HomeMy WebLinkAboutDrainage Reports - 05/21/2008 (4)City of Ft. Collins Approyo Plans
Approved By
Date S/z+la $
Final Drainage and Erosion Control
Study for
Harmony Technology Park
Site Master Plan
Fort Collins, Colorado
Prepared for:
MAV Development
303 Detroit Street, Suite 301
Ann Arbor, Michigan 48104
Prepared by
Stantec Consulting, Inc.
209 South Meldrum
Fort Collins, Colorado 80521
(970) 482-5922
$tantEC
Final
Drainage and Erosion Control Study
Harmony Technology Park
Site Master Plan
Fort Collins, Colorado
May 19, 2008
'
Stankc Consulting Inc
209 South Meldrum Street
'
Port Collins CO 80521-2603
Tel: (970) 482-5922 Fax: (970) 482-6368
stantec.com
StailfieC
May 19, 2008
Mr. Basil Harridan
City of Fort Collins
Water Utilities--Stormwater
'
700 Wood Street
Fort
Collins, Colorado 80521
IRE: Final Drainage and Erosion Control Study for Harmony Technology Park Site Master
Plan
Dear Basil:
We are pleased to submit to you, for your review and approval, this Final Drainage and Erosion
Control Study for Harmony Technology Park Site Master Plan. All computations within this study
have been completed in compliance with the City of Fort Collins Storm Drainage Design Criteria.
tWe appreciate your time and consideration in reviewing this submittal. Please call if you have any
questions.
' Respectfully,
Stantec
' Prepared by:
1
Brad Kuglet V _ Anthony G. Willkomm, P.E.
t Project Engineer Project Manager
TABLE OF CONTENTS
I) ESCRIPTION PAGE
I. GENERAL LOCATION AND DESCRIPTION
A. LOCATION 1
B. DESCRIPTION OF PROPERTY 1
II. DRAINAGE BASINS
A. MAJOR BASIN DESCRIPTION
1
B. SUB -BASIN DESCRIPTION
I-2
III.
DRAINAGE DESIGN CRITERIA
A. REGULATIONS
2
B. DEVELOPMENT CRITERIA REFERENCE AND CONSTRAINTS
2
C. HYDROLOGICAL CRITERIA
2
D. HYDRAULIC CRITERIA
2
IV,
DRAINAGE FACILITY DESIGN
A. GENERAL CONCEPT
3
B. EXISTING SPECIFIC DETAILS
34
C. PROPOSED SPECIFIC DETAILS
4-5
V.
STORM WATER QUALITY
A. GENERAL CONCEPT
6
B. SPECIFIC DETAILS
6
VI.
EROSION CONTROL -,
A. GENERAL CONCEPT
6
VIL CONCLUSIONS
A.
COMPLIANCE WITH STANDARDS 6
B.
DRAINAGE CONCEPT 7
C.
STORM WATER QUALITY 7
D.
EROSION CONTROL CONCEPT 7
REFERENCES 8
APPENDIX
PAGE
VICINITY MAP A
RATIONAL METHOD HYDROLOGY B
SWMM POND SIZING AND EPA SWMM C
POND SIZING CALCULATIONS: RATING CURVES, WQCV D
SWMM AND RATIONAL EXHIBITS E
I
PRELIMINARY DRAINAGE AND EROSION CONTROL STUDY
FOR HARMONY TECHNOLOGY PARK SITE MASTER PLAN
' FORT COLLINS, COLORADO
GENERAL LOCATION AND DESCRIPTION
A. Location
' The Harmony Technology Park is located south of Harmony Road and east of Ziegler
Road in southeastern Fort Collins, Colorado. The site is shown on the Vicinity Map
' in Appendix A. More particularly, the site is situated in the northwest quarter of
Section 4, Township 6 North, Range 68 West of the Sixth P.M., City of Fort Collins,
Larimer County, Colorado.
' B. Description of Property
' Harmony Technology Park Site Master Plan (HTPSMP) consists approximately of
120 acres. The development will consist mostly of office, light industrial and
commercial buildings. The majority of the property currently consists of fallow
' farmland with tall grass vegetation. The site generally slopes in a southeasterly
direction at approximately 0.5%-1.0%.
' II. DRAINAGE BASINS ..
' A. Major Basin Description
The HTPSMP lies within the McClellands Basin. The project drainage is modeled in
the East Harmony Portion of McClellands Creek Master Drainage Plan (August
1999).
' B. Existine Sub -Basin Description
' Historic drainage patterns on the subject site are in a southeasterly direction.
Existing flows from the site flow overland to Lady Moon Drive, where there is a
series of small detention ponds and outlet pipes into a main storm line, 24" to 3611
,
' that runs south down Lady Moon drive. Flow is then routed into a 53" x 83"
elliptical pipe and piped east down Rock Creek Drive. Flows are eventually released
into the Fossil Creek Inlet Ditch.
I
' The anticipated off -site runoff from the adjacent property and roadways surrounding
the HTPSMP will be outflow from the existing Intel Pond A. HTP First Filing and
existing overland and gutter flows from Harmony Road, Lady Moon Drive and Rock
Creek Drive. Currently the 100-year overflow of 4.9 cfs from Intel discharges into an
open swale and flows west to east toward Lady Moon Drive. Flow is routed south
through a open ditch to an existing detention pond and released through an existing
15" pipe into the existing 24" pipe running south down Lady Moon Drive.
' Additional details on existing conditions are provided in section IV. B.
l Il. DRAINAGE BASIN CRITERIA
A. Reeulations
' The City of Fort Collins Storm Drainage Design Criteria is being used for the subject
site.
B. Development Criteria Reference and Constraints
' The criteria and constraints from The East Harmony Portion of McClellands Basin
100-Year Master Plan dated August 1999 by Icon Engineering will be utilized in this
Drainage Study. The Harmony Technology Park Site Master Plan is currently being
tutilized as fallow agricultural land.
C. Hydrologic Criteria
' The Rational Method was used for determining surface runoff for the existing project
' site. The 10-year and 100-year storm event criteria, obtained by the City of Fort
Collins, were used in calculating runoff values. These calculations and criteria are
included in Appendix B of this study.
' The City of Fort Collins Storm Drainage Criteria requires water quality and detention
of the 100-year design storm event, with a 10-year historic release rate for this site.
The allowable release rate from the on -site detention ponds is 0.5 cfs/acre for the
100-year event and 0.2 cfs/acre for the 10-year storm event, in accordance with the
McClellands Master Drainage Plan. The proposed ponds have been sized utilizing
EPA SWMM and ModSWMM. The input and output data are included in
Appendix C.
D. Hydraulic Criteria
All calculations within this study have been prepared in accordance with the City of
Fort Collins Storm Drainage Criteria and are included in the appendices.
