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Monroe L. Weber-Shir k S chool of Civil and Environmental Engi neering Sedimentation
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Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Mar 29, 2015

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Page 1: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Monroe L. Weber-Shirk

School of Civil and

Environmental Engineering

SedimentationSedimentation

Page 2: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Simple Sorting

Goal: clean waterSource: (contaminated) surface waterSolution: separate contaminants from waterHow?

Page 3: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Unit processes* designed to remove _________________________ remove __________ ___________ inactivate ____________

*Unit process: a process that is used in similar ways in many different applications

Unit Processes Designed to Remove Particulate MatterScreeningCoagulation/flocculationSedimentationFiltration

Where are we?Where are we?

Particles and pathogensdissolved chemicals

pathogens

Empirical design

Theories developed later

Smaller particles

Page 4: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Conventional Surface Water Treatment

Conventional Surface Water Treatment

Screening

Rapid Mix

Flocculation

Sedimentation

Filtration

Disinfection

Storage

Distribution

Raw water

AlumPolymers

Cl2

sludge

sludge

sludge

Page 5: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

ScreeningScreening

Removes large solids logsbranches rags fish

Simple processmay incorporate a mechanized trash

removal system

Protects pumps and pipes in WTP

Page 6: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

SedimentationSedimentation

the oldest form of water treatmentuses gravity to separate particles from wateroften follows coagulation and flocculation

Page 7: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Sedimentation: Effect of the particle concentration

Sedimentation: Effect of the particle concentration

Dilute suspensionsParticles act independently

Concentrated suspensionsParticle-particle interactions are significantParticles may collide and stick together

(form flocs)Particle flocs may settle more quicklyAt very high concentrations particle-

particle forces may prevent further consolidation

Page 8: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

projected

Sedimentation:Particle Terminal Fall Velocity

maF 0 WFF bd

p p g

2

2t

wPDd

VACF W

dF

bF

p wgr" velocity terminalparticle

tcoefficien drag

gravity todueon accelerati

densitywater

density particle

area sectional cross particle

volumeparticle

t

D

w

p

p

p

V

C

g

ρ

ρ

A

_______W

________bF =

Identify forces

( )4

3p w

tD w

gdV

C

r r

r

-=

Page 9: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Drag Coefficient on a Sphere

laminar

Re tV d

turbulentturbulent boundary

0.1

1

10

100

1000

Reynolds Number

Dra

g C

oeff

icie

nt

Stokes Law

24

RedC

18

2wp

t

gdV

( )4

3

p wt

D w

gdV

C

r r

r

-=

Page 10: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Floc DragFloc Drag

C.Dtransition Re( )24

Re

3

Re 0.34

Regraph

CDsphere

0.1 1 10 100 1 103 1 10

4 1 105 1 10

6 1 107

0.1

1

10

100

CDsphere

CDtransition Rek Stokes Rek

Regraph Rek

Flocs created in the water treatment process can have Re exceeding 1 and thus their terminal velocity must be modeled using

Page 11: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Sedimentation Basin:Critical Path

Horizontal velocity

Vertical velocityL

H hV

Sludge zoneInle

t zo

ne

Ou

tlet

zone

Sludge out

cV

hV

WH

flow rate

What is Vc for this sedimentation tank?

Vc = particle velocity that just barely ______________gets captured

Q

A

cV H

Page 12: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Sedimentation Basin:Importance of Tank Surface Area

cV

hV

L

H

W

Suppose water were flowing up through a sedimentation tank. What would be the velocity of a particle that is just barely removed?

Q

tankof area surface topA

tank of volume

timeresidence

s

WHL

Want a _____ Vc, ______ As, _______ H, _______ . small large

Time in tank

small large

cs

QV

A=

HQ

Q

LW s

Q

A c

HV

Vc is a property of the sedimentation tank!

Page 13: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Conventional Sedimentation Basin

Settling zone

Sludge zoneInle

t zo

ne

Ou

tlet

zone

Sludge out

long rectangular basins 4-6 hour retention time 3-4 m deepmax of 12 m widemax of 48 m longWhat is Vc for

conventional design?

