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Lecture 14
Upfeed SystemsPipe Sizing Procedure Pipe Sizing Example
Lecture 14
Upfeed SystemsPipe Sizing Procedure Pipe Sizing Example
Upfeed SystemsUpfeed SystemsUpfeed SystemsUpfeed Systems
Pressure in Upfeed SystemsPressure in Upfeed Systems
Fixture pressure head Static headFriction head lossMeter pressure loss
M: p. 929, F.21.13
Pressure in Upfeed SystemsPressure in Upfeed Systems
Proper fixture flow pressureA+ Pressure lost due to heightB+ Pressure lost due to frictionC+ Pressure lost through meterD Total street main pressure E
A: FixtureA: FixtureFlow PressureFlow Pressure
Pressure needed to get water through fixture
M: p. 987, T.21.14
B: Pressure lost due to B: Pressure lost due to heightheight
Weight of water column
M: p. 929, F.21.13
C: Pressure loss due to C: Pressure loss due to frictionfriction
Initially unknown, must be calculated based on pressure remaining after accounting for the other factors
D: Pressure lost through D: Pressure lost through metermeter
Make initial size assumption and then repeat to optimum size
M: p. 988, F.21.63a
E: Total Street Main E: Total Street Main PressurePressure
Check with water company or fire department
Pipe Sizing ProcedurePipe Sizing ProcedurePipe Sizing ProcedurePipe Sizing Procedure
1. Determine 1. Determine Supply Supply Fixture Fixture Units Units
Fixture units take into account usage diversity
M: p. 991, T.21.15
2. Calculate Demand Flow2. Calculate Demand Flow
Use curve 1 for flush valve dominated systemUse curve 2 for flush tank dominated systems
M: p. 992, F.21.65a
3. Determine the 3. Determine the “Most Critical Fixture (MCF)”“Most Critical Fixture (MCF)”
Highest and farthest from inlet main
Confirm pressure required (A)
Identify height (B)
M: p. 975, F.21.52
4. Determine Developed 4. Determine Developed LengthLength
The total length of all horizontal and vertical pipes from the main to the MCF
M: p. 1014, F.22.17
5. Determine Total 5. Determine Total Effective Length (TEL)Effective Length (TEL)
Two approaches:
1. equivalent length or2. multiply DL x 1.5
TEL= DL x 1.5
M: p. 993, T.21.16a
6. Determine Street 6. Determine Street Main Pressure (E)Main Pressure (E)
Contact utility company or fire department
7. Determine Pressure 7. Determine Pressure Available for Friction Loss Available for Friction Loss
Proper fixture flow pressureA+ Pressure lost due to heightB+ Pressure lost due to frictionC+ Pressure lost through meter D Total street main pressure E
orC=E-A-B-D
Meter Loss (D)Meter Loss (D)
Since D is unknown, pick an initial size, do calculation, repeat as needed to optimize flow
C=E-A-B-D
M: p. 988, F.21.63a
8. Determine Friction 8. Determine Friction loss/100’loss/100’
C=E-A-B-D
Δp/100’ = 100 x C/TEL
9. Verify flow 9. Verify flow for meter sizefor meter size
If flow > Total Demand (#2) repeat 7-9 at smaller diameter
If flow < Total Demand (#2) repeat 7-9 at larger diameter
M: p. 989, F.21.64a
10. Select final10. Select finalmeter sizemeter size
When flow > Total Demand (#2) stop
M: p. 989, F.21.64a
Pipe Sizing ExamplePipe Sizing ExamplePipe Sizing ExamplePipe Sizing Example
Given InformationGiven InformationSmall Office Building public numbers
2 Flush valve toilets2 Lavatories2 Drinking fountains1 Service sink
DL: 92’MCF: Flush Valve Toilet, 16’ above water mainStreet Main Pressure: 44.1 psi
1. Determine 1. Determine Supply Supply Fixture Fixture Units Units
Fixture units take into account usage diversity
M: p. 991, T.21.15
1. Determine Supply Fixture 1. Determine Supply Fixture UnitsUnits
Cold Hot Total2 Flush valve toilets 20.00 --- 20.02 Lavatories 3.00 3.00 4.02 Drinking fountains 0.50 --- 0.51 Service sink 2.25 2.25 3.0
25.75 5.25 27.5
2. Calculate Demand Flow2. Calculate Demand Flow20 WSFU out of 27.5 WSFU are flush valves Use curve 1 for flush valve dominated system
40 gpmM: p. 992, F.21.65a
3. Determine 3. Determine the Most the Most Critical Critical Fixture Fixture
Confirm pressure required (A)
15 psi
Height above main (B)
16’ 7.0 psiS. p. 987, T.21.14
4. Determine Developed 4. Determine Developed LengthLength
Developed length
92’
M: p. 1014, F.22.17
Note: this figure for generic reference only and does not illustrate the example problem
5. Determine Total 5. Determine Total Effective Length (TEL)Effective Length (TEL)
TEL= DL x 1.5 = 92 x 1.5 = 138’
6. Determine Street 6. Determine Street Main Pressure (E)Main Pressure (E)
44.1 psi
7. Determine Pressure 7. Determine Pressure Available for Friction Loss Available for Friction Loss
Proper fixture flow pressureA15.0+ Pressure lost due to heightB7.0+ Pressure lost due to frictionC ?+ Pressure lost through meter D?