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IV. DRAINAGE FACILITY DESIGN
A. General Concept
The purpose of this study is to size the proposed detention ponds and present general
drainage concepts for HTPSMP, for use when future development of the site is
reviewed. It is important to note that all storm infrastructure was designed for the
100-year storm, with an 80% impervious value being used for all basins in the
SWMM model analysis.
HTPSMP has been divided into six S WMM basins, (see S WMM Drainage Exhibit in
back pocket of this study for locations). Runoff from these basins will be routed via
curb and gutter, swales and storm drains to the proposed detention facilities in the
future.
' The proposed ponds have been sized to provide water quality and extended detention
for the site, while also providing controlled releases into the storm drain system.
Flows are conveyed to the southeast corner of the site. The site area is approximately
120 acres. At 0.5 cfs per acre the site can release 60 cfs at the final discharge point in
Rock Creek Drive. All ponds are design with one foot of freeboard.
B. Existina Specific Details
The flows from the entire site have been calculated as an existing condition with the
rational method.
Basins OSI, OS2
' Basins OS 1, OS2 convey storm flow from a small portion of the north side of Rock
Creek Drive and the east and west sides of Lady Moon Drive. Flow is conveyed via
' curb and gutter and is captured by two existing Type R Inlets and released into the
ditch on the east side of Lady Moon Drive.
' Basin EX-1
Basin EX-1 conveys its flows southeast towards design point EX-1 in its existing
overland flow condition, where flow is treated and released to existing storm pipe in
Lady Moon Drive.
Basins EX-2, EX-3
' Basins EX-2, EX-3, convey flow from the east and west sides of Lady Moon Drive
and is captured in Combination Type 13 on grade Inlets. From there is discharged
into an existing detention pond and released at Design Point EX-1.
Basin EX-4
' Basin EX-4 conveys its flows southeast towards design point EX4 in its existing
overland flow condition. Flow from a road side ditch is also routed east to an
existing inlet and discharged into the existing detention pond. Here flow is treated
tand release into existing pipe in Lady Moon Drive.
Basins EX-5, EX-6
Basins EX-5, EX-6, convey flow from the east and west sides of Lady Moon Drive
and is captured in Type R Inlets. From there is discharged into an existing detention
pond and released at Design Point EX-4.
Basin EX-7
Basin EX-7 conveys its flows southeast towards design point EX-7 in its existing
'
overland flow condition, where flow is treated and release to existing storm pipe in
Lady Moon Drive.
Basin EX-8
Basin EX-8 conveys its flow from a high point in Ziegler Road, south to Rock
Creek Drive. Flow travels east via curb and gutter to an existing 15' Type R Inlet
at EX-8 and discharges to EX-7.
'
C. Proposed Specific Details
' Water quality and detention is required and will be provided for the Harmony
Technology Park site. The detention for the site is a comprehensive plan that
relays storm water to six proposed detention ponds. The entire site was
' modeled as being 80% impervious and detention ponds sized using
MODSWMM anti EPASWMM.
' Pond110
Pond 110 will capture flow from 32.9 acres of the site and provides 8.08
acre/feet of storage including water quality. The controlled release rate out of
' the pond will be 15 cfs into a 24" pipe that will be routed into the existing 36"
storm pipe in Lady Moon Drive.
Pond101
Pond 101 will capture flow from 6.9 acres of the site and provides 1.53
acre/feet of storage including water quality. The controlled release rate out of
the pond will be 5 cfs into a 18" pipe that will be routed to a proposed 30" pipe
in Technology Parkway. Here, flows will combine with the existing 100-yr
' outlet flow from Pond A on the Intel Site.
1 4
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' Pond 201
Pond 201 will capture flow from 23.0 acres of the site and provides 5.76
' acre/feet of storage including water quality. The controlled release rate out of
the pond will be 10 cfs into a 18" pipe that will be routed to a proposed 30"
pipe in Technology Parkway. Here flows will combine with outflow from Pond
101 and the existing 100-yr outlet flow from Pond A on the Intel Site.
Pond 501
Pond 501 will capture flow from 16.5 acres of the site and provides 4.14
acre/feet of storage including water quality. The controlled release rate out of
the pond will be 7.5 cfs into a 18" pipe that will be routed to a proposed 30"
'
pipe in Technology Parkway. Here flows will combine with outflow from Pond
201, Pond 101 and the existing 100-yr outlet flow from Pond A on the Intel
'
Site. The combined flows will be diverted east in the existing 30" storm in
Rock Creek Drive.
Pond 600
Pond 600 will capture flow from 12.4 acres of the site and provides 2.61
acre/feet of storage including water quality. The controlled release rate out of
the pond will be 10 cfs into a proposed 18" pipe that will be routed to Pond
301. The release rate and storage for this pond was achieved by running
'
EPASWMM for Ponds 600 and 301 in series.
Pond 301
Pond 301 will capture flow from 29.0 acres of the site and provides 8.65
acre/feet of storage including water quality. The controlled release rate out of
the pond will be P2 cfs into a proposed 24" pipe that will be routed to an
existing 24" pipe in Lady Moon Drive. The release rate and storage for this
pond was achieved by running EPASWMM for Ponds 600 and 301 in series.
The combined outflow from Ponds 600 and 301 will be conveyed south in the
'
existing 30" storm in Lady Moon Drive.
The SWMM models and data are located in Appendix C. Mapping is shown in
'
Appendix E.
NOTE:
Per discussion with City of Fort Collins Stormwater Department, any lot
development that requires detention and water quality will facilitate construction of
'
the entire pond for that basin, as shown in the SWMM exhibit and per required
SWMM model volumes. No partial ponds will be built unless approved by City of
Fort Collins Stormwater Department. The purpose of this is to mitigate continued
'
regrading and continued disturbance of erosion control measures and
development
seeding/landscaping of the ponds, as new phases of occur.
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STORM WATER QUALITY
A. General Concept
The State of Colorado requires Stormwater Management Plans as part of their permit
process. The Harmony Technology Park site development is anticipating
construction beginning in June of 2008. Therefore this study has sought to find
various Best Management Practices for the treatment of storm water runoff that could
be implemented in the construction phase of the project.
B. Specific Details
Best Management Practices (BMP) for the treatment of storm water runoff has
been incorporated into the design for this project. This includes extended
detention and grass lined swales. Best management practices shall be provided
with each phase of development or as sites develop within the Master Plan.
VI. EROSION CONTROL
A. General Concept
The Harmony Technology Park site lies within the Moderate Rainfall Erodibility
Zone and the Moderate Wind Erodibility Zone per the City of Fort Collins zone
maps. The potential exists for erosion problems during construction, and after
construction until the disturbed ground is re -vegetated or paved.