3 24 18 /

4c

H m hrV m day

hr day

Page 14: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

___________________________________________________________________________________________________________________________________________________________Vc of 20 to 60 m/day*

Residence time of 1.5 to 3 hours*

Settling zone

Sludge zoneInle

t zo

ne

Ou

tlet

zone

Design Criteria for Horizontal Flow

Sedimentation Tanks

Design Criteria for Horizontal Flow

Sedimentation Tanks

Minimal turbulence (inlet baffles)

Uniform velocity (small dimensions normal to velocity)

No scour of settled particles

Slow moving particle collection system

Q/As must be small (to capture small particles)

* Schulz and Okun And don’t break flocs at inlet!

Page 15: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Sedimentation Tank particle captureSedimentation Tank particle capture

What is the size of the smallest floc that can be reliably captured by a tank with critical velocity of 60 m/day?

We need a measure of real water treatment floc terminal velocities

Research…

Page 16: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Physical Characteristics of Floc: The Floc Density Function

Physical Characteristics of Floc: The Floc Density Function

Tambo, N. and Y. Watanabe (1979). "Physical characteristics of flocs--I. The floc density function and aluminum floc." Water Research 13(5): 409-419.

Measured floc density based on sedimentation velocity (Our real interest!)

Flocs were prepared from kaolin clay and alum at neutral pH

Floc diameters were measured by projected area

Page 17: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Floc Density Function:Dimensional Analysis!Floc Density Function:Dimensional Analysis!

Floc density is a function of __________

Make the density dimensionlessMake the floc size

dimensionlessWrite the functional

relationshipAfter looking at the data

conclude that a power law relationship is appropriate

floc w floc

w clay

df

d

floc

clay

d

d

floc w

w

dn

floc w floc

w clay

da

d

floc size

Page 18: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Model ResultsModel Results

For clay assume dclay was 3.5 m (based on Tambo and Watanabe)

a is 10 and nd is -1.25 (obtained by fitting the dimensionless model to their data)

The coefficient of variation for predicted dimensionless density is 0.2 for dfloc/dclay of 30 and 0.7 for dfloc/dclay of 1500

The model is valid for __________flocs in the size range 0.1 mm to 3 mm

dn

floc w floc

w clay

da

d

clay/alum

Page 19: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Additional Model LimitationAdditional Model Limitation

This model is simplistic and doesn’t includeDensity of clayRatio of alum concentration to clay concentrationMethod of floc formation

Data doesn’t justify a more sophisticated modelAre big flocs formed from a few medium sized

flocs or directly from many clay particles?Flocs that are formed from smaller flocs may tend to be

less dense than flocs that are formed from accumulation of (alum coated) clay particles

Page 20: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Model Results → Terminal Velocity

dn

floc w floc

w clay

da

d

24 30.34

Re RedC

4

3floc w

tD w

gdV

C

= shape factor (1 for spheres)

Requires iterative solution for velocity

Re t flocV d

Page 21: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Floc Sedimentation VelocityFloc Sedimentation Velocity

1 103 0.01 0.1 1 10 100

1

10

100

1 103

Vt dfloci

dclay a nd

m

day

dfloci

mm

a: 10nd: -1.25dclay: 3.5 m: 45/24

Page 22: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Floc density summaryFloc density summary

Given a critical velocity for a sedimentation tank (Vc) we can estimate the smallest particles that we will be able to capture

This is turn connects back to flocculator design

We need flocculators that can reliably produce large flocs so the sedimentation tank can remove them

Page 23: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Flocculation/Sedimentation: Deep vs. Shallow

Flocculation/Sedimentation: Deep vs. Shallow

Compare the expected performance of shallow and deep horizontal flow sedimentation tanks assuming they have the same critical velocity (same Q and same surface area)

More opportunities to ______ with other particles by _________ ____________ or ________________

Expect the _______ tank to perform better!

deepercollide

differentialsedimentationBrownian motion

But the deep tank is expensive to make and hard to get uniform flow!

Page 24: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Flocculation/Sedimentation: Batch vs. Upflow

Flocculation/Sedimentation: Batch vs. Upflow

Compare the expected performance of a batch (bucket) and an upflow clarifier assuming they have the same critical velocity

How could you improve the performance of the batch flocculation/sedimentation tank?

Water inlet

36 - 100 m/dayWater inlet

36 - 100 m/day

Page 25: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

LamellaLamella

Sedimentation tanks are commonly divided into layers of shallow tanks (lamella)

The flow rate can be increased while still obtaining excellent particle removal

Lamella decrease distance particle has to fall in order to be removed

Page 26: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Defining critical velocity for plate and tube settlers

Defining critical velocity for plate and tube settlers

b

L

cosL sin

b

Vup V

How far must particle settle to reach lower plate?

