HomeMy WebLinkAbout20 - Design Report - The Nest PUD - Water, Sewer
DESIGN REPORT
WATER & SEWER MANAGEMENT
THE NEST PUD SUBDIVISION
Prepared for:
Center Arrow Partners, LLC
P.O. Box 1633, Bozeman, MT 59771
Prepared by:
C&H Engineering and Surveying, Inc.
1091 Stoneridge Drive, Bozeman, MT 59718
(406) 587-1115
Project Number: 180805
April 2020
INTRODUCTION
The proposed Nest PUD Subdivision is a 15-lot condominium subdivision located on Lot R1,
Block 5, Westbrook Subdivision, Phase 4 (5.41-acres) in the Westbrook Subdivision. This project
will require connection to existing City of Bozeman water and sanitary sewer systems.
WATER SYSTEM LAYOUT
The Nest PUD Subdivision will extend the existing 8” class 51 ductile iron water main installed
in Glenwood Drive and Annie Street and will tap into the existing 12” water main running along
Durston Road. All new water mains are to be installed in the City standard location and will be
located 10’ away from any proposed sewer mains. All water mains will be looped and no blowoffs
will be required with this layout.
A WaterCAD analysis is enclosed at the end of the report analyzing the 8-inch water main
extension installed with this project. The connection to the existing system was modeled as a pump
curve using data obtained from the City of Bozeman Water Department: static, residual and pitot
pressures were read at hydrants #2005 and #1985, located at the intersections of Annie Street/Twin
Lakes Ave and Annie Street/Rosa Way, respectively. This data was used to develop the pump
curve used at the connection point to model the existing system. The following equation based off
of the Hazen Williams method is used to generate the pump curve:
Q = Qf x ((Ps - P) / (Ps - Pr))0.54
Where: Q = flow predicted at desired residual pressure, Qf = total flow measured during test, Pr=
residual pressure during test, Ps = static pressure and P = residual pressure at the desired flow rate.
In the model, the pump is connected to a reservoir which acts as a source of water. The elevation
of the reservoir is fixed at the elevation of the pump, which is also equivalent to the elevation of
the tie-in point. The reservoir does not create any head on the system; the head is generated entirely
by the pumps. The input data and the pump curves are included at the end of the report. The pump
curve table includes all calculations and equations used in determining flow characteristics at the
connection point. A C-factor of 130 was chosen for ductile iron class 51 pipe.
WATER DISTRIBUTION SYSTEM SIZING
Residential Units:
Average Daily Residential Usage = 170 gallons per capita per day
Average Population Density = 2.17 persons/dwelling unit
Minimum Fire Hydrant Flow = 1,500 gpm
Residual Pressure Required = 20 psi for Fire Flow
Average Day Demand (Peaking Factor = 1)
Maximum Day Demand (Peaking Factor = 2.3)
Maximum Hour Demand (Peaking Factor = 3.0)
Residential Water Demands (Demand Junction 1)
Average Day Demand = 33 d.u. x 2.17 persons/d.u. x 170 gpcpd = 12,240 gpd = 8.5 gpm
Maximum Day Demand = 8.5 gpm x 2.3 = 19.4 gpm
Peak Hour Demand = 8.5 gpm x 3.0 = 25.4 gpm
Residential Water Demands (Demand Junction 2)
Average Day Demand = 12 d.u. x 2.17 persons/d.u. x 170 gpcpd = 4,464 gpd = 3.1 gpm
Maximum Day Demand = 3.1 gpm x 2.3 = 7.1 gpm
Peak Hour Demand = 3.1 gpm x 3.0 = 9.2 gpm
Available Pressure: 8-inch class 51 ductile iron main Annie Street and Rosa Way
Static = 96 psi (Hydrant #2005)
Residual = 88 psi (Hydrant #2005)
Pitot (2.5” nozzle) = 80 (Hydrant #1985)
Flowing = 1,500 gpm (Hydrant #1985)
Design Report - Page 4 of 8
HYDRAULIC ANALYSIS
A water distribution model was created using WaterCAD Version 10.01.00.72 for demand
forecasting and describing domestic and fire protection requirements. In order to model the system,
each junction node of the water distribution system was assessed a demand based on its service
area. The table shown below quantifies the demands placed at the junction nodes and calculates
the demands for Average Day, Maximum Day and Peak Hour within the subdivision. The peaking
factor for each case is 1, 2.3 and 3.0 respectively.
The Nest PUD Subdivision (Table 1):
DEMAND JUNCTION NODE DWELLING UNITS (D.U.)
POPULATION (RES.) 2.17 PEOPLE PER D.U.
AVERAGE DAY GPM (170 GALLONS PER DAY PER PERSON)
MAX. DAY GPM
PEAK HOUR GPM
DJ 1 33 72 8.5 19.4 25.4
DJ 2 12 26 3.1 7.1 9.2
Total 45 98 11.53 26.51 34.58
*See Demand Junction Map for more information on which lots contribute to each Demand
Junction.