Erosion Control devices shall be used in the construction of each phase that will be
completed to make up the Harmony Technology Park. Erosion Control Performance
Standards shall also be completed with each construction phase along with a
construction schedule showing the overall time frame for construction activities.
VII. CONCLUSIONS
A. Compliance with Standards
' All computations within this study have been completed in compliance with the City
of Fort Collins Storm Drainage Design Criteria. The City of Fort Collins Stormwater
Utility will not maintain the on -site storm drainage facilities within the Harmony
' Technology Park Site. The owners of the Harmony Technology Park Site will
maintain their on -site storm drainage facilities on a regular basis.
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C.
tU
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Drainaae Concept
The proposed drainage concepts presented in this study and shown on the final utility
plans adequately provide for the transmission of developed on -site runoti to the
proposed detention ponds. As site develops the combination of on -site street
capacities and the on -site storm sewer system will provide for the developed flows to
reach the proposed detention ponds. The sizes, locations and release rates of these
ponds will allow the Harmony Technology Park to develop in conformance with the
McClellands Basin Drainage Master Planning concepts accepted by the City of Fort
Collins.
If groundwater is encountered at the time of construction, a Colorado Department of
Health Construction Dewatering Permit will be required.
Storm Water Ouality
Sediment basin traps will be provided within the on -site detention ponds in each
phase of construction. These traps will allow storm water pollutants an opportunity
to be filtered out of the storm water as the storm water carries the pollutants across
the site. Periodic maintenance may be required to remove sediment deposits as they
accumulate in the on -site detention ponds.
Erosion Control Concept
Erosion control concepts will need to adequately provide for the control of wind
and rainfall erosion from Harmony Technology Park Site. Through the
construction of the proposed phases performance standards will be met per the City
of Fort Collins Regulations.
7
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1.
2.
EiA
5.
W
7
Storm Drainage Design Criteria and Construction Standards by the City of Fort
Collins, Colorado, May 1984, Revised January 1997.
Erosion Control Reference Manual for Construction Sites by the City of Fort Collins,
Colorado, January 1991, Revised January 1997.
East Harmony Portion of McClellands Basin 100-Year Master Plan, by Icon Inc.,
Fort Collins, Colorado, August 1999.
Final Drainage and Erosion Control Report, Harmony Technology Park 2Id Filing,
Prepared by JR Engineering, June 20, 2001.
2004 High School Final Drainage and Erosion Control Study, Poudre School District
R-1, Prepared by Nolte Associates, Inc., June 24, 2002
Final Drainage and Project Development Report for Harmony Technology Park First
Filing, Prepared by Sear -Brown, January 23, 1998,
The Urban Storm Drainage Criteria Manual (published by the Urban Drainage and
Flood Control District — Denver, Colorado — June 2001).
0
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APPENDIX A
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VICINITY MAP
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VICINITY MAP
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APPENDIX B
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RATIONAL
METHODHYDROLOGY
i
Existing Weighted Runoff Coefficients
Harmony Technology Park Site
18771OW
This sheet calculates the composite "C" values for the Rational Method.
EX-2
0.95
0,25
24,158
0.56
20.534
0.47
85
15
0.85
EX-3
0.95
0.25
36,795
0.84
31,275
0.72
85
15
0.85
EX-4
0.96
0.25
478,575
10.99
47,858
1.10
10
90
0.32
EX-5
0.95
0.25
23.637
0.54
20,092
0.46
85
15
0.85
EX-6
0.95
0.25
42,065
0.97
35.756
0.82
85
15
0.86
EX-7
0.96
0.25
2,074,707
47.63
207,471
4.76
10
90
0.32
EX-8
0.95
0.25
141.438
3.25
120,222
2.76
85
15
0.85
OS-1
0.96
0.25
64,326
1.48
54,677
1.26
85
15
0.85
OS-2
0.95
0.25
44,688
1.03
37.985
0.87
85
15
0.85
SITE
0.95
0.25
5.416.889
124
824.519-
19
15.2
85
0.3& -
3:38 PM
Tho Sear -Brown Group 3113/2008
TIME OF CONCENTRATION
10 year design storm
Harmony Technology Park Site
187710640
1.87(1.1- CC(),I-D
= Se.3v
t°= t'+t'
Cr = 1.00
SUB -BASIN DATA
INITIAL/OVERLAND TIME
TRAVEL TIME
FINAL
REMARKS
BASIN AREA C
LENGTH
SLOPE
4
LENGTH CHANNEL
SLOPE
VELOCITY
tL
t°
NO. (ac)
(8)
N
(min)
(R)
TYPE(a)
(°k)
(ftts)
(min)
(min)
1 2 3
4
5
6
7
8
10
12
13
EX-1 57.08 0.32
500
1
32.6
2000
GW
1
1.54
21.7
54.3
EX-2 0.55 US
50
2
2.7
810
PA
O6
1,47
9.2
11.9
EX-3 0.84 0.85
50
2
2.7
810
PA
0.6
1.47
9.2
11.9
EX-4 10.99 0,32
500
1
32.6
1000
GW
1
1.54
10.8
43.4
EX-5 0.54 0.86
50
2
2.7
460
PA
0.6
1.47
5.2
7.9
EX-6 0.97 0.86
50
2
2.7
460
PA
0.6
1.47
5.2
7.9
EX-7 47.63 0.32
500
1
32.6
2150
GW
1
1.54
23.3
56.9
EX-8 3.25 0.85
80
2
3.4
2500
PA
0.6
1.47
28.4
31.8
OS-1 1.48 0.85
25
2
1.9
650
PA
0.6
1.47
7.4
9.3
OS-2 1.03 0.85
25
2
1.9
640
PA
0.6
1.47
7.3
9.2
Note:
a) Codes the channel type for velocity calculations.
PA = Paved, PL = Pasture & Lawns, GW = Grassed Waterway
338 PM
The Sear B,own Group 311312008
TIME OF CONCENTRATION
100 year design storm
Harmony Technology Park Site
187710640
1.87(I.I - CCr ),/D
to= tl+tt
CI. 1.25
SUB -BASIN DATA
INITIFWOVERLAND TIME
TRAVEL TIME
FINAL
REMARKS
BASIN
AREA C
LENGTH
SLOPE
L
LENGTH
CHANNEL
SLOPE
VELOCITY
k
I.
NO.