Path for critical particle?

cosc

bh

hc

cosc

bh

What is total vertical distance that particle will travel?

sinh L

h

What is net vertical velocity?net up cV V V

Page 27: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Compare timesCompare times

Time to travel distance hc Time to travel distance h=

cosc

bh

sinh L

c

c up c

h hV V V

sincosc up c

b LV V V

sin cosup c cbV bV L V

sin cosup cbV L b V

sin cosup

c

bVV

L b

b

L

cosL sin

b

Vup V

hc

h

1 cos sinup

c

V LV b

Page 28: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Comparison with Q/AsComparison with Q/As

b

L

cosL

sinb

Vup V

hc

h

Q V bw

sinupV

V

cossin

bA L w

1sin cos

sin

upc

V bwQV

bA L w

sinupV bw

Q

cos sinup

c

V bV

L b

Same answer!

As is horizontal area over which particles can settle

Page 29: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Performance ratio (conventional to plate/tube settlers)

Performance ratio (conventional to plate/tube settlers)

Compare the area on which a particle can be removed

Use a single lamella to simplify the comparison

bL

cosL sin

b

Conventional capture area

sinconventional

bA w

Plate/tube capture area

cossintube

bA w wL

1 cos sinratio

LA

b

Page 30: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Critical Velocity Debate?Critical Velocity Debate?

cos sinc

VV

Lb

cos1

sinup

c

V LV b

Schulz and Okun

Water Quality and Treatment (1999)

1 cos sinup

c

V LV b

Weber-Shirk

WQ&T shows this geometryBut has this equation

Assume that the geometry is

Page 31: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

90°45°

10°5°

Check the extremes!Check the extremes!

01020304050607080900

5

10

15

20

ratio ( )

ratioWS ( )

deg

1 cos sinup

c

V LV b

cos

1sin

up

c

V LV b

Page 32: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Critical Velocity GuidelinesCritical Velocity Guidelines

Based on tube settlers10 – 30 m/day

Based on Horizontal flow tanks20 to 60 m/day

Unclear why horizontal flow tanks have a higher rating than tube settlers

Could be slow adoption of tube settler potential Could be upflow velocity that prevents particle

sedimentation in the zone below the plate settlers

http://www.brentwoodprocess.com/tubesystems_main.html

Schulz and Okun

Page 33: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Problems with Big TanksProblems with Big Tanks

To approximate plug flow and to avoid short circuiting through a tank the hydraulic radius should be much smaller than the length of the tank

Long pipes work well!Vc performance of large scale sedimentation tanks

is expected to be 3 times less than obtained in laboratory sedimentation tanks*

Plate and tube settlers should have much better flow characteristics than big open horizontal flow sedimentation tanks

h

AR

P

Page 34: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Goal of laminar flow to avoid floc resuspension

Goal of laminar flow to avoid floc resuspension

4Re hV R

*2 2h

b w bR

w

1cos

sinc

LV V

b

2Re

V b

12 cos

sinRe 390c

LbV

b

30 /cV m day1L m5b cm60

Re is laminar for typical designs, _____________________

Is Re a design constraint? sinupV

V

1 cos sinup

c

V LV b

h

AreaR

Wet Perimeter

not a design constraint

Page 35: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Mysterious RecommendationsMysterious Recommendations

Re must be less than 280 (Arboleda, 1983 as referenced in Schulz and Okun)

The entrance region should be discounted due to “possible turbulence” (Yao, 1973 as referenced in Schulz and Okun)

0.13Reuseful

L Lb b

At a Re of 280 we discard 36 and a typical L/b is 20 so this doesn’t make sense

But this isn’t about turbulence (see next slide)!!!