CONCLUSION
The proposed 8-inch DIP water mains provide adequate capacity to serve the subdivision under
the Peak Hour Demand condition. The flows and pressures within the system for the Peak Hour
Demands were generated with the WaterCAD program and can be found in Appendix A.
The capacity of the system to meet fire flow requirements was tested by running a steady state fire
flow analysis for all junctions at fire hydrant locations. The model shows that all hydrant junctions
satisfy fire flow constraints (residual pressure > 20 psi, flow rate > 1500 gpm), while providing
service to lots at peak hour. The results of the analysis at peak hourly flow are given in Appendix
A.
Design Report - Page 5 of 8
SANITARY SEWER SYSTEM
An 8-inch PVC sanitary sewer line will be installed in the woonerf section and will flow north to
connect with the existing 8-inch stub located just south of the Annie Street/Cassandra Lane
intersection.
DESIGN REQUIREMENTS
The flow rates used herein are according to the City of Bozeman Design Standards and
Specifications Policy (DSSP) dated March, 2004. The peaking factor for the design area is
determined by figuring the equivalent population and inserting the population into the Harmon
Formula. An 8-inch main is used because that is the minimum diameter allowed within the City of
Bozeman.
Using the city average of 2.17 persons per household the equivalent population is calculated.
Connection:
Equivalent Population = (2.17 persons/dwelling unit)(45 units) = 98 persons
Harmon Formula: Peaking Factor = (18 + P0.5)/(4 + P0.5)
where: P = Population in thousands
Peaking Factor = (18 + 0.0980.5)/(4 + 0.0980.5)
Peaking Factor = 4.25
Assumed infiltration rate = 150 gallons/acre/day = 150 (5.41 acres) = 812 gal/day
The peak flow rate is calculated by multiplying the City's design generation rate of 65 gallons per
capita per day by the population, multiplying by the peaking factor, and adding the infiltration rate:
Peak Flow Rate = 65 gpcpd (98 persons) (4.25) + 812 gpd = 27,885 gpd
= 19.36 gpm
= 0.0431 cfs
Design Report - Page 6 of 8
The capacity of an 8-inch main is checked using Manning’s Equation:
Qfull = (1.486/0.013)AR2/3S1/2
For an 8-inch PVC main:
Manning's n = 0.013 for PVC Pipe
Minimum Slope = 0.004 ft/ft
A = area = (3.14/4)d 2 = (3.14/4)(8/12)2 = 0.34907 ft2
P = perimeter = 2(3.14)r = 2(3.14)(4/12) = 2.0944 ft
R = hydraulic radius = A/P = 0.34907/2.0944 = 0.16667 ft
R2/3 = 0.30105 ft
S = 0.004 ft/ft
S1/2 = 0.0632 ft/ft
Qfull = (1.486/0.013)(0.34907)(0.30105)(0.0632) = 0.7592 cfs
Connection:
Q/Qfull = 0.0431 /0.7592 = 0.0568 or 5.68%
Based on these calculations, an 8-inch sewer line has adequate capacity to carry the design flows
for the subdivision.
Design Report - Page 7 of 8
APPENDIX A
WATERCAD MODEL
Scenario Summary Report
Scenario: Base
Scenario Summary
1ID
BaseLabel
Notes
Base Active TopologyActive Topology
Base PhysicalPhysical
Base DemandDemand
Base Initial SettingsInitial Settings
Base OperationalOperational
Base AgeAge
Base ConstituentConstituent
Base TraceTrace
Base Fire FlowFire Flow
Base Energy CostEnergy Cost
Base TransientTransient
Base Pressure Dependent DemandPressure Dependent Demand
Base Failure HistoryFailure History
Base SCADASCADA
Base User Data ExtensionsUser Data Extensions
Base Calculation OptionsSteady State/EPS Solver Calculation
Options
Base Calculation OptionsTransient Solver Calculation Options
Hydraulic Summary
Steady StateTime Analysis Type TrueUse simple controls during
steady state?
Hazen-WilliamsFriction Method FalseIs EPS Snapshot?
0.001Accuracy 12:00:00 AMStart Time
40Trials Fire FlowCalculation Type
Page 1 of 127 Siemon Company Drive Suite 200 W
Watertown, CT 06795 USA +1-203-755-1666
5/7/2019
WaterCAD CONNECT Edition Update 1
[10.01.00.72]
Bentley Systems, Inc. Haestad Methods Solution
Center180805 The Nest PUD WaterCAD Model.wtg
Pump Definition Detailed Report: HYD 1985
Element Details
49ID Notes
HYD 1985Label
Pump Curve
Head(ft)Flow(gpm)
221.540
207.691,284
196.151,781
184.622,181
173.082,526
161.542,835
150.003,117
138.463,379
126.923,625
115.383,858
103.854,079
92.314,290
80.774,493
69.234,688
57.694,876
46.155,059
34.625,236
23.085,408
11.545,576
0.005,739
Pump Efficiency Type
Best
Efficiency
Point
Pump Efficiency Type
%100.0Motor Efficiency
%100.0BEP Efficiency FalseIs Variable Speed Drive?
gpm0BEP Flow
Transient (Physical)
lb·ft²0.000Inertia (Pump and Motor)SI=25,
US=1280Specific Speed
rpm0Speed (Full)TrueReverse Spin Allowed?
