft)

                                                                                                      C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                      Minimum Length of Spiral

                                                                                                      Or (2) L = (24pminR)12

                                                                                                      Where

                                                                                                      L = minimum length of spiral (ft)

                                                                                                      R = curve radius (ft)

                                                                                                      pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                      Maximum Length of Spiral

                                                                                                      L = (24pmaxR)12

                                                                                                      Where

                                                                                                      L = maximum length of spiral (ft)

                                                                                                      R = curve radius (ft)

                                                                                                      pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                      Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                      Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                      o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                      Ls = 147 feet round it to

                                                                                                      Ls = 150 feet

                                                                                                      Source Iowa DOT Design Manual

                                                                                                      SPIRAL TERMINOLOGY

                                                                                                      Source Iowa DOT Design Manual

                                                                                                      Source Iowa DOT Design Manual

                                                                                                      Source Iowa DOT Design Manual

                                                                                                      Attainment of Superelevationon spiral curves

                                                                                                      See sketches that follow

                                                                                                      Normal Crown (DOT ndash pt A)

                                                                                                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                      65Source Iowa DOT Standard Road Plans RP-2

                                                                                                      With Spirals

                                                                                                      Same as point E of GB

                                                                                                      With Spirals

                                                                                                      Tangent runout (A to B)

                                                                                                      With Spirals

                                                                                                      Removal of crown

                                                                                                      With Spirals

                                                                                                      Transition of superelevation

                                                                                                      Full superelevation

                                                                                                      69

                                                                                                      • Slide 1
                                                                                                      • Geometric Design ndash Basic Principles
                                                                                                      • GEOMETRIC DESIGN ndash Course Heads
                                                                                                      • Slide 4
                                                                                                      • Curves
                                                                                                      • Horizontal Curves
                                                                                                      • Design Elements
                                                                                                      • Slide 8
                                                                                                      • Slide 9
                                                                                                      • Slide 10
                                                                                                      • Slide 11
                                                                                                      • Horizontal Curves
                                                                                                      • Slide 13
                                                                                                      • Slide 14
                                                                                                      • Slide 15
                                                                                                      • Slide 16
                                                                                                      • Slide 17
                                                                                                      • Slide 18
                                                                                                      • Horizontal Curve Sight Distance
                                                                                                      • Slide 20
                                                                                                      • Slide 21
                                                                                                      • Slide 22
                                                                                                      • Slide 23
                                                                                                      • Slide 24
                                                                                                      • Slide 25
                                                                                                      • TRANSITIONS Superelevation Spiral Curves
                                                                                                      • Superelevation
                                                                                                      • Image
                                                                                                      • Superelevation Transitioning
                                                                                                      • Slide 30
                                                                                                      • Attainment of Superelevation - General
                                                                                                      • Tangent Runout Section
                                                                                                      • Superelevation Runoff Section
                                                                                                      • Slide 34
                                                                                                      • Slide 35
                                                                                                      • Slide 36
                                                                                                      • Slide 37
                                                                                                      • Slide 38
                                                                                                      • Slide 39
                                                                                                      • Slide 40
                                                                                                      • Slide 41
                                                                                                      • Attainment Location - WHERE
                                                                                                      • Minimum Length of Runoff for curve
                                                                                                      • Minimum Length of Tangent Runout
                                                                                                      • Length of Superelevation Runoff
                                                                                                      • Relative Gradient (G)
                                                                                                      • Maximum Relative Gradient (G)
                                                                                                      • Multilane Adjustment
                                                                                                      • Length of Superelevation Runoff Example
                                                                                                      • Slide 50
                                                                                                      • Tangent runout length Example continued
                                                                                                      • Slide 52
                                                                                                      • Spiral Curve Transitions
                                                                                                      • Slide 54
                                                                                                      • Spirals
                                                                                                      • Minimum Length of Spiral
                                                                                                      • Slide 57
                                                                                                      • Maximum Length of Spiral
                                                                                                      • Length of Spiral
                                                                                                      • Slide 60
                                                                                                      • Slide 61
                                                                                                      • Slide 62
                                                                                                      • Slide 63
                                                                                                      • Attainment of Superelevation on spiral curves
                                                                                                      • Slide 65
                                                                                                      • Slide 66
                                                                                                      • Slide 67
                                                                                                      • Slide 68
                                                                                                      • Slide 69

                                                                                                        52

                                                                                                        From previous example speed = 50 mph e = 4

                                                                                                        From chart runoff = 144 feet same as from calculation

                                                                                                        Source A Policy on Geometric Design of Highways and Streets (The Green Book) Washington DC American Association of State Highway and Transportation Officials 2001 4th Ed

                                                                                                        Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                                        Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                        leave a horizontal curve

                                                                                                        Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                        Spirals Advantages

                                                                                                        Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                        Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                        Provides transition in width when horizontal curve is widened

                                                                                                        Aesthetic

                                                                                                        Minimum Length of Spiral

                                                                                                        Possible Equations

                                                                                                        Larger of (1) L = 315 V3

                                                                                                        RC

                                                                                                        Where

                                                                                                        L = minimum length of spiral (ft)

                                                                                                        V = speed (mph)

                                                                                                        R = curve radius (ft)

                                                                                                        C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                        Minimum Length of Spiral

                                                                                                        Or (2) L = (24pminR)12

                                                                                                        Where

                                                                                                        L = minimum length of spiral (ft)

                                                                                                        R = curve radius (ft)

                                                                                                        pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                        Maximum Length of Spiral

                                                                                                        L = (24pmaxR)12

                                                                                                        Where

                                                                                                        L = maximum length of spiral (ft)

                                                                                                        R = curve radius (ft)

                                                                                                        pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                        Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                        Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                        based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                        o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                        o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                        Ls = 147 feet round it to

                                                                                                        Ls = 150 feet

                                                                                                        Source Iowa DOT Design Manual

                                                                                                        SPIRAL TERMINOLOGY

                                                                                                        Source Iowa DOT Design Manual

                                                                                                        Source Iowa DOT Design Manual

                                                                                                        Source Iowa DOT Design Manual

                                                                                                        Attainment of Superelevationon spiral curves

                                                                                                        See sketches that follow

                                                                                                        Normal Crown (DOT ndash pt A)

                                                                                                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                        65Source Iowa DOT Standard Road Plans RP-2

                                                                                                        With Spirals

                                                                                                        Same as point E of GB

                                                                                                        With Spirals

                                                                                                        Tangent runout (A to B)

                                                                                                        With Spirals

                                                                                                        Removal of crown

                                                                                                        With Spirals

                                                                                                        Transition of superelevation

                                                                                                        Full superelevation

                                                                                                        69

                                                                                                        • Slide 1
                                                                                                        • Geometric Design ndash Basic Principles
                                                                                                        • GEOMETRIC DESIGN ndash Course Heads
                                                                                                        • Slide 4
                                                                                                        • Curves
                                                                                                        • Horizontal Curves
                                                                                                        • Design Elements
                                                                                                        • Slide 8
                                                                                                        • Slide 9
                                                                                                        • Slide 10
                                                                                                        • Slide 11
                                                                                                        • Horizontal Curves
                                                                                                        • Slide 13
                                                                                                        • Slide 14
                                                                                                        • Slide 15
                                                                                                        • Slide 16
                                                                                                        • Slide 17
                                                                                                        • Slide 18
                                                                                                        • Horizontal Curve Sight Distance
                                                                                                        • Slide 20
                                                                                                        • Slide 21
                                                                                                        • Slide 22
                                                                                                        • Slide 23
                                                                                                        • Slide 24
                                                                                                        • Slide 25
                                                                                                        • TRANSITIONS Superelevation Spiral Curves
                                                                                                        • Superelevation
                                                                                                        • Image
                                                                                                        • Superelevation Transitioning
                                                                                                        • Slide 30
                                                                                                        • Attainment of Superelevation - General
                                                                                                        • Tangent Runout Section
                                                                                                        • Superelevation Runoff Section
                                                                                                        • Slide 34
                                                                                                        • Slide 35
                                                                                                        • Slide 36
                                                                                                        • Slide 37
                                                                                                        • Slide 38
                                                                                                        • Slide 39
                                                                                                        • Slide 40
                                                                                                        • Slide 41
                                                                                                        • Attainment Location - WHERE
                                                                                                        • Minimum Length of Runoff for curve
                                                                                                        • Minimum Length of Tangent Runout
                                                                                                        • Length of Superelevation Runoff
                                                                                                        • Relative Gradient (G)
                                                                                                        • Maximum Relative Gradient (G)
                                                                                                        • Multilane Adjustment
                                                                                                        • Length of Superelevation Runoff Example
                                                                                                        • Slide 50
                                                                                                        • Tangent runout length Example continued
                                                                                                        • Slide 52
                                                                                                        • Spiral Curve Transitions
                                                                                                        • Slide 54
                                                                                                        • Spirals
                                                                                                        • Minimum Length of Spiral
                                                                                                        • Slide 57
                                                                                                        • Maximum Length of Spiral
                                                                                                        • Length of Spiral
                                                                                                        • Slide 60
                                                                                                        • Slide 61
                                                                                                        • Slide 62
                                                                                                        • Slide 63
                                                                                                        • Attainment of Superelevation on spiral curves
                                                                                                        • Slide 65
                                                                                                        • Slide 66
                                                                                                        • Slide 67
                                                                                                        • Slide 68
                                                                                                        • Slide 69

                                                                                                          Spiral Curve TransitionsSpiral Curve TransitionsSpiral Curve TransitionsSpiral Curve Transitions

                                                                                                          Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                          leave a horizontal curve

                                                                                                          Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                          Spirals Advantages