Page 36: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Entrance Region Length

1

10

100

Re

l e/D

1/ 64.4 Reel

D0.06Reel

D

laminar turbulent

Reel fD

Distance for velocity profile to develop

0.12Reel

b

Page 37: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Entrance regionEntrance region

The distance required to produce a velocity profile that then remains unchanged

Laminar flow velocity profile is parabolic

Velocity profile begins as uniform flow

Tube and plate settlers are usually not long enough to get to the parabolic velocity profile

Page 38: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Lamella Design Strategy

Angle is approximately 60° to get solids to slide down the incline

Lamella spacing of 5 cm (b)L varies between 0.6 and 1.2 mVc of 10-30 m/dayFind Vup through active area of tankFind active area of sed tankAdd area of tank required for angled

plates: add L*cos() to tank length

tankactive

up

QA

V

1 cos sinup c

LV V

b

Page 39: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Sedimentation tank cross sectionSedimentation tank cross section

Effluent Launder (a manifold)

Page 40: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Design starting with VupDesign starting with Vup

The value of the vertical velocity is important in determining the effectiveness of sludge blankets and thus it may be advantageous to begin with a specified Vup and a specified Vc and then solve for L/b

Page 41: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Equations relating Velocities and geometry

Equations relating Velocities and geometry

1 cos sinactiveup lamella

c

V L

V b

activeup total

up active

V L

V L

cosactive total lamellaL L L

Continuity (Lengths are sed tank lengths)

Lamella gain

Page 42: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Designing a plate settlerDesigning a plate settler

wplate

bplate

Lplate

Qplant

Ntanks

Vertical space in the sedimentation tank divided between sludge storage and

collection flow distributionPlates flow collection

Page 43: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

AguaClara Plant Layout (draft)AguaClara Plant Layout (draft)

Drain Valve access holes

Chemical store room

Steps

Effluent launders

Sed tanks

Floc tank

To the distribution tank

Sed tank manifold

Page 44: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Distributing flow between tanksDistributing flow between tanks

Which sedimentation tank will have the highest flow rate?

Where is the greatest head loss in the flow through a sedimentation tank?

Either precisely balance the amount of head loss through each tank

Or add an identical flow restriction in each flow path

Where is the highest velocity?

Page 45: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Will the flow be the same?Will the flow be the same?

h

Long

Short

Head loss for long route = head loss for short route if KE is ignored

Q for long route< Q for short route

K=1K=1

K=

1

K=0.2K=0.5 K=1

2 21 1 2 2

1 22 2 L

p V p Vz z h

g g g g

Page 46: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Conservative estimate of effects of manifold velocity

Conservative estimate of effects of manifold velocity

2

1 2 2 longport

portL

VH H h

g

long short

Control surface 1l

cs 3

Long orifice Short orifice2

1 3 2 shortport

portL

VH H h

g

cs 2

2max

2 3 2 manifold

manifoldL

VH H h

g

cs 4 cs 5

2 2

2 32 2longport shortport

port portL L

V VH h H h

g g

2max

2 manifold longport shortport

manifoldL L L

Vh h h

g

Page 47: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Modeling the flowModeling the flow

2

2

elonglong

longlongratio

short eshortshort

short

ghA

KQQ

Q ghA

K

Q.pipeminor D h.e K A.circle D( )2 g h.e

K

long shortL Lh h

0.20.26

3short

ratiolong

KQ

K

We are assuming that minor losses dominate. It would be easy to add a major loss term (fL/d). The dependence of the friction factor on Q would require iteration.

Since each point can have only one pressure

This neglects velocity head differences

Page 48: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Design a robust system that gets the same flow through both pipes

Design a robust system that gets the same flow through both pipes

2

21ratio long short

controlratio

Q K KK

Q

short controlratio

long control

K KQ

K K

2

2

0.95 3 0.225.7

1 0.95controlK

Add an identical minor head loss to both paths

Solve for the control loss coefficient

Design the orifice…

Page 49: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Piezometric head decrease in a manifold assuming equal port flows

Piezometric head decrease in a manifold assuming equal port flows

2 2

port port

2 4 2 41

8 8port

np

i

iQ C nQH

g d g d

port

2

2 22 4

1

8port

n

pi

QH C i n

g d

2 2

1

2 3 16

n

i

ni n n

Piezometric head decrease in a manifold with n ports d is the manifold diameter

represents the head loss coefficient in the manifold at each port or along the manifold as fL/d

Note that we aren’t using the total flow in the manifold, we are using Qport

port

2

2 22 4

82 3 1

6portp

Q nH C n n n

g d

Head loss Kinetic energy

portpC

Page 50: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Convert from port to total manifold flow and pressure coefficient

Convert from port to total manifold flow and pressure coefficient

total portQ nQportp pC nC

port

2

2 22 4

82 3 1

6portp

Q nH C n n n

g d

total

2

2 4 2

8 1 1 11

3 2 6p

QH C

g d n n

Loss coefficient Velocity headmanifold

pmanifold

LC f K

d Note approximation with f

These are losses in the manifold

Page 51: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Calculate additional head loss required to get uniform flow

