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Appendix B. Hand Calculation Method for Orifice Design
AbstractThis appendix explains how to perform the calculations
for orifice plate design by hand. For manual look-up of the orifice
coefficient, S (given beta) or the diameter ratio, beta (given S),
the following eight figures are provided:
Orifice calculation sheets have been prepared for guidance
through the orifice calcu-lation steps. Calculation sheets filled
in with appropriate examples are attached. The four orifice
calculation sheets are as follows:
LIQUID, square-edge orifice, Form ICM-EF-59B (Figure B-9)
LIQUID, quadrant-edge orifice, Form ICM-EF-59C (Figure B-10) GAS,
square-edge orifice, Form ICM-EF-59D (Figure B-11) VAPOR/STEAM,
square-edge orifice, Form ICM-EF-59E (Figure B-12)Note that in
these calculation sheets, the term "sharp edge" is used instead of
"square-edge."
Results of the hand calculations agree closely with the computer
program ORIFICE.
The two types of calculations that can be performed are orifice
sizing and orifice re-ranging, except for quadrant-edge.
Figure B-1 Flange Taps - 6 Inch Pipe Size (6.056 in.); S vs.
Beta for Different RD Values (Based on Data from ISO 5167)
Figure B-2 Flange Taps; Pipe Size Corrections for S Values
(Based on Data from ISO 5167)
Figure B-3 Radius Taps; S vs. Beta for Different RD Values
(Based on Data from ISO 5167)
Figure B-4 Corner Taps; S vs. Beta for Different RD Values
(Based on Data from ISO 5167)
Figure B-5 Pipe Taps; S vs. Beta for Different RD Values (Based
on Data from ISO 5167)
Figure B-6 ASME Small Bore with Flange Taps; S vs. Beta for
Different RD Values1 in. to 1-1/2 in. Pipe Size (Based on Data from
"Fluid Meters: Their Theory and Applica-tion", 6th ed., 1971.
Courtesy of ASME)
Figure B-7 ASME Small Bore with Corner Taps (.546 in.); S vs.
Beta for Different RD Values1/2 in. Schedule 80 Pipe Size (Based on
Data from "Fluid Meters: Their Theory and Application", 6th ed.,
1971. Courtesy of ASME)
Figure B-8 Quadrant Edge Data; S and Thickness Ratio vs.
BetaChevron Corporation B-1 July 1999
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Appendix B Instrumentation and Control ManualB1.0 Calculation
Procedure1. Fill in the STREAM PROPERTY input blocks.
2. Fill in the FLOW RATE input blocks.
3. Fill in the ORIFICE DATA input blocks.
TEMPERAURE -- degrees Fahrenheit for liquid and vapor/steam--
degrees Rankine = F + 460 for gas
PRESSURE -- PSIA for gas and vaporLIQUID SPECIFIC GRAVITY -- Gb
at 60 F (Gb for water =
1.00)VAPOR/STEAM SPECIFIC GRAVITY -- cu.ft./lb.
-- for steam, use steam tablesGAS SPECIFIC GRAVITY -- Ideal sp.
gr. is used
= M.W. gas/M.W. dry air= Zb Real sp. gr.
LIQUID KINEMATIC VISCOSITY -- use centistokesGAS AND VAPOR
ABSOLUTE VISCOSITY
-- use centipoise
UNITS: For liquid use BPD, BPH, GPM, or GPH. For vapor use
lbs/hour; for gas use SCFH.
FULL SCALE: Flow that creates a dp across the orifice taps equal
to the maximum value of the dp transmitter range.
NORMAL: For square-edge and ASME small-bore this should be the
mid-range dp value, which equals .707 (full-scale flow rate)
1/3 FS: For quadrant-edge, equal to .333 (full-scale flow
rate)
TYPE OF ORIFICE PLATE -- Square-edge-- ASME small-bore--
Quadrant-edge
TYPE OF TAPS -- Flange, radius, corner or pipe
forsquare-edge
-- Flange or corner only for ASMEsmall-bore
-- Flange for quadrant-edgePIPE INSIDE DIAMETER -- Use 3 decimal
placesORIFICE DIAMETER -- Entered for orifice re-ranging
calculation July 1999 B-2 Chevron Corporation
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Instrumentation and Control Manual Appendix B4. Fill in the
CORRECTIONS FACTORS.
5. Calculate Pipe Reynolds Number.
Space is provided for values in equations.
See examples on sheets provided.
6. Calculate orifice size or dp range for square-edge or ASME
small-bore orifice.