(ac)
(fi)
N
(min)
(ft)
TYPE(a)
N
(ft/s)
(min)
(min)
1
2 3
4
5
6
7
8
10
12
13
EX-1
57.08 0.32
500
1.0
29.3
2000
GW
1.0
1.54
21.7
50.9
EX-2
0.55 0.86
50
2.0
1.0
810
PA
0.6
1.47
9.2
10.3
EX-3
0.84 0.85
50
2.0
1.0
810
PA
0.6
1.47
9.2
10.3
EX-4
10.99 0.32
500
1.0
29.3
1000
GW
1.0
1.54
10.8
40.1
EX-5
0.54 0.85
50
2.0
1.0
460
PA
0.6
1.47
5.2
6.3
EX-6
0.97 0.&5
50
2,0
1.0
460
PA
0.6
1,47
5.2
6.3
EX-7
47.63 0.32
500
1.0
29.3
2150
GW
1.0
1.54
23.3
52.5
EX-8
3.25 0.85
80
2.0
1.3
2500
PA
0.6
1.47
28.4
29.7
OS-1
1,48 0,85
25
2.0
0.7
650
PA
0.6
1.47
7.4
8.1
OS-2
1,03 0.85
25
2.0
0.7
640
PA
0.6
1A7
7.3
8.0
Note:
a) Codes the channel type for velocity calculations.
PA = Paved, PL = Pasture & Lawns, GW = Grassed Waterway
3:38 PM
The Sear -Brown Group W1312008
I
Rational Method
10 Year Design Storm
Harmony Technology Park Site
187710640
Routing Flow Time (tj
Runoff
Street
Pipe
Design Point
Basins
4
Length Type Slope Velocity Travel
ipe
Travel
I,
C
Intensity
Area
rce
Runoff
er
Runoff
o a
Runoff
Capacity Design Velocity
Slope
apace
Manning's Roughness SiZe Flow Depth Capacity
esign
Flow
or ma
Flow Depth
verage
Velocity
Location
(min)
(ft) (a) (%) (fVs) (min)
(min)
(min)
(In/hr)
(ac)
(cfs)
(cfs)
(cfs)
(cfs) (Pos) WS)
M)
"n" (in) (in) (cfs)
(cfs)
(in)
ON
Remarks
EX-1
EX-1
54.3
- 0.0
54.3
0.32
1.49
57.08
27.28
0.00
27.26
EX-2
EX-2
11.9
- 0.0
11.9
0.85
3.52
0,55
1.65
0.00
1.65
EX-3
EX-3
11.9
- 0.0
11.9
0.85
3.52
0.84
2.51
0.00
2.51
EX-4
EX-4
43.4
- 0.0
43.4
0.32
1.73
10.99
6.08
0.00
6.08
EX-5
EX-5
7.9
- 0.0
7.9
0.85
4.16
0.54
1.91
0.00
1.91
EX-6
EX-6
7.9
- 0.0
7.9
0.85
4.16
0.97
3:39
0.00
3.39
EX-7
EX-7
55.9
- 0.0
55.9
0.32
1.46
47.63
22.33
0.00
22.33
EX-8
EX-8
31.8
- 0.0
31.8
0.85
2.13
3.25
5,85
0.00
5.85
OS-1
OS-1
9.3
- 0.0
9.3
0.85
3.90
1.48
4.86
0.00
4.86
OS-2
I OS-2 1
9.2
- 0.0
9.2
0,851
3.92
1,03 1
3,40
0,00
3.40
' Note:
a) Codes the channel type for velocity calculations.
PA = Paved, PL = Pasture & Lawns, GW = Grassed Waterway
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Me Sear -Brown Group 3:40 PM
3113/2008
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1
1
1
1
1
1
Rational Method
100 Year Design Storm
Harmony Technology Park Site
187710640
Routing Flow Time (tj
Runoff
Street
Pipe
Design Point
Basins
tc
Length Type Slope Velocity Travel
'pe
Travel
tc.
C
C'Ct
Intensity
Area
UIreCt
Runoff
Uther
Runoff
I otal
Runoff
Capacity
Design Velocity
Slope
apace y
Manning's Roughness Size Flow Depth Capacity
uesign
Flow
orma
Flow Depth
Average
Velocity
Location
(min)
(ft) (a) (%) (ftls) (min)
(min)
(min)
(inthr)
(ac)
(cfs)
(cfs)
(cfs)
(cfs)
(fus) (fus)
N
"n" (in)
EX-1
EX-1
50.9
- 0.0
50.9
0.32
0.40
3.19
57.08
72.86
0.00
72.86
(in) (cfs)
(ds)
(in)
(fus)
Remarks
EX-2
EX-2
10.3
- 0.0
10.3
0.85
1.00
7.64
0.55
4.24
0.00
4.24
EX-3
EX-3
10.3
- 0.0
10.3
0.85
1.00
7.64
0.84
6.45
0.00
6.45
EX-4
EX-4
40.1
- 0.0
40.1
0.32
0.40
3.73
10.99
16.41
0.00
16.41
EX-5
EX-5
6.3
- 0.0
6.3
0.85
1.00
9.24
0.54
5.01
0.00
5.01
EX-6
EX-6
6.3
- 0.0
6.3
0.85
1.00
9.24
0.97
8.92
0.00
8.92
EX-7
EX-7
52.5
- 0.0
52.5
0.32
0.40
3.12
47.63
59.53
0.00
59.53
EX-8
EX-8
29.7
- 0.0
29.7
0.85
1.00
4.54
3.25
14.75
0.00
14.75
OS-1
OS-1
8.1
-- 0.0
8.1
0.85
1.00
8,39
1.48
12.40
0.00
12.40
OS-2
OS-2
8.0
-- &0
8.0
0.85
1.00
8.44
1.03
8.66
0.00
8.66
Note:
a) Codes the channel type for velocity calculations.
PA = Paved, PL = Pasture & Lawns, GW = Grassed Waterway
The Seai-8rowr; 3ror,A 138 PM
3; i 312008
I
1
1
1
1
1
1
1
1
1
1
1
i
1
1
1
1
1
APPENDIX C
1
I
1
1
1
1
1 SWMM POND SIZING AND
1
1
1
1
1
1
1
1
1
1
1
1
EPA SWMM
1
Stantec
ENVIRONMENTAL PROTECTION AGENCY - STORM WATER MANAGEMENT MODEL - VERSION PC.1
DEVELOPED BY METCALF + EDDY, INC.