                                                                                                          Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                          Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                          Provides transition in width when horizontal curve is widened

                                                                                                          Aesthetic

                                                                                                          Minimum Length of Spiral

                                                                                                          Possible Equations

                                                                                                          Larger of (1) L = 315 V3

                                                                                                          RC

                                                                                                          Where

                                                                                                          L = minimum length of spiral (ft)

                                                                                                          V = speed (mph)

                                                                                                          R = curve radius (ft)

                                                                                                          C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                          Minimum Length of Spiral

                                                                                                          Or (2) L = (24pminR)12

                                                                                                          Where

                                                                                                          L = minimum length of spiral (ft)

                                                                                                          R = curve radius (ft)

                                                                                                          pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                          Maximum Length of Spiral

                                                                                                          L = (24pmaxR)12

                                                                                                          Where

                                                                                                          L = maximum length of spiral (ft)

                                                                                                          R = curve radius (ft)

                                                                                                          pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                          Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                          Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                          based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                          o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                          o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                          Ls = 147 feet round it to

                                                                                                          Ls = 150 feet

                                                                                                          Source Iowa DOT Design Manual

                                                                                                          SPIRAL TERMINOLOGY

                                                                                                          Source Iowa DOT Design Manual

                                                                                                          Source Iowa DOT Design Manual

                                                                                                          Source Iowa DOT Design Manual

                                                                                                          Attainment of Superelevationon spiral curves

                                                                                                          See sketches that follow

                                                                                                          Normal Crown (DOT ndash pt A)

                                                                                                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                          65Source Iowa DOT Standard Road Plans RP-2

                                                                                                          With Spirals

                                                                                                          Same as point E of GB

                                                                                                          With Spirals

                                                                                                          Tangent runout (A to B)

                                                                                                          With Spirals

                                                                                                          Removal of crown

                                                                                                          With Spirals

                                                                                                          Transition of superelevation

                                                                                                          Full superelevation

                                                                                                          69

                                                                                                          • Slide 1
                                                                                                          • Geometric Design ndash Basic Principles
                                                                                                          • GEOMETRIC DESIGN ndash Course Heads
                                                                                                          • Slide 4
                                                                                                          • Curves
                                                                                                          • Horizontal Curves
                                                                                                          • Design Elements
                                                                                                          • Slide 8
                                                                                                          • Slide 9
                                                                                                          • Slide 10
                                                                                                          • Slide 11
                                                                                                          • Horizontal Curves
                                                                                                          • Slide 13
                                                                                                          • Slide 14
                                                                                                          • Slide 15
                                                                                                          • Slide 16
                                                                                                          • Slide 17
                                                                                                          • Slide 18
                                                                                                          • Horizontal Curve Sight Distance
                                                                                                          • Slide 20
                                                                                                          • Slide 21
                                                                                                          • Slide 22
                                                                                                          • Slide 23
                                                                                                          • Slide 24
                                                                                                          • Slide 25
                                                                                                          • TRANSITIONS Superelevation Spiral Curves
                                                                                                          • Superelevation
                                                                                                          • Image
                                                                                                          • Superelevation Transitioning
                                                                                                          • Slide 30
                                                                                                          • Attainment of Superelevation - General
                                                                                                          • Tangent Runout Section
                                                                                                          • Superelevation Runoff Section
                                                                                                          • Slide 34
                                                                                                          • Slide 35
                                                                                                          • Slide 36
                                                                                                          • Slide 37
                                                                                                          • Slide 38
                                                                                                          • Slide 39
                                                                                                          • Slide 40
                                                                                                          • Slide 41
                                                                                                          • Attainment Location - WHERE
                                                                                                          • Minimum Length of Runoff for curve
                                                                                                          • Minimum Length of Tangent Runout
                                                                                                          • Length of Superelevation Runoff
                                                                                                          • Relative Gradient (G)
                                                                                                          • Maximum Relative Gradient (G)
                                                                                                          • Multilane Adjustment
                                                                                                          • Length of Superelevation Runoff Example
                                                                                                          • Slide 50
                                                                                                          • Tangent runout length Example continued
                                                                                                          • Slide 52
                                                                                                          • Spiral Curve Transitions
                                                                                                          • Slide 54
                                                                                                          • Spirals
                                                                                                          • Minimum Length of Spiral
                                                                                                          • Slide 57
                                                                                                          • Maximum Length of Spiral
                                                                                                          • Length of Spiral
                                                                                                          • Slide 60
                                                                                                          • Slide 61
                                                                                                          • Slide 62
                                                                                                          • Slide 63
                                                                                                          • Attainment of Superelevation on spiral curves
                                                                                                          • Slide 65
                                                                                                          • Slide 66
                                                                                                          • Slide 67
                                                                                                          • Slide 68
                                                                                                          • Slide 69

                                                                                                            Spiral Curve Transitions Vehicles follow a transition path as they enter or

                                                                                                            leave a horizontal curve

                                                                                                            Combination of high speed and sharp curvature can result in lateral shifts in position and encroachment on adjoining lanes

                                                                                                            Spirals Advantages

                                                                                                            Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                            Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                            Provides transition in width when horizontal curve is widened

                                                                                                            Aesthetic

                                                                                                            Minimum Length of Spiral

                                                                                                            Possible Equations

                                                                                                            Larger of (1) L = 315 V3

                                                                                                            RC

                                                                                                            Where

                                                                                                            L = minimum length of spiral (ft)

                                                                                                            V = speed (mph)

                                                                                                            R = curve radius (ft)

                                                                                                            C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                            Minimum Length of Spiral

                                                                                                            Or (2) L = (24pminR)12

                                                                                                            Where

                                                                                                            L = minimum length of spiral (ft)

                                                                                                            R = curve radius (ft)

                                                                                                            pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                            Maximum Length of Spiral

                                                                                                            L = (24pmaxR)12

                                                                                                            Where

                                                                                                            L = maximum length of spiral (ft)

                                                                                                            R = curve radius (ft)

                                                                                                            pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                            Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                            Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                            based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                            o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                            o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                            Ls = 147 feet round it to

                                                                                                            Ls = 150 feet

                                                                                                            Source Iowa DOT Design Manual

                                                                                                            SPIRAL TERMINOLOGY

                                                                                                            Source Iowa DOT Design Manual

                                                                                                            Source Iowa DOT Design Manual

                                                                                                            Source Iowa DOT Design Manual

                                                                                                            Attainment of Superelevationon spiral curves

                                                                                                            See sketches that follow

                                                                                                            Normal Crown (DOT ndash pt A)

                                                                                                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                            65Source Iowa DOT Standard Road Plans RP-2

                                                                                                            With Spirals

                                                                                                            Same as point E of GB

                                                                                                            With Spirals

                                                                                                            Tangent runout (A to B)

                                                                                                            With Spirals

                                                                                                            Removal of crown

                                                                                                            With Spirals

                                                                                                            Transition of superelevation

                                                                                                            Full superelevation

                                                                                                            69

                                                                                                            • Slide 1
                                                                                                            • Geometric Design ndash Basic Principles
                                                                                                            • GEOMETRIC DESIGN ndash Course Heads
                                                                                                            • Slide 4
                                                                                                            • Curves
                                                                                                            • Horizontal Curves
                                                                                                            • Design Elements
                                                                                                            • Slide 8
                                                                                                            • Slide 9
                                                                                                            • Slide 10
                                                                                                            • Slide 11
                                                                                                            • Horizontal Curves
                                                                                                            • Slide 13
                                                                                                            • Slide 14
                                                                                                            • Slide 15
                                                                                                            • Slide 16
                                                                                                            • Slide 17
                                                                                                            • Slide 18
                                                                                                            • Horizontal Curve Sight Distance
                                                                                                            • Slide 20
                                                                                                            • Slide 21
                                                                                                            • Slide 22
                                                                                                            • Slide 23
                                                                                                            • Slide 24
                                                                                                            • Slide 25
                                                                                                            • TRANSITIONS Superelevation Spiral Curves
                                                                                                            • Superelevation
                                                                                                            • Image
                                                                                                            • Superelevation Transitioning
                                                                                                            • Slide 30
                                                                                                            • Attainment of Superelevation - General
                                                                                                            • Tangent Runout Section
                                                                                                            • Superelevation Runoff Section
                                                                                                            • Slide 34
                                                                                                            • Slide 35
                                                                                                            • Slide 36
                                                                                                            • Slide 37
                                                                                                            • Slide 38
                                                                                                            • Slide 39
                                                                                                            • Slide 40
                                                                                                            • Slide 41
                                                                                                            • Attainment Location - WHERE
                                                                                                            • Minimum Length of Runoff for curve
                                                                                                            • Minimum Length of Tangent Runout
                                                                                                            • Length of Superelevation Runoff
                                                                                                            • Relative Gradient (G)
                                                                                                            • Maximum Relative Gradient (G)
                                                                                                            • Multilane Adjustment
                                                                                                            • Length of Superelevation Runoff Example
                                                                                                            • Slide 50
                                                                                                            • Tangent runout length Example continued
                                                                                                            • Slide 52
                                                                                                            • Spiral Curve Transitions
                                                                                                            • Slide 54
                                                                                                            • Spirals
                                                                                                            • Minimum Length of Spiral
                                                                                                            • Slide 57
                                                                                                            • Maximum Length of Spiral
                                                                                                            • Length of Spiral
                                                                                                            • Slide 60
                                                                                                            • Slide 61
                                                                                                            • Slide 62
                                                                                                            • Slide 63
                                                                                                            • Attainment of Superelevation on spiral curves
                                                                                                            • Slide 65
                                                                                                            • Slide 66
                                                                                                            • Slide 67
                                                                                                            • Slide 68
                                                                                                            • Slide 69