Calculate additional head loss required to get uniform flow

2

1 1 11

3 2 6long pK Cn n

0shortK

Kcontrol is the minor loss coefficient we need somewhere in the ports connecting to the manifold

Note that this Klong gives the correct head loss when using Qmaxmanifold

Long path Short path

2

2

1 1 11

3 2 61

1

p

control

ratio

Cn n

K

Q

2

21ratio long short

controlratio

Q K KK

Q

Page 52: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Total Loss CoefficientTotal Loss Coefficient

2

1 1 11

3 2 6long pK Cn n

2

21ratio long

controlratio

Q KK

Q

21long

total long controlratio

KK K K

Q

Excluding KE

Including KE (more conservative)

2

2 2

11 1

1 1long ratio long

total long controlratio ratio

K Q KK K K

Q Q

We are calculating the total loss coefficient so we can get a relationship between the total available piezometric head and the diameter of the manifold

Page 53: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Calculate the manifold diameter given a total manifold head lossCalculate the manifold diameter given a total manifold head loss

2manifold

2 4

8 totall

manifold

Q Kh

g d

12 4

2

8 manifold totalmanifold

l

Q Kd

g h

Solve the minor loss equation for D

We could use a total head loss of perhaps 5 to 20 cm to determine the diameter of the manifold. After selecting a manifold diameter (a real pipe size) find the required control head loss and the orifice size.

Minor loss equation

Ktotal is defined based on the total flow through the manifold and includes KE .

21long

totalratio

KK

Q

2

1 1 11

3 2 6long pK Cn n

Page 54: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Full Equation for Manifold DiameterFull Equation for Manifold Diameter

∑ Cp is loss coefficient for entire length of manifold

12 4

2

8 manifoldmanifold total

l

Qd K

gh

1

4

2 2

2 2

1 1 11

8 3 2 61

pmanifold

manifoldl ratio

CQ n n

dgh Q

21long

totalratio

KK

Q

2

1 1 11

3 2 6long pK Cn n

Page 55: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Manifold design equation with major losses

Manifold design equation with major losses

n is number of portsf is friction factor (okay to use f based on Qtotal)Qratio is acceptable ratio of min port flow over max port flowhl is total head loss through the ports and through the manifoldQmanifold is the total flow through the manifold from the n ports∑K is the sum of the minor loss coefficients for the manifold (zero for a straight pipe)

Iteration is required!

1

4

22

2 2

1 1 11

3 2 68

1

manifold

manifoldmanifoldmanifold

l ratio

Lf K

d n nQd

gh Q

Page 56: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Head loss in a ManifoldHead loss in a Manifold

2

4 2 2

8 1 1 1

3 2 6manifold

manifoldtotall

manifold manifold

fLQh K

d g d n n

2

1 1 1

3 2 6manifoldl lh hn n

The head loss in a manifold pipe can be obtained by calculating the head loss with the maximum Q through the pipe and then multiplying by a factor that is dependent on the number of ports.

Page 57: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Now find the effluent launder orifice area

Now find the effluent launder orifice area

2or controlQ K A gh

2or control

QA

K gh

Use the orifice equation to figure out what the area of the flow must be to get the required control head loss. This will be the total area of the orifices into the effluent launder for one tank.

2

2

1 1 11

3 2 61

1

p

control

ratio

Cn n

K

Q

Page 58: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Orifice flow (correction!)Orifice flow (correction!)

2orQ K A g h 2

2 2

1

2or

or or

Qh

K gA

Solve for h and substitute area of a circle to obtain same form as minor loss equation

Kor = 0.63

2.5 d 8 d

d

h

D

2

22manifold

emanifold

Qh K

gA

4 2

2 4 2

4

2 4 2

1

1

manifold or

or or manifold

or or manifold

manifold

or or or

d QK

K d Q

Q n Q

dK

K d n

Page 59: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Calculating the orifice diameter based on uniform flow between orifices

Calculating the orifice diameter based on uniform flow between orifices

2

2

1 1 11

3 2 61

1

p

control

ratio

Cn n

K

Q

4

2 4 2

1 manifoldcontrol

or or or

dK

K d n

1

4

2 2

1or manifold

or or control

d dK n K

manifoldp

manifold

LC f K

d

Page 60: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

How small must the orifice be?Case of 1 orifice

How small must the orifice be?Case of 1 orifice

4

2 4

pipe

or or

dK

K d

1

4

2

1or pipe

or

d dKK

For this case dorifice must be approximately 0.56dpipe.