UNIVERSITY OF FLORIDA
WATER RESOURCES ENGINEEERS, INC. (SEPTEMBER 1970)
UPDATED BY UNIVERSITY OF FLORIDA (JUNE 1973)
HYDROLOGIC ENGINEERING CENTER, CORPS OF ENGINEERS
MISSOURI RIVER DIVISION, CORPS OF ENGINEERS (SEPTEMBER1974)
BOYLE ENGINEERING CORPORATION (MARCH 1985, JULY 1985)
*** ENTRY MADE TO RUNOFF MODEL ***
CASVVMM\HTPMasterFina1100 revised5-16-OB.out 1 Printed: 5/16/2008
Stentx
HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFinall00.IN STANTEC; 3/6/08
NUMBER OF TIME STEPS 720
INTEGRATION TIME INTERVAL (MINUTES) 1.00
1.0 PERCENT OF IMPERVIOUS AREA HAS ZERO DETENTION DEPTH
FOR 24 RAINFALL STEPS, THE TIME INTERVAL IS 5.00 MINUTES
FOR RAINGAGE NUMBER 1 RAINFALL HISTORY IN INCHES PER HOUR
1.00 1.14 1.33 2.23 2.84 5.49
1.72 1.06 1.00 .95 .91 .87
9.95 4.12 2.48 1.46
.84 .81 .78 .75
GASWMM\HTPMasterFina1100 revised5-16-08.out 2 Printed: 5/16/2008
'
HARMONY
TECHNOLOGY PARK
stantac
100-YEAR EVENT
FILE: HTPMasterFina1100.IN
STANTEC:
3/6/08
SUBAREA
GUTTER
WIDTH AREA
PERCENT
SLOPE
RESISTANCE
FACTOR
SURFACE STORAGE(IN)
INFILTRATION RATE(IN/HR)
GAGE
NUMBER
OR MANHOLE (FT) (AC)
IMPERV.
(FT/FT)
IMPERV.
PERV.
IMPERV.
PERV.
MAXIMUM
MINIMUM
DECAY RATE
'
NO
-2
0
.0 .0
.0
.0300
.016
.250
.100
.300
.51
.50
.00180
100
100
4591.0 32.9
80.0
.0200
.016
.250
.100
.300
.51
.50
.00180
1
401
101
1502.0 6.9
80.0
.0200
.016
.250
.100
.300
.51
.50
.00180
1
501
201
3343.0 23.0
80.0
.0200
.016
.250
.100
.300
.51
.50
.00180
1
600
600
2568.0 12.4
80.0
.0200
.016
.250
.100
.300
.51
.50
.00180
1
101
1
301
4210.0 29.0
80.0
.0201
.016
.250
.100
.300
.51
.50
.00181
'
801
501
2585.0 16.5
80.0
.0200
.016
.250
.100
.300
.51
.50
.00180
1
903
208
300.0 10.0
80.0
.0200
.016
.250
.100
.300
.51
.50
.00180
1
TOTAL NUMBER OF
SUBCATCHMENTS, 7
'
TOTAL TRIBUTARY
AREA (ACRES), 130.72
' HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFina1100.IN STANTEC: 3/6/08
1
t
1
HYDROGRAPHS ARE LISTED FOR THE FOLLOWING
TIME(HR/MIN) 600 601
0
1.
.0
.0
0
2.
.0
.0
0
3.
.0
.0
0
4.
.0
.1
O
5.
.0
.1
0
6.
.1
.1
0
7.
.4
.7
0
8.
1.5
2.6
0
9.
3.0
5.3
0
10.
4.6
8.2
0
11.
6.2
11.5
0
12.
7.9
15.0
0
13.
9.2
18.1
0
14.
10.3
20.7 ..
0
15.
11.1
22.9
0
16.
13.0
27.1
0
17.
15.7
33.1
0
18.
17.8
37.9
0
19.
19.2
41.6
0
20.
20.2
44.5
0
21.
22.0
48.7
0
22.
24.6
54.3
0
23.
26.4
58.7
0
24.
27.8
62.2
0
25.
28.9
64.9
0
26.
35.3
77.7
0
27.
45.6
98.7
0
28.
52.6
114.4
0
29.
57.2
125.6
0
30.
60.1
133.6
0
31.
73.7
161.9
0
32.
94.5
205.5
0
33.
106.3
234.1
0
34.
112.9
252.1
0
35.
116.6
263.5
0
36.
101.2
236.1
0
37.
77.9
189.2
0
38.
66.5
163.3
0
39.
60.3
147.9
0
40.
56.7
138.3
0
41.
50.7
124.3
0
42.
43.3
107.8
0
43.
38.9
97.1
0
44.
36.1
89.8
0
45.
34.3
84.7
0
46.
31.0
77.0
0
47.
26.9
67.7
0
48.
24.2
61.1
0
49.
22.3
56.4
0
50.
21.0
52.9
0
51.
19.7
49.4
2 SUBCATCHMENTS - AVERAGE VALUES WITHIN TIME INTERVALS
CASWMM\HTPMasterFina1100 revised5-16-08.out
3
Printed: 5/16/2008
Stantec
I
1
�l
I
LJ
1
1
1
1
C
52. 18.3 46.0
53. 17.3 43.4
54. 16.6 41.4
55. 16.1 39.9
56. 15.4 38.2
57. 14.7 36.3
58. 14.1 34.9
59. 13.7 33.7
0. 13.4 32.8
1. 13.0 31.9
2. 12.7 31.0
3. 12.4 30.3
4. 12.2 29.7
5. 12.0 29.2
6. 11.8 28.6
7. 11.6 28.1
B. 11.4 27.6
9. 11.3 27.2
10. 11.2 26.9
11. 11.0 26.5
12. 10.9 26.1
13. 10.7 25.7
14. 10.6 25.5
15. 10.5 25.2
16. 10.4 24.9
17. 10.3 24.6
18. 10.2 24.3
19. 10.1 24.0
20. 10.0 23.8
21. 9.9 23.6
22. 9.8 23.3
23. 9.7 23.1
24. 9.6 22.9
25. 9.5 22.7
26. 9.5 22.5
27. 9.4 22.2
28. 9.3 22.0
29. 9.2 21.9
30. 9.1 21.7
31. 9.1 21.5
32. 9.0 21.3
33. 8.9 21.1
34. 8.8 20.9
35. 8.8 20.8
36. 8.7 20.6
37. 8.6 20.4
38. 8.5 20.2
39. 8.4 20.0
40. 8.4 19.9
41. 8.3 19.7
42. 8.2 19.5
43. 8.2 19.4
44. 8.1 19.3
45. 8.1 19.2
46. 8.0 19.0
47. 8.0 18.9
48. 7.9 18.7
49. 7.9 18.6
50. 7.8 18.5
51. 7.8 18.4
52. 7.7 18.2
53. 7.6 18.1
54. 7.6 18.0
55. 7.6 17.9
56. 7.5 17.8
57. 7.5 17.6
58. 7.4 17.5
59. 7.4 17.4
0. 7.3 17.3
1. 6.5 15.7
2. 5.2 13.1
3. 4.3 11.1
4. 3.5 9.5
5. 3.0 8.2
6. 2.5 7.1
7. 2.2 6.3
B. 1.9 5.5
9. 1.7 4.9
10. 1.5 4.4
11. 1.3 4.0
12. 1.2 3.6
13. 1.1 3.3
14. 1.0 3.0
15. .9 2.7
16. .8 2.5
17. .7 2.3
18. .7 2.2
19. .6 2.0
20. .6 1.9
21. .5 1.7
C:\SWMM\HTPMasterFina1100 revised5-16-08.out
Printed: 5/16/2008
stantec
11
�I
1
2
22.