                                                                                                              Spirals Advantages

                                                                                                              Provides natural easy to follow path for drivers (less encroachment promotes more uniform speeds) lateral force increases and decreases gradually

                                                                                                              Provides location for superelevation runoff (not part on tangentcurve)

                                                                                                              Provides transition in width when horizontal curve is widened

                                                                                                              Aesthetic

                                                                                                              Minimum Length of Spiral

                                                                                                              Possible Equations

                                                                                                              Larger of (1) L = 315 V3

                                                                                                              RC

                                                                                                              Where

                                                                                                              L = minimum length of spiral (ft)

                                                                                                              V = speed (mph)

                                                                                                              R = curve radius (ft)

                                                                                                              C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                              Minimum Length of Spiral

                                                                                                              Or (2) L = (24pminR)12

                                                                                                              Where

                                                                                                              L = minimum length of spiral (ft)

                                                                                                              R = curve radius (ft)

                                                                                                              pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                              Maximum Length of Spiral

                                                                                                              L = (24pmaxR)12

                                                                                                              Where

                                                                                                              L = maximum length of spiral (ft)

                                                                                                              R = curve radius (ft)

                                                                                                              pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                              Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                              Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                              based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                              o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                              o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                              Ls = 147 feet round it to

                                                                                                              Ls = 150 feet

                                                                                                              Source Iowa DOT Design Manual

                                                                                                              SPIRAL TERMINOLOGY

                                                                                                              Source Iowa DOT Design Manual

                                                                                                              Source Iowa DOT Design Manual

                                                                                                              Source Iowa DOT Design Manual

                                                                                                              Attainment of Superelevationon spiral curves

                                                                                                              See sketches that follow

                                                                                                              Normal Crown (DOT ndash pt A)

                                                                                                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                              65Source Iowa DOT Standard Road Plans RP-2

                                                                                                              With Spirals

                                                                                                              Same as point E of GB

                                                                                                              With Spirals

                                                                                                              Tangent runout (A to B)

                                                                                                              With Spirals

                                                                                                              Removal of crown

                                                                                                              With Spirals

                                                                                                              Transition of superelevation

                                                                                                              Full superelevation

                                                                                                              69

                                                                                                              • Slide 1
                                                                                                              • Geometric Design ndash Basic Principles
                                                                                                              • GEOMETRIC DESIGN ndash Course Heads
                                                                                                              • Slide 4
                                                                                                              • Curves
                                                                                                              • Horizontal Curves
                                                                                                              • Design Elements
                                                                                                              • Slide 8
                                                                                                              • Slide 9
                                                                                                              • Slide 10
                                                                                                              • Slide 11
                                                                                                              • Horizontal Curves
                                                                                                              • Slide 13
                                                                                                              • Slide 14
                                                                                                              • Slide 15
                                                                                                              • Slide 16
                                                                                                              • Slide 17
                                                                                                              • Slide 18
                                                                                                              • Horizontal Curve Sight Distance
                                                                                                              • Slide 20
                                                                                                              • Slide 21
                                                                                                              • Slide 22
                                                                                                              • Slide 23
                                                                                                              • Slide 24
                                                                                                              • Slide 25
                                                                                                              • TRANSITIONS Superelevation Spiral Curves
                                                                                                              • Superelevation
                                                                                                              • Image
                                                                                                              • Superelevation Transitioning
                                                                                                              • Slide 30
                                                                                                              • Attainment of Superelevation - General
                                                                                                              • Tangent Runout Section
                                                                                                              • Superelevation Runoff Section
                                                                                                              • Slide 34
                                                                                                              • Slide 35
                                                                                                              • Slide 36
                                                                                                              • Slide 37
                                                                                                              • Slide 38
                                                                                                              • Slide 39
                                                                                                              • Slide 40
                                                                                                              • Slide 41
                                                                                                              • Attainment Location - WHERE
                                                                                                              • Minimum Length of Runoff for curve
                                                                                                              • Minimum Length of Tangent Runout
                                                                                                              • Length of Superelevation Runoff
                                                                                                              • Relative Gradient (G)
                                                                                                              • Maximum Relative Gradient (G)
                                                                                                              • Multilane Adjustment
                                                                                                              • Length of Superelevation Runoff Example
                                                                                                              • Slide 50
                                                                                                              • Tangent runout length Example continued
                                                                                                              • Slide 52
                                                                                                              • Spiral Curve Transitions
                                                                                                              • Slide 54
                                                                                                              • Spirals
                                                                                                              • Minimum Length of Spiral
                                                                                                              • Slide 57
                                                                                                              • Maximum Length of Spiral
                                                                                                              • Length of Spiral
                                                                                                              • Slide 60
                                                                                                              • Slide 61
                                                                                                              • Slide 62
                                                                                                              • Slide 63
                                                                                                              • Attainment of Superelevation on spiral curves
                                                                                                              • Slide 65
                                                                                                              • Slide 66
                                                                                                              • Slide 67
                                                                                                              • Slide 68
                                                                                                              • Slide 69

                                                                                                                Minimum Length of Spiral

                                                                                                                Possible Equations

                                                                                                                Larger of (1) L = 315 V3

                                                                                                                RC

                                                                                                                Where

                                                                                                                L = minimum length of spiral (ft)

                                                                                                                V = speed (mph)

                                                                                                                R = curve radius (ft)

                                                                                                                C = rate of increase in centripetal acceleration (fts3) use 1-3 fts3 for highway)

                                                                                                                Minimum Length of Spiral

                                                                                                                Or (2) L = (24pminR)12

                                                                                                                Where

                                                                                                                L = minimum length of spiral (ft)

                                                                                                                R = curve radius (ft)

                                                                                                                pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                                Maximum Length of Spiral

                                                                                                                L = (24pmaxR)12

                                                                                                                Where

                                                                                                                L = maximum length of spiral (ft)

                                                                                                                R = curve radius (ft)

                                                                                                                pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                                Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                                Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                                based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                                o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                                o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                                Ls = 147 feet round it to

                                                                                                                Ls = 150 feet

                                                                                                                Source Iowa DOT Design Manual

                                                                                                                SPIRAL TERMINOLOGY

                                                                                                                Source Iowa DOT Design Manual

                                                                                                                Source Iowa DOT Design Manual

                                                                                                                Source Iowa DOT Design Manual

                                                                                                                Attainment of Superelevationon spiral curves

                                                                                                                See sketches that follow

                                                                                                                Normal Crown (DOT ndash pt A)

                                                                                                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                With Spirals

                                                                                                                Same as point E of GB

                                                                                                                With Spirals

                                                                                                                Tangent runout (A to B)

                                                                                                                With Spirals

                                                                                                                Removal of crown

                                                                                                                With Spirals

                                                                                                                Transition of superelevation

                                                                                                                Full superelevation

                                                                                                                69

                                                                                                                • Slide 1
                                                                                                                • Geometric Design ndash Basic Principles
                                                                                                                • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                • Slide 4
                                                                                                                • Curves
                                                                                                                • Horizontal Curves
                                                                                                                • Design Elements
                                                                                                                • Slide 8
                                                                                                                • Slide 9
                                                                                                                • Slide 10
                                                                                                                • Slide 11
                                                                                                                • Horizontal Curves
                                                                                                                • Slide 13
                                                                                                                • Slide 14
                                                                                                                • Slide 15
                                                                                                                • Slide 16
                                                                                                                • Slide 17
                                                                                                                • Slide 18
                                                                                                                • Horizontal Curve Sight Distance
                                                                                                                • Slide 20
                                                                                                                • Slide 21
                                                                                                                • Slide 22
                                                                                                                • Slide 23
                                                                                                                • Slide 24
                                                                                                                • Slide 25
                                                                                                                • TRANSITIONS Superelevation Spiral Curves
                                                                                                                • Superelevation
                                                                                                                • Image
                                                                                                                • Superelevation Transitioning
                                                                                                                • Slide 30
                                                                                                                • Attainment of Superelevation - General
                                                                                                                • Tangent Runout Section
                                                                                                                • Superelevation Runoff Section
                                                                                                                • Slide 34
                                                                                                                • Slide 35
                                                                                                                • Slide 36
                                                                                                                • Slide 37
                                                                                                                • Slide 38
                                                                                                                • Slide 39
                                                                                                                • Slide 40
                                                                                                                • Slide 41
                                                                                                                • Attainment Location - WHERE
                                                                                                                • Minimum Length of Runoff for curve
                                                                                                                • Minimum Length of Tangent Runout
                                                                                                                • Length of Superelevation Runoff
                                                                                                                • Relative Gradient (G)
                                                                                                                • Maximum Relative Gradient (G)
                                                                                                                • Multilane Adjustment
                                                                                                                • Length of Superelevation Runoff Example
                                                                                                                • Slide 50
                                                                                                                • Tangent runout length Example continued
                                                                                                                • Slide 52
                                                                                                                • Spiral Curve Transitions
                                                                                                                • Slide 54
                                                                                                                • Spirals
                                                                                                                • Minimum Length of Spiral
                                                                                                                • Slide 57
                                                                                                                • Maximum Length of Spiral
                                                                                                                • Length of Spiral
                                                                                                                • Slide 60
                                                                                                                • Slide 61
                                                                                                                • Slide 62
                                                                                                                • Slide 63
                                                                                                                • Attainment of Superelevation on spiral curves
                                                                                                                • Slide 65
                                                                                                                • Slide 66
                                                                                                                • Slide 67
                                                                                                                • Slide 68
                                                                                                                • Slide 69

                                                                                                                  Minimum Length of Spiral

                                                                                                                  Or (2) L = (24pminR)12

                                                                                                                  Where

                                                                                                                  L = minimum length of spiral (ft)