Page 1 of 227 Siemon Company Drive Suite 200 W
Watertown, CT 06795 USA +1-203-755-1666
5/7/2019
WaterCAD CONNECT Edition Update 1
[10.01.00.72]
Bentley Systems, Inc. Haestad Methods Solution
Center180805 The Nest PUD WaterCAD Model.wtg
Pump Definition Detailed Report: HYD 1985
Page 2 of 227 Siemon Company Drive Suite 200 W
Watertown, CT 06795 USA +1-203-755-1666
5/7/2019
WaterCAD CONNECT Edition Update 1
[10.01.00.72]
Bentley Systems, Inc. Haestad Methods Solution
Center180805 The Nest PUD WaterCAD Model.wtg
Scenario: Base
P-3P-4P-5P-7P-1Page 1 of 127 Siemon Company Drive Suite 200 W
Watertown, CT 06795 USA +1-203-755-1666
1/24/2020
WaterCAD CONNECT Edition Update 1[10.01.00.72]Bentley Systems, Inc. Haestad Methods Solution Center180805 The Nest PUD WaterCAD Model.wtg
FlexTable: Pipe Table
Headloss
Gradient
(ft/ft)
Hydraulic
Grade (Stop)
(ft)
Hydraulic
Grade
(Start)
(ft)
Velocity
(ft/s)
Flow
(gpm)
Minor Loss
Coefficient
(Unified)
Hazen-Williams
C
MaterialDiameter
(in)
Length (User
Defined)
(ft)
Label
0.0004,975.474,975.470.0000.390130.0Ductile Iron8.022P-6
0.0004,975.474,975.470.0691.580130.0Ductile Iron8.0521P-7
0.0004,754.004,754.000.00350.000150.0PVC999.01P-1
0.0004,975.514,975.520.22351.880130.0Ductile Iron8.0430P-2
0.0004,975.474,975.470.0000.000130.0Ductile Iron6.010P-5
0.0004,975.494,975.510.22352.260130.0Ductile Iron8.0380P-3
0.0004,975.474,975.490.22352.860130.0Ductile Iron8.0406P-4
0.0004,975.494,975.490.0000.000130.0Ductile Iron6.028P-8
Page 1 of 127 Siemon Company Drive Suite 200 W Watertown, CT 06795 USA
+1-203-755-1666
1/24/2020
WaterCAD CONNECT Edition Update 1
[10.01.00.72]Bentley Systems, Inc. Haestad Methods Solution Center180805 The Nest PUD WaterCAD Model.wtg
Fire Flow Node FlexTable: Fire Flow Report
Junction w/
Minimum
Pressure
(System)
Pressure
(Calculated Zone
Lower Limit)
(psi)
Pressure
(Zone Lower
Limit)
(psi)
Pressure
(Calculated
Residual)
(psi)
Pressure
(Residual
Lower Limit)
(psi)
Flow (Total
Available)
(gpm)
Flow (Total
Needed)
(gpm)
Fire Flow
(Available)
(gpm)
Fire Flow
(Needed)
(gpm)
Label
DJ-222020202,6031,5002,6031,500HYD 2
DJ-219020202,2521,5002,2521,500HYD-1
Page 1 of 127 Siemon Company Drive Suite 200 W Watertown, CT 06795 USA
+1-203-755-1666
1/24/2020
WaterCAD CONNECT Edition Update 1
[10.01.00.72]Bentley Systems, Inc. Haestad Methods Solution Center180805 The Nest PUD WaterCAD Model.wtg
FlexTable: Junction Table
Pressure
(psi)
Hydraulic
Grade
(ft)
Demand
(gpm)
Demand CollectionElevation
(ft)
Label
934,975.4725<Collection: 1 items>4,760.00DJ-1
914,975.479<Collection: 1 items>4,765.00DJ-2
944,975.490<Collection: 0 items>4,757.17HYD 2
934,975.470<Collection: 0 items>4,760.00HYD-1
964,975.510<Collection: 0 items>4,754.50J-2
924,975.470<Collection: 0 items>4,762.00J-4
944,975.490<Collection: 0 items>4,757.17J-8
Page 1 of 127 Siemon Company Drive Suite 200 W
Watertown, CT 06795 USA +1-203-755-1666
1/24/2020
WaterCAD CONNECT Edition Update 1
[10.01.00.72]
Bentley Systems, Inc. Haestad Methods Solution
Center180805 The Nest PUD WaterCAD Model.wtg
Design Report - Page 8 of 8
APPENDIX B
DEMAND JUNCTION MAP &
SANITARY SEWER MAP