.5
1.6
2
23.
.5
1.5
2
24.
.4
1.4
2
25.
.4
1.3
2
26.
.4
1.2
2
27.
.3
1.2
2
28.
.3
1.1
2
29.
.3
1.0
2
30.
.3
1.0
2
31.
.3
.9
2
32.
.2
.9
2
33.
.2
.8
2
34.
.2
.8
2
35.
.2
.7
2
36.
.2
.7
2
37.
.2
.7
2
38.
.2
.6
2
39.
.2
.6
2
40.
.2
.6
2
41.
1
.5
2
42.
1
.5
2
43.
1
.5
2
44.
1
.5
2
45.
1
.5
2
46.
1
.4
2
47.
1
.4
2
48.
1
.4
2
49.
1
.4
2
50.
1
.4
2
51.
1
.3
2
52.
1
.3
2
53.
1
.3
2
54.
1
.3
2
55.
1
.3
2
56.
1
.3
2
57.
1
.3
2
58.
1
.3
2
59.
1
.2
3
0.
1
.2
3
1.
1
.2
3
2.
1
.2
3
3.
.0
.2
3
4.
.0
.2
3
5.
.0
.2
3
6.
.0
.2
3
7.
.0
.2
3
8.
.0
.2
3
9.
.0
.2
3
10.
.0
.2
3
11.
.0
.2
3
12.
.0
.1
3
13.
.0
.1
3
14.
.0
.1 ..
3
15.
.0
.1
3
16.
.0
.1
3
17.
.0
.1
3
18.
.0
.1
3
19.
.0
.1
3
20.
.0
.1
3
21.
.0
.1
3
22.
.0
.1
3
23.
.0
.1
3
24.
.0
.1
3
25.
.0
.1
3
26.
.0
.1
3
27.
.0
.1
3
28.
.0
.1
3
29.
.0
.1
3
30.
.0
.1
3
31.
.0
.1
3
32.
.0
.1
3
33.
.0
.1
3
34.
.0
.1
3
35.
.0
.1
3
36.
.0
.1
3
37.
.0
.1
3
38.
.0
.1
3
39.
.0
.1
3
40.
.0
.1
3
41.
.0
.1
3
42.
.0
.1
3
43.
.0
.1
3
44.
.0
.1
3
45.
.0
.1
3
46.
.0
.1
3
47.
.0
.1
3
48.
.0
.1
3
49.
.0
.0
3
50.
.0
.0
3
51.
.0
.0
C:\SWMM\HTPMasterFina1100 revised5-16-OB.out
5
Printed: 5/16/2008
Stentee
3
52.
.0
.0
3
53.
.0
.0
3
54.
.0
.0
3
55.
.0
.0
3
56.
.0
.0
3
57.
.0
.0
3
58.
.0
.0
3
59.
.0
.0
4
0.
.0
.0
4
1.
.0
.0
4
2.
.0
.0
4
3.
.0
.0
4
4.
.0
.0
4
5.
.0
.0
4
6.
.0
.0
4
7.
0
.0
4
B.
.0
.0
4
9.
.0
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4
10.
.0
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4
11.
.0
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4
12.
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4
13.
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4
14.
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4
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4
16.
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4
17.
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4
18.
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i
19.
.0
.0
20.
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4
21.
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4
22.
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4
23.
.0
.0
4
24.
.0
.0
4
25.
.0
.0
4
26.
.0
.0
4
27.
.0
.0
4
28.
.0
.0
4
29.
.0
.0
4
30.
.0
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4
31.
.0
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4
32.
.0
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4
33.
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4
34.
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4
35.
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4
36.
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4
37.
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4
38.
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4
39.
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4
40.
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4
41.
.0
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4
42.
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4
43.
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4
44.
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4
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4
48.
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49.
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4
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4
51.
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4
52.
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4
53.
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4
54.
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4
55.
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4
56.
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4
57.
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4
58.
.0
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4
59.
.0
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5
0.
.0
.0
5
1.
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5
2.
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3.
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4.
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5
5.
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5
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5
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5
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5
16.
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5
17.
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5
18.
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5
19.
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5
20.
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C:\SWMM\HTPMasterFina1100 revised5.16-08.out 6 Printed: 5/16/2008
Stantac
I
5
21.
.0
.0
5
22.
.0
.0
5
23.
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5
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5
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5
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5
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51.
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6
0.
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6
1.
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6
2.
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6
3.
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6
4.
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6
5.
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6
6.
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6
7.
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45.
.0
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6
46.
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47.
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48.
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49.
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6
50.
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C:\SWMM\HTPMasterFinallOO
revised5-16-08.out
7
Printed: 5/16/2008
Stantee
I
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C:\SWMM\HTPMasterFinallOO revised5-16-OB.out
8
Printed: 5/16/2008
Stentec
I
I
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i
i
f
E
F
f
F
f
f
f
f
E
f
f
f
F
F
E
f
f
E
E
f
f
E
E
E
c
c
S
5
5
5
5
9
9
9
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9
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9
9
9
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9
9
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9
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9
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9
9
9
9
9
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21.
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58.
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59.
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1.
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2.
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3.
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4.
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5.
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6.
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7.
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B.
.0
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9.
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10.
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11.
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12.
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13.
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48.
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C:\S1
VMM\HTPMasterFina1100 revised5-16-OB.out
pi
Printed: 5/16/2008
Stantee
9
50.
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9
51.
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9
52.
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10
0.
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10
1.
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10
2.
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10
3.
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10
4.
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10
5.
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10
6.
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10
7.
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10
8.
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10
9.
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10
10.
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10
11.
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10
12.
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10
13.
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10
14.
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10
15.
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10
16.
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10
17.
..0
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10
18.
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10
19.
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10
20.
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10
21.
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10
22.
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10
23.
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10
24.
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10
25.
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10
26.
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10
27.
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10
28.
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10
29.
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10
30.
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32.
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33.
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36.
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37.
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10
38.
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10
39.
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40.
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10
41.
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10
42.
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10
43.
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10
44.
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10
45.
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10
46.
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10
47.
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10
48.
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10
49.
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10
50.
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10
51.
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10
52.
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10
53.
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10
54.
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10
55.
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10
56.
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10
57.
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10
58.
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10
59.
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11
0.
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11
1.
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11
2.
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11
3.
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11
4.
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11
5.
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11
6.
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11
7.
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11
S.
.0
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11
9.
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11
10.
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11
11.
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11
12.
.0
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11
13.