                                                                                                                  R = curve radius (ft)

                                                                                                                  pmin = minimum lateral offset between the tangent and circular curve (066 feet)

                                                                                                                  Maximum Length of Spiral

                                                                                                                  L = (24pmaxR)12

                                                                                                                  Where

                                                                                                                  L = maximum length of spiral (ft)

                                                                                                                  R = curve radius (ft)

                                                                                                                  pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                                  Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                                  Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                                  based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                                  o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                                  o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                                  Ls = 147 feet round it to

                                                                                                                  Ls = 150 feet

                                                                                                                  Source Iowa DOT Design Manual

                                                                                                                  SPIRAL TERMINOLOGY

                                                                                                                  Source Iowa DOT Design Manual

                                                                                                                  Source Iowa DOT Design Manual

                                                                                                                  Source Iowa DOT Design Manual

                                                                                                                  Attainment of Superelevationon spiral curves

                                                                                                                  See sketches that follow

                                                                                                                  Normal Crown (DOT ndash pt A)

                                                                                                                  1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                  2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                  3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                  4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                  65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                  With Spirals

                                                                                                                  Same as point E of GB

                                                                                                                  With Spirals

                                                                                                                  Tangent runout (A to B)

                                                                                                                  With Spirals

                                                                                                                  Removal of crown

                                                                                                                  With Spirals

                                                                                                                  Transition of superelevation

                                                                                                                  Full superelevation

                                                                                                                  69

                                                                                                                  • Slide 1
                                                                                                                  • Geometric Design ndash Basic Principles
                                                                                                                  • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                  • Slide 4
                                                                                                                  • Curves
                                                                                                                  • Horizontal Curves
                                                                                                                  • Design Elements
                                                                                                                  • Slide 8
                                                                                                                  • Slide 9
                                                                                                                  • Slide 10
                                                                                                                  • Slide 11
                                                                                                                  • Horizontal Curves
                                                                                                                  • Slide 13
                                                                                                                  • Slide 14
                                                                                                                  • Slide 15
                                                                                                                  • Slide 16
                                                                                                                  • Slide 17
                                                                                                                  • Slide 18
                                                                                                                  • Horizontal Curve Sight Distance
                                                                                                                  • Slide 20
                                                                                                                  • Slide 21
                                                                                                                  • Slide 22
                                                                                                                  • Slide 23
                                                                                                                  • Slide 24
                                                                                                                  • Slide 25
                                                                                                                  • TRANSITIONS Superelevation Spiral Curves
                                                                                                                  • Superelevation
                                                                                                                  • Image
                                                                                                                  • Superelevation Transitioning
                                                                                                                  • Slide 30
                                                                                                                  • Attainment of Superelevation - General
                                                                                                                  • Tangent Runout Section
                                                                                                                  • Superelevation Runoff Section
                                                                                                                  • Slide 34
                                                                                                                  • Slide 35
                                                                                                                  • Slide 36
                                                                                                                  • Slide 37
                                                                                                                  • Slide 38
                                                                                                                  • Slide 39
                                                                                                                  • Slide 40
                                                                                                                  • Slide 41
                                                                                                                  • Attainment Location - WHERE
                                                                                                                  • Minimum Length of Runoff for curve
                                                                                                                  • Minimum Length of Tangent Runout
                                                                                                                  • Length of Superelevation Runoff
                                                                                                                  • Relative Gradient (G)
                                                                                                                  • Maximum Relative Gradient (G)
                                                                                                                  • Multilane Adjustment
                                                                                                                  • Length of Superelevation Runoff Example
                                                                                                                  • Slide 50
                                                                                                                  • Tangent runout length Example continued
                                                                                                                  • Slide 52
                                                                                                                  • Spiral Curve Transitions
                                                                                                                  • Slide 54
                                                                                                                  • Spirals
                                                                                                                  • Minimum Length of Spiral
                                                                                                                  • Slide 57
                                                                                                                  • Maximum Length of Spiral
                                                                                                                  • Length of Spiral
                                                                                                                  • Slide 60
                                                                                                                  • Slide 61
                                                                                                                  • Slide 62
                                                                                                                  • Slide 63
                                                                                                                  • Attainment of Superelevation on spiral curves
                                                                                                                  • Slide 65
                                                                                                                  • Slide 66
                                                                                                                  • Slide 67
                                                                                                                  • Slide 68
                                                                                                                  • Slide 69

                                                                                                                    Maximum Length of Spiral

                                                                                                                    L = (24pmaxR)12

                                                                                                                    Where

                                                                                                                    L = maximum length of spiral (ft)

                                                                                                                    R = curve radius (ft)

                                                                                                                    pmax = maximum lateral offset between the tangent and circular curve (33 feet)

                                                                                                                    Safety problems may occur when spiral curves are too long ndash drivers underestimate sharpness of approaching curve (driver expectancy)

                                                                                                                    Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                                    based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                                    o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                                    o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                                    Ls = 147 feet round it to

                                                                                                                    Ls = 150 feet

                                                                                                                    Source Iowa DOT Design Manual

                                                                                                                    SPIRAL TERMINOLOGY

                                                                                                                    Source Iowa DOT Design Manual

                                                                                                                    Source Iowa DOT Design Manual

                                                                                                                    Source Iowa DOT Design Manual

                                                                                                                    Attainment of Superelevationon spiral curves

                                                                                                                    See sketches that follow

                                                                                                                    Normal Crown (DOT ndash pt A)

                                                                                                                    1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                    2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                    3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                    4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                    65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                    With Spirals

                                                                                                                    Same as point E of GB

                                                                                                                    With Spirals

                                                                                                                    Tangent runout (A to B)

                                                                                                                    With Spirals

                                                                                                                    Removal of crown

                                                                                                                    With Spirals

                                                                                                                    Transition of superelevation

                                                                                                                    Full superelevation

                                                                                                                    69

                                                                                                                    • Slide 1
                                                                                                                    • Geometric Design ndash Basic Principles
                                                                                                                    • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                    • Slide 4
                                                                                                                    • Curves
                                                                                                                    • Horizontal Curves
                                                                                                                    • Design Elements
                                                                                                                    • Slide 8
                                                                                                                    • Slide 9
                                                                                                                    • Slide 10
                                                                                                                    • Slide 11
                                                                                                                    • Horizontal Curves
                                                                                                                    • Slide 13
                                                                                                                    • Slide 14
                                                                                                                    • Slide 15
                                                                                                                    • Slide 16
                                                                                                                    • Slide 17
                                                                                                                    • Slide 18
                                                                                                                    • Horizontal Curve Sight Distance
                                                                                                                    • Slide 20
                                                                                                                    • Slide 21
                                                                                                                    • Slide 22
                                                                                                                    • Slide 23
                                                                                                                    • Slide 24
                                                                                                                    • Slide 25
                                                                                                                    • TRANSITIONS Superelevation Spiral Curves
                                                                                                                    • Superelevation
                                                                                                                    • Image
                                                                                                                    • Superelevation Transitioning
                                                                                                                    • Slide 30
                                                                                                                    • Attainment of Superelevation - General
                                                                                                                    • Tangent Runout Section
                                                                                                                    • Superelevation Runoff Section
                                                                                                                    • Slide 34
                                                                                                                    • Slide 35
                                                                                                                    • Slide 36
                                                                                                                    • Slide 37
                                                                                                                    • Slide 38
                                                                                                                    • Slide 39
                                                                                                                    • Slide 40
                                                                                                                    • Slide 41
                                                                                                                    • Attainment Location - WHERE
                                                                                                                    • Minimum Length of Runoff for curve
                                                                                                                    • Minimum Length of Tangent Runout
                                                                                                                    • Length of Superelevation Runoff
                                                                                                                    • Relative Gradient (G)
                                                                                                                    • Maximum Relative Gradient (G)
                                                                                                                    • Multilane Adjustment
                                                                                                                    • Length of Superelevation Runoff Example
                                                                                                                    • Slide 50
                                                                                                                    • Tangent runout length Example continued
                                                                                                                    • Slide 52
                                                                                                                    • Spiral Curve Transitions
                                                                                                                    • Slide 54
                                                                                                                    • Spirals
                                                                                                                    • Minimum Length of Spiral
                                                                                                                    • Slide 57
                                                                                                                    • Maximum Length of Spiral
                                                                                                                    • Length of Spiral
                                                                                                                    • Slide 60
                                                                                                                    • Slide 61
                                                                                                                    • Slide 62
                                                                                                                    • Slide 63
                                                                                                                    • Attainment of Superelevation on spiral curves
                                                                                                                    • Slide 65
                                                                                                                    • Slide 66
                                                                                                                    • Slide 67
                                                                                                                    • Slide 68
                                                                                                                    • Slide 69

                                                                                                                      Length of Spiralo AASHTO also provides recommended spiral lengths

                                                                                                                      based on driver behavior rather than a specific equation See Table 1612 of text and the associated tangent runout lengths in Table 1613

                                                                                                                      o Superelevation runoff length is set equal to the spiral curve length when spirals are used

                                                                                                                      o Design Note For construction purposes round your designs to a reasonable values eg

                                                                                                                      Ls = 147 feet round it to

                                                                                                                      Ls = 150 feet

                                                                                                                      Source Iowa DOT Design Manual

                                                                                                                      SPIRAL TERMINOLOGY

                                                                                                                      Source Iowa DOT Design Manual

                                                                                                                      Source Iowa DOT Design Manual

                                                                                                                      Source Iowa DOT Design Manual

                                                                                                                      Attainment of Superelevationon spiral curves

                                                                                                                      See sketches that follow

                                                                                                                      Normal Crown (DOT ndash pt A)