Total street main pressure E44.1
Meter Loss (D)Meter Loss (D)
Pick an initial size
2” diameter… 1.4 psi
M: p. 988, F.21.63a
8. Determine Friction 8. Determine Friction loss/100’loss/100’
C=E-A-B-D = 44.1-15.0-7.0-1.4 = 20.7 psi
Δp/100’=100 x 20.7/138 = 15 psi/100’
9. Verify flow 9. Verify flow for meter sizefor meter size
At 2” Flow=150 gpm > Total Demand 40 gpm
At 1-1/2”Flow=60 gpm > Total Demand 40 gpm
(Δp/100’= 13.1)
At 1”Flow=13 gpm < Total Demand 40 gpm
(Δp/100’= 5.1)M: p. 989 F.21.64a
9. Verify flow 9. Verify flow for meter sizefor meter size
When flow > Total Demand (#2) stop
At 1-1/2”Flow=60 gpm > Total Demand 40 gpm
(Δp/100’= 13.1)
M: p. 989 F.21.64a
Pipe SizingPipe SizingUse Δp/100’= 13.1 psi/100’
Use fixture units to determine flow
M: p. 989 F.21.64a
Pipe SizingPipe Sizing
Use fixture units to determine flow
Pay attention to flush valve domination
M: p. 992 F.21.65a
Pipe SizingPipe SizingUse Δp/100’= 13.1 psi/100’
Use fixture units to determine flow
Select size which does not exceed 13.1 psi/100’
20 gpm, use 1” 10 gpm, use ¾”
Use runout sizes at each fixture
M: p. 989, F.21.64a
Runout Runout Pipe SizingPipe Sizing
Use actual flow to size runouts
Lavatory: 2 gpm
M: p.987, T.21.14
Runout Runout Pipe SizingPipe Sizing
Use Δp/100’= 13.1 psi/100’
Lavatory: 2 gpm
M: p. 989, F.21.64a
Notation SystemNotation System
Suggested for organizing data
WSFU CurveFlow Diam.
M: p. 1014, F.22.17
3.6 2 4 ¾”
2.7 2 3 ½”
Waste & Vent SystemsWaste & Vent SystemsWaste & Vent SystemsWaste & Vent Systems
FundamentalsFundamentals
Siphon action can drain water
Trap blocks sewer gas
Vent breaks siphon
M: p. 1006, F.22.8
Air GapsAir Gaps
Eliminate the potential for cross contamination
M: p. 1009, F.22.11
Vents and StacksVents and Stacks
Individual ventsCircuit ventsSoil stackVent stackStack vent
“Wet stack”
Vent through roof (VTR)
M: p. 1008, F.22.10
Note: Drain fittings are 45º
Drains & SewersDrains & Sewers
House drainHouse sewerStorm drain
Clean outsHouse trapsFresh air inlet
M: p. 1007, F.22.9
Note: Drain fittings are 45º
Waste & Vent Sizing Waste & Vent Sizing ProcedureProcedureWaste & Vent Sizing Waste & Vent Sizing ProcedureProcedure
1. Identify waste & soil locations1. Identify waste & soil locations
Clusters are more efficient
M: p. 1014, F.22.17
2. Layout system 2. Layout system vertically & horizontallyvertically & horizontally
Grouped fixtures can be stacked in a vertical riser
M: p. 1027, F.22.31
3. Size Traps3. Size Traps
Trap size is usedwhen connectingto main
M: p. 1017, T.22.2
4. Calculate 4. Calculate Drainage Fixture Drainage Fixture Units (DFU) Units (DFU)
Pipe sizes based on DFU
M: p. 1017, T.22.2.2
5. Determine loads5. Determine loads
Fixture location may control size
M: p. 1022, F.22.24
6. Determine slope and size of 6. Determine slope and size of horizontal drains horizontal drains
Slope may be constrained by depth of floor cavity
M: p. 1020, T.22.5
7. Verify maximum vent length7. Verify maximum vent length
Measured from plans
M: p. 1022, F.22.24
8. Size vents according to 8. Size vents according to DFU and length DFU and length
Calculate for each vent load and developed length
M: p. 1019, T.22.4
9. Verify space requirements 9. Verify space requirements and adjust designand adjust design
Common adjustments “Wet” walls 6” cavity Slope and ceiling exposure Cleanout access