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11
14.
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11
15.
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16.
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18.
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C:\SWMM\HTPMasterFine1100 revised5-16.08.out 10 Printed: 5/16/2008
Stantac
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
43.
44.
45.
46.
47.
48.
49.
50.
51.
52.
53.
54.
55.
56.
57.
58.
59.
0.
C:\SWMM\HTPMasterFina1100 revised5-16-08.out 11 Printed: 5/16/2008
Stantec
HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFina1100.IN STANTEC; 3/6/08
*** CONTINUITY CHECK FOR SUBCATCHMEMT ROUTING IN UDSWM2-PC MODEL ***
WATERSHED AREA (ACRES) 130.720
TOTAL RAINFALL (INCHES) 3.669
TOTAL INFILTRATION (INCHES) .250
TOTAL WATERSHED OUTFLOW (INCHES) 3.321
TOTAL SURFACE STORAGE AT END OF STROM (INCHES) .098
ERROR IN CONTINUITY, PERCENTAGE OF RAINFALL .000
CASVVMM\HTPMasterFina1100 revised5-16-08.out 12 Printed: 5/16/2008
Stanteo
HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFina1100.IN STANTEC; 3/6/08
WIDTH
INVERT
SIDE SLOPES
OVERBANK/SURCHARGE
GUTTER
GUTTER
NDP
NP
OR DIAM LENGTH
SLOPE
HORIZ TO
VERT
MANNING
JK
NUMBER
CONNECTION
(FT) (FT)
(FT/FT)
L
R
N
210
205
0
2
PIPE
2.0 600.
.0030
.0
.0
.013
1
205
206
0
2
PIPE
2.5 1330.
.0030
.0
.0
.013
1
206
207
0
2
PIPE
2.5 1300.
.0030
.0
.0
.013
1
208
207
0
3
.1 1.
.0010
.0
.0
.001
1
207
511
0
3
.1 1.
.0010
.0
.0
.001
1
110
510
9
2
PIPE
.0 0.
.0010
.0
.0
.001
0
RESERVOIR
STORAGE IN
ACRE-FEET
VS SPILLWAY OUTFLOW
.0
.0
.1
6.0 .2 8.5
1.9
10.4
3.4
12.1
13.5
7.4
14.8
10.0
15.9 12.9 17.0
600
301
6
2
PIPE
.0 0.
.0010
.0
.0
.001
0
RESERVOIR
STORAGE IN
ACRE-FEET
VS SPILLWAY OUTFLOW
.0
.0
.1
4.5 .5 6.3
1.2
7.8
1.9
8.9
10.0
211
510
0
2
PIPE
2.5 1140.
.0030
.0
.0
.013
1
510
511
0
3
.1 1.
.0010
.0
.0
.001
1
100
110
0
3
.1 1.
.0010
.0
.0
.001
1
101
210
5
2
PIPE
.0 0.
.0010
.0
.0
.001
0
RESERVOIR
STORAGE IN
ACRE-FEET
VS SPILLWAY OUTFLOW
0
.0
1
2.5 4 3.5
1.0
4.3
1.6
5.0
201
205
9
2
PIPE
.0 0.
.0010
.0
.0
.001
0
RESERVOIR
STORAGE IN
ACRE-FEET
VS SPILLWAY OUTFLOW
.0
.0
.0
2.6 .2 4.5
.8
5.8
1.7
6.8
7.8
3.8
8.6
5.0
9.3 6.4 10.0
301
211
8
2
PIPE
.0 0.
.0010
.0
.0
.001
0
RESERVOIR
STORAGE IN
ACRE-FEET
VS SPILLWAY OUTFLOW
.0
.0
.1
4.5 .7 6.4
1.9
7.9
3.4
9.1
10.1
6.8
11.1
8.7 12.0
501
206
9
2
PIPE
.0 0.
.0010
.0
.0
.001
0
RESERVOIR
STORAGE IN
ACRE-FEET
VS SPILLWAY OUTFLOW
.0
.0
.1
2.6 .3 3.8
.8
4.6
1.4
5.3
5.9
3.0
6.5
3.9
7.0 4.9 7.5
TOTAL NUMBER OF GUTTERS/PIPES,
14
DEPTH
(FT)
2.00
2.50
2.50
10.00
10.00
.00
wS
rIi
2.6
2.50
10.00
10.00
.00
�t
2.7
00
5.0
00
2.1
CASWMMV-1TPMasterFine1100 revised5-16-08.out 13 Printed: 5/16/2006
Stantac
HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFinal100.IN STANTEC; 3/6/08
ARRANGEMENT OF SUBCATCHMENTS AND GUTTERS/PIPES
GUTTER
TRIBUTARY
GUTTER/PIPE
D.A.(AC)
100
0
0
0
0
0
0
0
0
0 0
32.9
205
210
201
0
0
0
0
0
0
0 0
29.9
206
205
501
0
0
0
0
0
0
0 0
46.4
207
206
208
0
0
0
0
0
0
0 0
56.4
208
0
0
0
0
0
0
0
0
0 0
10.0
210
101
0
0
0
0
0
0
0
0 0
6.9
211
301
0
0
0
0
0
0
0
0 0
41.4
510
110
211
0
0
0
0
0
0
0 0
71.3
TRIBUTARY SUBAREA
100 0 0 0
0
0
0
0
0 0
0 0 0 0
0
0
0
0
0 0
0 0 0 0
0
0
0
0
0 0
0 0 0 0
0
0
0
0
0 0
903 0 0 0
0
0
0
0
0 0
0 0 0 0
0
0
0
0
0 0
0 0 0 0
0
0
0
0
0 0
0 0 0 0
0
0
0
0
0 0
CASVVMM\HTPMasterFinal 100 revised5-16-OB.out 14
Printed: 5/16/2008
I
ShMmo
HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFina)100.IN STANTEC: 3/6/08
1
1
1
1
1
1
1
HYDROGRAPHS ARE LISTED FOR THE FOLLOWING 6 CONVEYANCE ELEMENTS
THE
UPPER NUMBER IS DISCHARGE IN CFS
THE
LOWER NUMBER
IS ONE OF THE FOLLOWING
CASES:
( )
DENOTES DEPTH ABOVE INVERT
IN FEET
(S)
DENOTES STORAGE IN AC -FT
FOR DETENTION
DAM.
DISCHARGE INCLUDES SPILLWAY OUTFLOW.
(I)
DENOTES GUTTER
INFLOW IN
CFS FROM
SPECIFIED
INFLOW HYDROGRAPH
(D)
DENOTES DISCHARGE IN CFS
DIVERTED
FROM THIS
GUTTER
(0)
DENOTES STORAGE IN AC -FT
FOR SURCHARGED GUTTER
TIME(HR/MIN)
101
110
201
301
501
600
0
1.