                                                                                                                      1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                      2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                      3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                      4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                      65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                      With Spirals

                                                                                                                      Same as point E of GB

                                                                                                                      With Spirals

                                                                                                                      Tangent runout (A to B)

                                                                                                                      With Spirals

                                                                                                                      Removal of crown

                                                                                                                      With Spirals

                                                                                                                      Transition of superelevation

                                                                                                                      Full superelevation

                                                                                                                      69

                                                                                                                      • Slide 1
                                                                                                                      • Geometric Design ndash Basic Principles
                                                                                                                      • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                      • Slide 4
                                                                                                                      • Curves
                                                                                                                      • Horizontal Curves
                                                                                                                      • Design Elements
                                                                                                                      • Slide 8
                                                                                                                      • Slide 9
                                                                                                                      • Slide 10
                                                                                                                      • Slide 11
                                                                                                                      • Horizontal Curves
                                                                                                                      • Slide 13
                                                                                                                      • Slide 14
                                                                                                                      • Slide 15
                                                                                                                      • Slide 16
                                                                                                                      • Slide 17
                                                                                                                      • Slide 18
                                                                                                                      • Horizontal Curve Sight Distance
                                                                                                                      • Slide 20
                                                                                                                      • Slide 21
                                                                                                                      • Slide 22
                                                                                                                      • Slide 23
                                                                                                                      • Slide 24
                                                                                                                      • Slide 25
                                                                                                                      • TRANSITIONS Superelevation Spiral Curves
                                                                                                                      • Superelevation
                                                                                                                      • Image
                                                                                                                      • Superelevation Transitioning
                                                                                                                      • Slide 30
                                                                                                                      • Attainment of Superelevation - General
                                                                                                                      • Tangent Runout Section
                                                                                                                      • Superelevation Runoff Section
                                                                                                                      • Slide 34
                                                                                                                      • Slide 35
                                                                                                                      • Slide 36
                                                                                                                      • Slide 37
                                                                                                                      • Slide 38
                                                                                                                      • Slide 39
                                                                                                                      • Slide 40
                                                                                                                      • Slide 41
                                                                                                                      • Attainment Location - WHERE
                                                                                                                      • Minimum Length of Runoff for curve
                                                                                                                      • Minimum Length of Tangent Runout
                                                                                                                      • Length of Superelevation Runoff
                                                                                                                      • Relative Gradient (G)
                                                                                                                      • Maximum Relative Gradient (G)
                                                                                                                      • Multilane Adjustment
                                                                                                                      • Length of Superelevation Runoff Example
                                                                                                                      • Slide 50
                                                                                                                      • Tangent runout length Example continued
                                                                                                                      • Slide 52
                                                                                                                      • Spiral Curve Transitions
                                                                                                                      • Slide 54
                                                                                                                      • Spirals
                                                                                                                      • Minimum Length of Spiral
                                                                                                                      • Slide 57
                                                                                                                      • Maximum Length of Spiral
                                                                                                                      • Length of Spiral
                                                                                                                      • Slide 60
                                                                                                                      • Slide 61
                                                                                                                      • Slide 62
                                                                                                                      • Slide 63
                                                                                                                      • Attainment of Superelevation on spiral curves
                                                                                                                      • Slide 65
                                                                                                                      • Slide 66
                                                                                                                      • Slide 67
                                                                                                                      • Slide 68
                                                                                                                      • Slide 69

                                                                                                                        Source Iowa DOT Design Manual

                                                                                                                        SPIRAL TERMINOLOGY

                                                                                                                        Source Iowa DOT Design Manual

                                                                                                                        Source Iowa DOT Design Manual

                                                                                                                        Source Iowa DOT Design Manual

                                                                                                                        Attainment of Superelevationon spiral curves

                                                                                                                        See sketches that follow

                                                                                                                        Normal Crown (DOT ndash pt A)

                                                                                                                        1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                        2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                        3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                        4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                        65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                        With Spirals

                                                                                                                        Same as point E of GB

                                                                                                                        With Spirals

                                                                                                                        Tangent runout (A to B)

                                                                                                                        With Spirals

                                                                                                                        Removal of crown

                                                                                                                        With Spirals

                                                                                                                        Transition of superelevation

                                                                                                                        Full superelevation

                                                                                                                        69

                                                                                                                        • Slide 1
                                                                                                                        • Geometric Design ndash Basic Principles
                                                                                                                        • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                        • Slide 4
                                                                                                                        • Curves
                                                                                                                        • Horizontal Curves
                                                                                                                        • Design Elements
                                                                                                                        • Slide 8
                                                                                                                        • Slide 9
                                                                                                                        • Slide 10
                                                                                                                        • Slide 11
                                                                                                                        • Horizontal Curves
                                                                                                                        • Slide 13
                                                                                                                        • Slide 14
                                                                                                                        • Slide 15
                                                                                                                        • Slide 16
                                                                                                                        • Slide 17
                                                                                                                        • Slide 18
                                                                                                                        • Horizontal Curve Sight Distance
                                                                                                                        • Slide 20
                                                                                                                        • Slide 21
                                                                                                                        • Slide 22
                                                                                                                        • Slide 23
                                                                                                                        • Slide 24
                                                                                                                        • Slide 25
                                                                                                                        • TRANSITIONS Superelevation Spiral Curves
                                                                                                                        • Superelevation
                                                                                                                        • Image
                                                                                                                        • Superelevation Transitioning
                                                                                                                        • Slide 30
                                                                                                                        • Attainment of Superelevation - General
                                                                                                                        • Tangent Runout Section
                                                                                                                        • Superelevation Runoff Section
                                                                                                                        • Slide 34
                                                                                                                        • Slide 35
                                                                                                                        • Slide 36
                                                                                                                        • Slide 37
                                                                                                                        • Slide 38
                                                                                                                        • Slide 39
                                                                                                                        • Slide 40
                                                                                                                        • Slide 41
                                                                                                                        • Attainment Location - WHERE
                                                                                                                        • Minimum Length of Runoff for curve
                                                                                                                        • Minimum Length of Tangent Runout
                                                                                                                        • Length of Superelevation Runoff
                                                                                                                        • Relative Gradient (G)
                                                                                                                        • Maximum Relative Gradient (G)
                                                                                                                        • Multilane Adjustment
                                                                                                                        • Length of Superelevation Runoff Example
                                                                                                                        • Slide 50
                                                                                                                        • Tangent runout length Example continued
                                                                                                                        • Slide 52
                                                                                                                        • Spiral Curve Transitions
                                                                                                                        • Slide 54
                                                                                                                        • Spirals
                                                                                                                        • Minimum Length of Spiral
                                                                                                                        • Slide 57
                                                                                                                        • Maximum Length of Spiral
                                                                                                                        • Length of Spiral
                                                                                                                        • Slide 60
                                                                                                                        • Slide 61
                                                                                                                        • Slide 62
                                                                                                                        • Slide 63
                                                                                                                        • Attainment of Superelevation on spiral curves
                                                                                                                        • Slide 65
                                                                                                                        • Slide 66
                                                                                                                        • Slide 67
                                                                                                                        • Slide 68
                                                                                                                        • Slide 69

                                                                                                                          Source Iowa DOT Design Manual

                                                                                                                          Source Iowa DOT Design Manual

                                                                                                                          Source Iowa DOT Design Manual

                                                                                                                          Attainment of Superelevationon spiral curves

                                                                                                                          See sketches that follow

                                                                                                                          Normal Crown (DOT ndash pt A)

                                                                                                                          1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                          2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                          3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                          4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                          65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                          With Spirals

                                                                                                                          Same as point E of GB

                                                                                                                          With Spirals

                                                                                                                          Tangent runout (A to B)

                                                                                                                          With Spirals

                                                                                                                          Removal of crown

                                                                                                                          With Spirals

                                                                                                                          Transition of superelevation

                                                                                                                          Full superelevation

                                                                                                                          69

                                                                                                                          • Slide 1
                                                                                                                          • Geometric Design ndash Basic Principles
                                                                                                                          • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                          • Slide 4
                                                                                                                          • Curves
                                                                                                                          • Horizontal Curves
                                                                                                                          • Design Elements
                                                                                                                          • Slide 8
                                                                                                                          • Slide 9
                                                                                                                          • Slide 10
                                                                                                                          • Slide 11
                                                                                                                          • Horizontal Curves
                                                                                                                          • Slide 13
                                                                                                                          • Slide 14
                                                                                                                          • Slide 15
                                                                                                                          • Slide 16
                                                                                                                          • Slide 17
                                                                                                                          • Slide 18
                                                                                                                          • Horizontal Curve Sight Distance
                                                                                                                          • Slide 20
                                                                                                                          • Slide 21
                                                                                                                          • Slide 22
                                                                                                                          • Slide 23
                                                                                                                          • Slide 24
                                                                                                                          • Slide 25
                                                                                                                          • TRANSITIONS Superelevation Spiral Curves
                                                                                                                          • Superelevation
                                                                                                                          • Image
                                                                                                                          • Superelevation Transitioning
                                                                                                                          • Slide 30
                                                                                                                          • Attainment of Superelevation - General
                                                                                                                          • Tangent Runout Section
                                                                                                                          • Superelevation Runoff Section
                                                                                                                          • Slide 34
                                                                                                                          • Slide 35
                                                                                                                          • Slide 36
                                                                                                                          • Slide 37
                                                                                                                          • Slide 38
                                                                                                                          • Slide 39
                                                                                                                          • Slide 40
                                                                                                                          • Slide 41
                                                                                                                          • Attainment Location - WHERE
                                                                                                                          • Minimum Length of Runoff for curve
                                                                                                                          • Minimum Length of Tangent Runout
                                                                                                                          • Length of Superelevation Runoff
                                                                                                                          • Relative Gradient (G)
                                                                                                                          • Maximum Relative Gradient (G)
                                                                                                                          • Multilane Adjustment
                                                                                                                          • Length of Superelevation Runoff Example
                                                                                                                          • Slide 50
                                                                                                                          • Tangent runout length Example continued
                                                                                                                          • Slide 52
                                                                                                                          • Spiral Curve Transitions
                                                                                                                          • Slide 54
                                                                                                                          • Spirals
                                                                                                                          • Minimum Length of Spiral
                                                                                                                          • Slide 57
                                                                                                                          • Maximum Length of Spiral
                                                                                                                          • Length of Spiral
                                                                                                                          • Slide 60
                                                                                                                          • Slide 61
                                                                                                                          • Slide 62
                                                                                                                          • Slide 63
                                                                                                                          • Attainment of Superelevation on spiral curves
                                                                                                                          • Slide 65
                                                                                                                          • Slide 66
                                                                                                                          • Slide 67
                                                                                                                          • Slide 68
                                                                                                                          • Slide 69