We learned that we can obtain equal similar parallel flow by ensuring that the head loss is similar all paths.

We can compensate for small differences in the paths by adding head loss that is large compared with the small differences.

Page 61: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Effluent Launders: Manifold ManifoldsEffluent Launders: Manifold Manifolds

Two Goals Extract water uniformly from the top of the sed tank so the flow

between all of the plates is the same Create head loss that is much greater than any of the potential

differences in head loss through the sedimentation tanks to guarantee that the flow through the sedimentation tanks is distributed equally

A pipe with orifices Recommended orifice velocity is 0.46 to 0.76 m/s (Water

Treatment Plant Design 4th edition page 7.28) The corresponding head loss is 3 to 8 cm through the orifices but it isn’t necessarily this simple!

We need to get a low enough head loss in the rest of the system

Page 62: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Effluent Launders and ManifoldEffluent Launders and Manifold

We need to determine the required diameter of the effluent launder pipe The number and the size of the orifices that control the flow of

water into the effluent launder The diameter of the manifold

The head loss through the orifices will be designed to be large relative to the differences in head loss for the various paths through the plant

We need an estimate of the head loss through the plant by the different paths

Eventually take into account what happens when one sedimentation tank is taken off line.

Page 63: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Head Loss in a sed tank? Head Loss in a sed tank?

Head loss through sed tank inlet pipes and plate settlers is miniscule

The major difference in head loss between sed tanks is due to the different path lengths in the manifold that collects the water from the sed tanks.

We want equally divided flow two places Sed tanks Plate settlers (orifices into launders)

Page 64: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Manifold head loss:Sed tanks equal!

Manifold head loss:Sed tanks equal!

We will assume minor losses dominate to develop the equations. If major losses are important they can be added or modeled as a minor loss.

The head loss coefficient from flowing straight through a PVC Tee is approximately 0.2

We make the assumption that the flow into each port is the same

Eventually we will figure out the design criteria to get identical port flow

Page 65: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Minor losses vs. Major lossesMinor losses vs. Major losses

Compare by taking a ratio 2

e 2

Vh K

g

2

f f2

L Vh

D g

e

f f

Kh D

h L

f

e f

KhL

D h

11

0.02

L

D Thus in a 10 cm diameter pipe, an

elbow with a K of 1 gives as much head loss as 5 m of pipe

Page 66: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Now design the Effluent LaunderNow design the Effluent Launder

The effluent launder might be a smaller diameter pipe than the sed tank manifold (especially if there are many sedimentation tanks)

The orifice ports will be distributed along both sides of the launder

Page 67: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Now design the Effluent LaunderNow design the Effluent Launder

Port spacing should be less than the vertical distance between the ports and the top of the plate settlers (I’m not sure about this constraint, but this should help minimize the chance that the port will cause a local high flow through the plate settlers closest to the port)

The depth of water above the plate settlers should be 0.6 to 1 m with launders spaced at 1.5 m (Water Treatment Plant

Design 4th edition page 7.24) This design guideline forces us to use a very deep tank. Deep

tanks are expensive and so we need to figure out what the real constraint is.

It is possible that the constraint is the ratio of water depth to launder spacing.

Page 68: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Effluent LaunderEffluent Launder

The solution technique is similar to the manifold design

We know the control head loss – the head loss through the ports will ensure that the flow through each port is almost the same

We need to find the difference in the head loss between the extreme paths

Then solve for the diameter of the effluent launder

Page 69: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Sedimentation Tank AppurtenancesSedimentation Tank Appurtenances

Distributing the flow between parallel tanks Effluent Launders Sludge removal (manifold design similar to

effluent launders) Isolating a tank for fill and drain: using only a

single drain valve per tankFilling the tank with clean waterNot disturbing the water levels in the rest of the plant

Entrance manifolds: designed to not break up flocs

Page 70: Monroe L. Weber-Shirk S chool of Civil and Environmental Engineering Sedimentation.

Plate settlers

launder

Sludgedrain

Sludge drain line that discharges into a floor drain on the platform