Given h, Find dFill in equations and solve for S.Look up beta
ratio in table.Interpolation is necessary.Use Table in Figure B-2
to correct for pipe size other than 6-inches (2-12 inches).Use
Reynolds number column that is closest to value calculated in step
5.
Given d, Find hCalculate beta ratio.Look up S in
table.Interpolation is necessary.
Use Reynolds number that is closest to value calculated in Step
5.
See examples on sheets provided.
7. Calculation for quadrant-edge orifice size.
-- Use 3 decimal placesFULL SCALE DP -- Entered for orifice
sizing calcula-
tion-- Standard value = 100 inches of
water
Fa -- Correction for thermal expansion of orifice meter at
flowing temperature found in ASME MFC-3M Tables or API MPMS.
Chapter 14.3/AGA-3.
Y -- Gas expansion factor for mid-scale flow Y1 = correction
based on upstream pressure Y2 = correction based on downstream
pressure Look up in table or chart - use mid-range differential
pressure (dp)
Fpv -- Supercompressibility correction factor Rarely used in
refinery calculations (usually set = 1.0)Look up in table or chart
when used.
Zb -- Compressibility factor at 60F, 1 Atm Rarely used in
refinery calculations (usually set = 1.0) Look up in table or chart
when used.Chevron Corporation B-3 July 1999
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Appendix B Instrumentation and Control ManualSelect a plate
thickness, look up values from Figure B-8, and calculate the
differential pressure h.
If h is too large, make plate thicker; if too small, make plate
thinner, and repeat calculation. h should equal about 100 inches of
water.
The permissible range of Reynolds numbers (at 1/3 full-scale
flow) for a quad-rant-edge orifice is a function of the beta
ratio:
See example on calculation sheet provided.
beta ratio 0.2 0.3 0.4 0.5 0.6min. RD 670.0 770.0 630.0 450.0
320.0max. RD 17500.0 28000.0 45000.0 70000.0 85000.0July 1999 B-4
Chevron Corporation
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Instrumentation and Control Manual Appendix BFig. B-1 Flange
Taps - 6 Inch Pipe Size (6.056 in.); S vs. Beta for Different RD
Values (Based on Data from ISO 5167)Chevron Corporation B-5 July
1999
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Appendix B Instrumentation and Control ManualFig. B-2 Flange
Taps; Pipe Size Corrections for S Values (Based on Data from ISO
5167)July 1999 B-6 Chevron Corporation
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Instrumentation and Control Manual Appendix BFig. B-3 Radius
Taps; S vs. Beta for Different RD Values (Based on Data from ISO
5167)Chevron Corporation B-7 July 1999
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Appendix B Instrumentation and Control ManualFig. B-4 Corner
Taps; S vs. Beta for Different RD Values (Based on Data from ISO
5167)July 1999 B-8 Chevron Corporation
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Instrumentation and Control Manual Appendix BFig. B-5 Pipe Taps;
S vs. Beta for Different RD Values (Based on Data from ISO
5167)Chevron Corporation B-9 July 1999
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Appendix B Instrumentation and Control ManualFig. B-6 ASME Small
Bore with Flange Taps; S vs. Beta for Different RD Values1 in. to
1-1/2 in. Pipe Size (Based on Data from "Fluid Meters: Their Theory
and Application", 6th ed., 1971. Courtesy of ASME)July 1999 B-10
Chevron Corporation
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Instrumentation and Control Manual Appendix BFig. B-7 ASME Small
Bore with Corner Taps (.546 in.); S vs. Beta for Different RD
Values1/2 in. Schedule 80 Pipe Size (Based on Data from "Fluid
Meters: Their Theory and Application", 6th ed., 1971. Courtesy of
ASME)Chevron Corporation B-11 July 1999
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Appendix B Instrumentation and Control ManualFig. B-8 Quadrant
Edge Data; S and Thickness Ratio vs. BetaJuly 1999 B-12 Chevron
Corporation
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Instrumentation and Control Manual Appendix BFig. B-9 Orifice
Calculation SheetLiquid, Square-edge OrificeChevron Corporation
B-13 July 1999
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Appendix B Instrumentation and Control ManualFig. B-10 Orifice
Calculation SheetLiquid, Quadrant-edge OrificeJuly 1999 B-14
Chevron Corporation
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Instrumentation and Control Manual Appendix BFig. B-11 Orifice
Calculation SheetGas, Square-Edge OrificeChevron Corporation B-15
July 1999
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Appendix B Instrumentation and Control ManualFig. B-12 Orifice
Calculation SheetVapor/Steam, Square-Edge OrificeJuly 1999 B-16
Chevron Corporation
Manual ContentsB1.0 Calculation ProcedureEngineering
SpecificationsStandard Drawings & Forms