                                                                                                                            Source Iowa DOT Design Manual

                                                                                                                            Source Iowa DOT Design Manual

                                                                                                                            Attainment of Superelevationon spiral curves

                                                                                                                            See sketches that follow

                                                                                                                            Normal Crown (DOT ndash pt A)

                                                                                                                            1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                            2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                            3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                            4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                            65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                            With Spirals

                                                                                                                            Same as point E of GB

                                                                                                                            With Spirals

                                                                                                                            Tangent runout (A to B)

                                                                                                                            With Spirals

                                                                                                                            Removal of crown

                                                                                                                            With Spirals

                                                                                                                            Transition of superelevation

                                                                                                                            Full superelevation

                                                                                                                            69

                                                                                                                            • Slide 1
                                                                                                                            • Geometric Design ndash Basic Principles
                                                                                                                            • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                            • Slide 4
                                                                                                                            • Curves
                                                                                                                            • Horizontal Curves
                                                                                                                            • Design Elements
                                                                                                                            • Slide 8
                                                                                                                            • Slide 9
                                                                                                                            • Slide 10
                                                                                                                            • Slide 11
                                                                                                                            • Horizontal Curves
                                                                                                                            • Slide 13
                                                                                                                            • Slide 14
                                                                                                                            • Slide 15
                                                                                                                            • Slide 16
                                                                                                                            • Slide 17
                                                                                                                            • Slide 18
                                                                                                                            • Horizontal Curve Sight Distance
                                                                                                                            • Slide 20
                                                                                                                            • Slide 21
                                                                                                                            • Slide 22
                                                                                                                            • Slide 23
                                                                                                                            • Slide 24
                                                                                                                            • Slide 25
                                                                                                                            • TRANSITIONS Superelevation Spiral Curves
                                                                                                                            • Superelevation
                                                                                                                            • Image
                                                                                                                            • Superelevation Transitioning
                                                                                                                            • Slide 30
                                                                                                                            • Attainment of Superelevation - General
                                                                                                                            • Tangent Runout Section
                                                                                                                            • Superelevation Runoff Section
                                                                                                                            • Slide 34
                                                                                                                            • Slide 35
                                                                                                                            • Slide 36
                                                                                                                            • Slide 37
                                                                                                                            • Slide 38
                                                                                                                            • Slide 39
                                                                                                                            • Slide 40
                                                                                                                            • Slide 41
                                                                                                                            • Attainment Location - WHERE
                                                                                                                            • Minimum Length of Runoff for curve
                                                                                                                            • Minimum Length of Tangent Runout
                                                                                                                            • Length of Superelevation Runoff
                                                                                                                            • Relative Gradient (G)
                                                                                                                            • Maximum Relative Gradient (G)
                                                                                                                            • Multilane Adjustment
                                                                                                                            • Length of Superelevation Runoff Example
                                                                                                                            • Slide 50
                                                                                                                            • Tangent runout length Example continued
                                                                                                                            • Slide 52
                                                                                                                            • Spiral Curve Transitions
                                                                                                                            • Slide 54
                                                                                                                            • Spirals
                                                                                                                            • Minimum Length of Spiral
                                                                                                                            • Slide 57
                                                                                                                            • Maximum Length of Spiral
                                                                                                                            • Length of Spiral
                                                                                                                            • Slide 60
                                                                                                                            • Slide 61
                                                                                                                            • Slide 62
                                                                                                                            • Slide 63
                                                                                                                            • Attainment of Superelevation on spiral curves
                                                                                                                            • Slide 65
                                                                                                                            • Slide 66
                                                                                                                            • Slide 67
                                                                                                                            • Slide 68
                                                                                                                            • Slide 69

                                                                                                                              Source Iowa DOT Design Manual

                                                                                                                              Attainment of Superelevationon spiral curves

                                                                                                                              See sketches that follow

                                                                                                                              Normal Crown (DOT ndash pt A)

                                                                                                                              1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                              2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                              3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                              4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                              65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                              With Spirals

                                                                                                                              Same as point E of GB

                                                                                                                              With Spirals

                                                                                                                              Tangent runout (A to B)

                                                                                                                              With Spirals

                                                                                                                              Removal of crown

                                                                                                                              With Spirals

                                                                                                                              Transition of superelevation

                                                                                                                              Full superelevation

                                                                                                                              69

                                                                                                                              • Slide 1
                                                                                                                              • Geometric Design ndash Basic Principles
                                                                                                                              • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                              • Slide 4
                                                                                                                              • Curves
                                                                                                                              • Horizontal Curves
                                                                                                                              • Design Elements
                                                                                                                              • Slide 8
                                                                                                                              • Slide 9
                                                                                                                              • Slide 10
                                                                                                                              • Slide 11
                                                                                                                              • Horizontal Curves
                                                                                                                              • Slide 13
                                                                                                                              • Slide 14
                                                                                                                              • Slide 15
                                                                                                                              • Slide 16
                                                                                                                              • Slide 17
                                                                                                                              • Slide 18
                                                                                                                              • Horizontal Curve Sight Distance
                                                                                                                              • Slide 20
                                                                                                                              • Slide 21
                                                                                                                              • Slide 22
                                                                                                                              • Slide 23
                                                                                                                              • Slide 24
                                                                                                                              • Slide 25
                                                                                                                              • TRANSITIONS Superelevation Spiral Curves
                                                                                                                              • Superelevation
                                                                                                                              • Image
                                                                                                                              • Superelevation Transitioning
                                                                                                                              • Slide 30
                                                                                                                              • Attainment of Superelevation - General
                                                                                                                              • Tangent Runout Section
                                                                                                                              • Superelevation Runoff Section
                                                                                                                              • Slide 34
                                                                                                                              • Slide 35
                                                                                                                              • Slide 36
                                                                                                                              • Slide 37
                                                                                                                              • Slide 38
                                                                                                                              • Slide 39
                                                                                                                              • Slide 40
                                                                                                                              • Slide 41
                                                                                                                              • Attainment Location - WHERE
                                                                                                                              • Minimum Length of Runoff for curve
                                                                                                                              • Minimum Length of Tangent Runout
                                                                                                                              • Length of Superelevation Runoff
                                                                                                                              • Relative Gradient (G)
                                                                                                                              • Maximum Relative Gradient (G)
                                                                                                                              • Multilane Adjustment
                                                                                                                              • Length of Superelevation Runoff Example
                                                                                                                              • Slide 50
                                                                                                                              • Tangent runout length Example continued
                                                                                                                              • Slide 52
                                                                                                                              • Spiral Curve Transitions
                                                                                                                              • Slide 54
                                                                                                                              • Spirals
                                                                                                                              • Minimum Length of Spiral
                                                                                                                              • Slide 57
                                                                                                                              • Maximum Length of Spiral
                                                                                                                              • Length of Spiral
                                                                                                                              • Slide 60
                                                                                                                              • Slide 61
                                                                                                                              • Slide 62
                                                                                                                              • Slide 63
                                                                                                                              • Attainment of Superelevation on spiral curves
                                                                                                                              • Slide 65
                                                                                                                              • Slide 66
                                                                                                                              • Slide 67
                                                                                                                              • Slide 68
                                                                                                                              • Slide 69

                                                                                                                                Attainment of Superelevationon spiral curves

                                                                                                                                See sketches that follow

                                                                                                                                Normal Crown (DOT ndash pt A)

                                                                                                                                1 Tangent Runout (sometimes known as crown runoff) removal of adverse crown (DOT ndash A to B) B = TS

                                                                                                                                2 Point of reversal of crown (DOT ndash C) note A to B = B to C

                                                                                                                                3 Length of Runoff length from adverse crown removed to full superelevated (DOT ndash B to D) D = SC

                                                                                                                                4 Fully superelevate remainder of curve and then reverse the process at the CS

                                                                                                                                65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                                With Spirals

                                                                                                                                Same as point E of GB

                                                                                                                                With Spirals

                                                                                                                                Tangent runout (A to B)

                                                                                                                                With Spirals

                                                                                                                                Removal of crown

                                                                                                                                With Spirals

                                                                                                                                Transition of superelevation

                                                                                                                                Full superelevation

                                                                                                                                69

                                                                                                                                • Slide 1
                                                                                                                                • Geometric Design ndash Basic Principles
                                                                                                                                • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                                • Slide 4
                                                                                                                                • Curves
                                                                                                                                • Horizontal Curves
                                                                                                                                • Design Elements
                                                                                                                                • Slide 8
                                                                                                                                • Slide 9
                                                                                                                                • Slide 10
                                                                                                                                • Slide 11
                                                                                                                                • Horizontal Curves
                                                                                                                                • Slide 13
                                                                                                                                • Slide 14
                                                                                                                                • Slide 15
                                                                                                                                • Slide 16
                                                                                                                                • Slide 17
                                                                                                                                • Slide 18
                                                                                                                                • Horizontal Curve Sight Distance
                                                                                                                                • Slide 20
                                                                                                                                • Slide 21
                                                                                                                                • Slide 22
                                                                                                                                • Slide 23
                                                                                                                                • Slide 24
                                                                                                                                • Slide 25
                                                                                                                                • TRANSITIONS Superelevation Spiral Curves
                                                                                                                                • Superelevation
                                                                                                                                • Image
                                                                                                                                • Superelevation Transitioning
                                                                                                                                • Slide 30
                                                                                                                                • Attainment of Superelevation - General
                                                                                                                                • Tangent Runout Section
                                                                                                                                • Superelevation Runoff Section
                                                                                                                                • Slide 34
                                                                                                                                • Slide 35
                                                                                                                                • Slide 36
                                                                                                                                • Slide 37
                                                                                                                                • Slide 38
                                                                                                                                • Slide 39
                                                                                                                                • Slide 40
                                                                                                                                • Slide 41
                                                                                                                                • Attainment Location - WHERE
                                                                                                                                • Minimum Length of Runoff for curve
                                                                                                                                • Minimum Length of Tangent Runout
                                                                                                                                • Length of Superelevation Runoff
                                                                                                                                • Relative Gradient (G)
                                                                                                                                • Maximum Relative Gradient (G)
                                                                                                                                • Multilane Adjustment
                                                                                                                                • Length of Superelevation Runoff Example
                                                                                                                                • Slide 50
                                                                                                                                • Tangent runout length Example continued
                                                                                                                                • Slide 52
                                                                                                                                • Spiral Curve Transitions
                                                                                                                                • Slide 54
                                                                                                                                • Spirals
                                                                                                                                • Minimum Length of Spiral
                                                                                                                                • Slide 57
                                                                                                                                • Maximum Length of Spiral
                                                                                                                                • Length of Spiral
                                                                                                                                • Slide 60
                                                                                                                                • Slide 61
                                                                                                                                • Slide 62
                                                                                                                                • Slide 63
                                                                                                                                • Attainment of Superelevation on spiral curves
                                                                                                                                • Slide 65
                                                                                                                                • Slide 66
                                                                                                                                • Slide 67
                                                                                                                                • Slide 68
                                                                                                                                • Slide 69

                                                                                                                                  65Source Iowa DOT Standard Road Plans RP-2

                                                                                                                                  With Spirals

                                                                                                                                  Same as point E of GB

                                                                                                                                  With Spirals

                                                                                                                                  Tangent runout (A to B)

                                                                                                                                  With Spirals

                                                                                                                                  Removal of crown

                                                                                                                                  With Spirals

                                                                                                                                  Transition of superelevation

                                                                                                                                  Full superelevation

                                                                                                                                  69

                                                                                                                                  • Slide 1
                                                                                                                                  • Geometric Design ndash Basic Principles
                                                                                                                                  • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                                  • Slide 4
                                                                                                                                  • Curves
                                                                                                                                  • Horizontal Curves
                                                                                                                                  • Design Elements
                                                                                                                                  • Slide 8
                                                                                                                                  • Slide 9
                                                                                                                                  • Slide 10
                                                                                                                                  • Slide 11
                                                                                                                                  • Horizontal Curves
                                                                                                                                  • Slide 13
                                                                                                                                  • Slide 14
                                                                                                                                  • Slide 15
                                                                                                                                  • Slide 16
                                                                                                                                  • Slide 17
                                                                                                                                  • Slide 18
                                                                                                                                  • Horizontal Curve Sight Distance
                                                                                                                                  • Slide 20
                                                                                                                                  • Slide 21
                                                                                                                                  • Slide 22
                                                                                                                                  • Slide 23
                                                                                                                                  • Slide 24
                                                                                                                                  • Slide 25
                                                                                                                                  • TRANSITIONS Superelevation Spiral Curves
                                                                                                                                  • Superelevation
                                                                                                                                  • Image
                                                                                                                                  • Superelevation Transitioning
                                                                                                                                  • Slide 30
                                                                                                                                  • Attainment of Superelevation - General
                                                                                                                                  • Tangent Runout Section
                                                                                                                                  • Superelevation Runoff Section
                                                                                                                                  • Slide 34
                                                                                                                                  • Slide 35
                                                                                                                                  • Slide 36
                                                                                                                                  • Slide 37
                                                                                                                                  • Slide 38
                                                                                                                                  • Slide 39
                                                                                                                                  • Slide 40
                                                                                                                                  • Slide 41
                                                                                                                                  • Attainment Location - WHERE
                                                                                                                                  • Minimum Length of Runoff for curve
                                                                                                                                  • Minimum Length of Tangent Runout
                                                                                                                                  • Length of Superelevation Runoff
                                                                                                                                  • Relative Gradient (G)
                                                                                                                                  • Maximum Relative Gradient (G)
                                                                                                                                  • Multilane Adjustment
                                                                                                                                  • Length of Superelevation Runoff Example
                                                                                                                                  • Slide 50
                                                                                                                                  • Tangent runout length Example continued
                                                                                                                                  • Slide 52
                                                                                                                                  • Spiral Curve Transitions
                                                                                                                                  • Slide 54
                                                                                                                                  • Spirals
                                                                                                                                  • Minimum Length of Spiral
                                                                                                                                  • Slide 57
                                                                                                                                  • Maximum Length of Spiral
                                                                                                                                  • Length of Spiral
                                                                                                                                  • Slide 60
                                                                                                                                  • Slide 61
                                                                                                                                  • Slide 62
                                                                                                                                  • Slide 63
                                                                                                                                  • Attainment of Superelevation on spiral curves
                                                                                                                                  • Slide 65
                                                                                                                                  • Slide 66
                                                                                                                                  • Slide 67
                                                                                                                                  • Slide 68
                                                                                                                                  • Slide 69

                                                                                                                                    With Spirals

                                                                                                                                    Tangent runout (A to B)

                                                                                                                                    With Spirals

                                                                                                                                    Removal of crown

                                                                                                                                    With Spirals

                                                                                                                                    Transition of superelevation

                                                                                                                                    Full superelevation

                                                                                                                                    69

                                                                                                                                    • Slide 1
                                                                                                                                    • Geometric Design ndash Basic Principles
                                                                                                                                    • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                                    • Slide 4
                                                                                                                                    • Curves
                                                                                                                                    • Horizontal Curves
                                                                                                                                    • Design Elements
                                                                                                                                    • Slide 8
                                                                                                                                    • Slide 9
                                                                                                                                    • Slide 10
                                                                                                                                    • Slide 11
                                                                                                                                    • Horizontal Curves
                                                                                                                                    • Slide 13
                                                                                                                                    • Slide 14
                                                                                                                                    • Slide 15
                                                                                                                                    • Slide 16
                                                                                                                                    • Slide 17
                                                                                                                                    • Slide 18
                                                                                                                                    • Horizontal Curve Sight Distance
                                                                                                                                    • Slide 20
                                                                                                                                    • Slide 21
                                                                                                                                    • Slide 22
                                                                                                                                    • Slide 23
                                                                                                                                    • Slide 24
                                                                                                                                    • Slide 25
                                                                                                                                    • TRANSITIONS Superelevation Spiral Curves
                                                                                                                                    • Superelevation
                                                                                                                                    • Image
                                                                                                                                    • Superelevation Transitioning
                                                                                                                                    • Slide 30
                                                                                                                                    • Attainment of Superelevation - General
                                                                                                                                    • Tangent Runout Section
                                                                                                                                    • Superelevation Runoff Section
                                                                                                                                    • Slide 34
                                                                                                                                    • Slide 35
                                                                                                                                    • Slide 36
                                                                                                                                    • Slide 37
                                                                                                                                    • Slide 38
                                                                                                                                    • Slide 39
                                                                                                                                    • Slide 40
                                                                                                                                    • Slide 41
                                                                                                                                    • Attainment Location - WHERE
                                                                                                                                    • Minimum Length of Runoff for curve
                                                                                                                                    • Minimum Length of Tangent Runout
                                                                                                                                    • Length of Superelevation Runoff
                                                                                                                                    • Relative Gradient (G)
                                                                                                                                    • Maximum Relative Gradient (G)
                                                                                                                                    • Multilane Adjustment
                                                                                                                                    • Length of Superelevation Runoff Example
                                                                                                                                    • Slide 50
                                                                                                                                    • Tangent runout length Example continued
                                                                                                                                    • Slide 52
                                                                                                                                    • Spiral Curve Transitions
                                                                                                                                    • Slide 54
                                                                                                                                    • Spirals
                                                                                                                                    • Minimum Length of Spiral
                                                                                                                                    • Slide 57
                                                                                                                                    • Maximum Length of Spiral
                                                                                                                                    • Length of Spiral
                                                                                                                                    • Slide 60
                                                                                                                                    • Slide 61
                                                                                                                                    • Slide 62
                                                                                                                                    • Slide 63
                                                                                                                                    • Attainment of Superelevation on spiral curves
                                                                                                                                    • Slide 65
                                                                                                                                    • Slide 66
                                                                                                                                    • Slide 67
                                                                                                                                    • Slide 68
                                                                                                                                    • Slide 69

                                                                                                                                      With Spirals

                                                                                                                                      Removal of crown

                                                                                                                                      With Spirals

                                                                                                                                      Transition of superelevation

                                                                                                                                      Full superelevation

                                                                                                                                      69

                                                                                                                                      • Slide 1
                                                                                                                                      • Geometric Design ndash Basic Principles
                                                                                                                                      • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                                      • Slide 4
                                                                                                                                      • Curves
                                                                                                                                      • Horizontal Curves
                                                                                                                                      • Design Elements
                                                                                                                                      • Slide 8
                                                                                                                                      • Slide 9
                                                                                                                                      • Slide 10
                                                                                                                                      • Slide 11
                                                                                                                                      • Horizontal Curves
                                                                                                                                      • Slide 13
                                                                                                                                      • Slide 14
                                                                                                                                      • Slide 15
                                                                                                                                      • Slide 16
                                                                                                                                      • Slide 17
                                                                                                                                      • Slide 18
                                                                                                                                      • Horizontal Curve Sight Distance
                                                                                                                                      • Slide 20
                                                                                                                                      • Slide 21
                                                                                                                                      • Slide 22
                                                                                                                                      • Slide 23
                                                                                                                                      • Slide 24
                                                                                                                                      • Slide 25
                                                                                                                                      • TRANSITIONS Superelevation Spiral Curves
                                                                                                                                      • Superelevation
                                                                                                                                      • Image
                                                                                                                                      • Superelevation Transitioning
                                                                                                                                      • Slide 30
                                                                                                                                      • Attainment of Superelevation - General
                                                                                                                                      • Tangent Runout Section
                                                                                                                                      • Superelevation Runoff Section
                                                                                                                                      • Slide 34
                                                                                                                                      • Slide 35
                                                                                                                                      • Slide 36
                                                                                                                                      • Slide 37
                                                                                                                                      • Slide 38
                                                                                                                                      • Slide 39
                                                                                                                                      • Slide 40
                                                                                                                                      • Slide 41
                                                                                                                                      • Attainment Location - WHERE
                                                                                                                                      • Minimum Length of Runoff for curve
                                                                                                                                      • Minimum Length of Tangent Runout
                                                                                                                                      • Length of Superelevation Runoff
                                                                                                                                      • Relative Gradient (G)
                                                                                                                                      • Maximum Relative Gradient (G)
                                                                                                                                      • Multilane Adjustment
                                                                                                                                      • Length of Superelevation Runoff Example
                                                                                                                                      • Slide 50
                                                                                                                                      • Tangent runout length Example continued
                                                                                                                                      • Slide 52
                                                                                                                                      • Spiral Curve Transitions
                                                                                                                                      • Slide 54
                                                                                                                                      • Spirals
                                                                                                                                      • Minimum Length of Spiral
                                                                                                                                      • Slide 57
                                                                                                                                      • Maximum Length of Spiral
                                                                                                                                      • Length of Spiral
                                                                                                                                      • Slide 60
                                                                                                                                      • Slide 61
                                                                                                                                      • Slide 62
                                                                                                                                      • Slide 63
                                                                                                                                      • Attainment of Superelevation on spiral curves
                                                                                                                                      • Slide 65
                                                                                                                                      • Slide 66
                                                                                                                                      • Slide 67
                                                                                                                                      • Slide 68
                                                                                                                                      • Slide 69

                                                                                                                                        With Spirals

                                                                                                                                        Transition of superelevation

                                                                                                                                        Full superelevation

                                                                                                                                        69

                                                                                                                                        • Slide 1
                                                                                                                                        • Geometric Design ndash Basic Principles
                                                                                                                                        • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                                        • Slide 4
                                                                                                                                        • Curves
                                                                                                                                        • Horizontal Curves
                                                                                                                                        • Design Elements
                                                                                                                                        • Slide 8
                                                                                                                                        • Slide 9
                                                                                                                                        • Slide 10
                                                                                                                                        • Slide 11
                                                                                                                                        • Horizontal Curves
                                                                                                                                        • Slide 13
                                                                                                                                        • Slide 14
                                                                                                                                        • Slide 15
                                                                                                                                        • Slide 16
                                                                                                                                        • Slide 17
                                                                                                                                        • Slide 18
                                                                                                                                        • Horizontal Curve Sight Distance
                                                                                                                                        • Slide 20
                                                                                                                                        • Slide 21
                                                                                                                                        • Slide 22
                                                                                                                                        • Slide 23
                                                                                                                                        • Slide 24
                                                                                                                                        • Slide 25
                                                                                                                                        • TRANSITIONS Superelevation Spiral Curves
                                                                                                                                        • Superelevation
                                                                                                                                        • Image
                                                                                                                                        • Superelevation Transitioning
                                                                                                                                        • Slide 30
                                                                                                                                        • Attainment of Superelevation - General
                                                                                                                                        • Tangent Runout Section
                                                                                                                                        • Superelevation Runoff Section
                                                                                                                                        • Slide 34
                                                                                                                                        • Slide 35
                                                                                                                                        • Slide 36
                                                                                                                                        • Slide 37
                                                                                                                                        • Slide 38
                                                                                                                                        • Slide 39
                                                                                                                                        • Slide 40
                                                                                                                                        • Slide 41
                                                                                                                                        • Attainment Location - WHERE
                                                                                                                                        • Minimum Length of Runoff for curve
                                                                                                                                        • Minimum Length of Tangent Runout
                                                                                                                                        • Length of Superelevation Runoff
                                                                                                                                        • Relative Gradient (G)
                                                                                                                                        • Maximum Relative Gradient (G)
                                                                                                                                        • Multilane Adjustment
                                                                                                                                        • Length of Superelevation Runoff Example
                                                                                                                                        • Slide 50
                                                                                                                                        • Tangent runout length Example continued
                                                                                                                                        • Slide 52
                                                                                                                                        • Spiral Curve Transitions
                                                                                                                                        • Slide 54
                                                                                                                                        • Spirals
                                                                                                                                        • Minimum Length of Spiral
                                                                                                                                        • Slide 57
                                                                                                                                        • Maximum Length of Spiral
                                                                                                                                        • Length of Spiral
                                                                                                                                        • Slide 60
                                                                                                                                        • Slide 61
                                                                                                                                        • Slide 62
                                                                                                                                        • Slide 63
                                                                                                                                        • Attainment of Superelevation on spiral curves
                                                                                                                                        • Slide 65
                                                                                                                                        • Slide 66
                                                                                                                                        • Slide 67
                                                                                                                                        • Slide 68
                                                                                                                                        • Slide 69

                                                                                                                                          69

                                                                                                                                          • Slide 1
                                                                                                                                          • Geometric Design ndash Basic Principles
                                                                                                                                          • GEOMETRIC DESIGN ndash Course Heads
                                                                                                                                          • Slide 4
                                                                                                                                          • Curves
                                                                                                                                          • Horizontal Curves
                                                                                                                                          • Design Elements
                                                                                                                                          • Slide 8
                                                                                                                                          • Slide 9
                                                                                                                                          • Slide 10
                                                                                                                                          • Slide 11
                                                                                                                                          • Horizontal Curves
                                                                                                                                          • Slide 13
                                                                                                                                          • Slide 14
                                                                                                                                          • Slide 15
                                                                                                                                          • Slide 16
                                                                                                                                          • Slide 17
                                                                                                                                          • Slide 18
                                                                                                                                          • Horizontal Curve Sight Distance
                                                                                                                                          • Slide 20
                                                                                                                                          • Slide 21
                                                                                                                                          • Slide 22
                                                                                                                                          • Slide 23
                                                                                                                                          • Slide 24
                                                                                                                                          • Slide 25
                                                                                                                                          • TRANSITIONS Superelevation Spiral Curves
                                                                                                                                          • Superelevation
                                                                                                                                          • Image
                                                                                                                                          • Superelevation Transitioning
                                                                                                                                          • Slide 30
                                                                                                                                          • Attainment of Superelevation - General
                                                                                                                                          • Tangent Runout Section
                                                                                                                                          • Superelevation Runoff Section
                                                                                                                                          • Slide 34
                                                                                                                                          • Slide 35
                                                                                                                                          • Slide 36
                                                                                                                                          • Slide 37
                                                                                                                                          • Slide 38
                                                                                                                                          • Slide 39
                                                                                                                                          • Slide 40
                                                                                                                                          • Slide 41
                                                                                                                                          • Attainment Location - WHERE
                                                                                                                                          • Minimum Length of Runoff for curve
                                                                                                                                          • Minimum Length of Tangent Runout
                                                                                                                                          • Length of Superelevation Runoff
                                                                                                                                          • Relative Gradient (G)
                                                                                                                                          • Maximum Relative Gradient (G)
                                                                                                                                          • Multilane Adjustment
                                                                                                                                          • Length of Superelevation Runoff Example
                                                                                                                                          • Slide 50
                                                                                                                                          • Tangent runout length Example continued
                                                                                                                                          • Slide 52
                                                                                                                                          • Spiral Curve Transitions
                                                                                                                                          • Slide 54
                                                                                                                                          • Spirals
                                                                                                                                          • Minimum Length of Spiral
                                                                                                                                          • Slide 57
                                                                                                                                          • Maximum Length of Spiral
                                                                                                                                          • Length of Spiral
                                                                                                                                          • Slide 60
                                                                                                                                          • Slide 61
                                                                                                                                          • Slide 62
                                                                                                                                          • Slide 63
                                                                                                                                          • Attainment of Superelevation on spiral curves
                                                                                                                                          • Slide 65
                                                                                                                                          • Slide 66
                                                                                                                                          • Slide 67
                                                                                                                                          • Slide 68
                                                                                                                                          • Slide 69

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