.0
.0
.0
.0
.0
.0
.00( )
.00(S)
.00(S)
.00(S)
.00(S)
.00(S)
0
6.
.0
.0
.0
.0
.0
.0
.00(S)
.00(S)
.00(S)
.00(S)
.00.(S)
.00(S)
0
11.
.3
2.0
2.6
1.3
.8
.9
.01(S)
.04(S)
.02(S)
.04(S)
.02(5)
.02(S)
0
16.
1.3
8.3
3.4
4.7
2.7
3.4
.05(S)
.17(S)
.12(S)
.17(S)
.09(S)
.OB(S)
0
21.
2.5
8.8
4.6
5.5
3.3
4.8
.11(S)
.42(S)
.31(S)
.45(S)
.24(S)
.18(S)
0
26.
2.8
9.3
5.3
6.6
3.9
5.5
.20(S)
.86(S)
.63(S)
.88(S)
.46(S)
.34(S)
0
31.
3.4
10.3
6.3
7.7
4.7
6.7
.40(S)
1.77(S)
1.28(S)
1.755)
.94(5)
.69(S)
0
36.
4.1
12.2
7.6
9.1
5.7
8.1
.79(S)
3.55(S)
2.54(S)
3.38(S)
1.85(S)
1.38(S)
0
41.
4.4
13.0
8.2
9.8
6.1
8.7
.99(S)
4.66(S)
3.31(S)
4.43(S)
2.40(S)
1.75(S)
0
46.
4.5
13.5
8.5
10.2
6.3
9.0
1.10(S)
5.29(S)
3.76(S)
5.05(S)
2.71(S)
1.94(S)
0
51.
4.6
13.7
8.7
10.4
6.4
9.2
1.16(S)
5.65(S)
4.01(S)
5.44(S)
2.89(S)
2.03(S)
0
56.
4.6
13.9
8.8
10.5
6.5
9.2
1.19(S)
5.88(S)
4.18(S)
5.72(S)
3.00(S)
2.09(S)
1
1.
4.6
14.0
8.9
10.7
6.6
9.3
1.21(S)
6.05(S)
4.30(S)
5.94(S)
3.09(S)
2.12(S)
1
6.
4.6
14.0
8.9
10.8
6.6
9.3
1.23(S)
6.19(S)
4.41(S)
6.14(S)
3.16(S)
2.14(S)
1
11.
4.6
14.1
9.0
10.9
6_6
9.3
1.24(S)
6.30(S)
4.49(S)
6.31(S)
3.22(S)
2.15(S)
1
16.
4.7
14.2
9.0
11.0
6.7
9.3
1.25(S)
6.41(S)
4.57(S)
6.48(S)
3.27(S)
2.16(S)
1
21.
4.7
14.2
9.1
11.0
6.7
9.3
1.25(S)
6.50(S)
4.64(S)
6.63(S)
3.32(S)
2.16(S)
1
26.
4.7
14.3
9.1
11.1
6.7
9.3
1.26(S)
6.58(S)
4.70(S)
6.78(S)
3.36(S)
2.17(S)
1
31.
4.7
14.3
9.1
11.2
6.8
9.3
1.26(S)
6.65(S)
4.76(S)
6.92(S)
3.40(S)
2.17(S)
1
36.
4.7
14.4
9.2
11.2
6.8
9.3
1.26(S)
6.72(S)
4.81(S)
7.05(S)
3.44(S)
2.16(S)
1
41.
4.7
14.4
9.2
11.3
6.8
9.3
1.26(S)
6.77(S)
4.86(S)
7.17(S)
3.47(S)
2.16(S)
1
46.
4.7
14.4
9.2
11.4
6.8
9.3
1.26(S)
6.83(S)
4.90(S)
7.29(S)
3.50(S)
2.15(S)
1
51.
4.7
14.5
9.2
11.4
6.8
9.3
1.26(S)
6.87(5)
4.94(S)
7.41(S)
3.52(S)
2.14(S)
1
56.
4.7
14.5
9.3
11.5
6.8
9.3
1.26(S)
6.91(S)
4.97(S)
7.52(S)
3.55(S)
2.13(S)
2
1.
4.7
14.5
9.3
11.5
6.8
9.3
1.25(5)
6.95(S)
5.00(S)
7.62(S)
3.57(S)
2.11(5)
2
6.
4.6
14.5
9.3
11.5
6.8
9.2
1.23(S)
6.93(5)
4.99(S)
7.67(S)
3.56(S)
2.07(S)
2
11.
4.6
14.5
9.3
11.5
6.8
9.1
1.21(S)
6.87(S)
4.95(S)
7.69(S)
3.53(S)
2.02(S)
2
16-
4.6
14.4
9.2
11.5
6.8
9.1
1.18(S)
6.79(S)
4.91(S)
7.69(S)
3.49(S)
1.97(S)
2
21.
4.5
14.4
9.2
11.5
6.8
9.0
1.15(S)
6.71(S)
4.85(S)
7.69(S)
3.45(S)
1.91(S)
2
26.
4.5
14.3
9.2
11.5
6.8
8.9
1.12(S)
6.62(S)
4.80(S)
7.68(S)
3.41(S)
1.85(S)
2
31.
4.5
14.3
9.1
11.5
6.7
8.8
1.09(S)
6.53(S)
4.74(S)
7.67(S)
3.37(S)
1.79(S)
2
36.
4.4
14.2
9.1
11.5
6.7
8.7
1.06(S)
6.44(S)
4.68(S)
7.66(S)
3.33(S)
1.73(S)
2
41.
4.4
14.1
9.1
11.5
6.7
8.6
1.03(S)
6.35(S)
4.62(S)
7.64(S)
3.28(S)
1.67(S)
2
46.
4.4
14.1-
9.0
11.5
6.7
8.5
1.00(S)
6.25(S)
4.56(S)
7.62(S)
3.24(S)
1.61(S)
2
51.
4.3
14.0
9.0
11.5
6.6
8.4
.97(S)
6.16(S)
4.50(S)
7.61(S)
3.19(S)
1.56(S)
2
56.
4.3
14.0
8.9
11.5
6.6
8.3
CASVVMM\HTPMasterFinal100 revised5-16-OB.out
15
Pdnted: 5/16/2008
I
1
t
1
1
I
1
1
1
Stentx
.94(S)
6.07(S)
4.44(S)
7:59(S)
3.15(S)
1.50(S)
4.3
13.9
8.9
11.5
6.6
8.2
.91(S)
5.97(S)
4.38(S)
7.57(S)
3.10(S)
1.44(S)
3 6.
4.2
13.9
8.9
11.5
6.6
8.1
.89(S)
5.88(S)
4.32(S)
7.54(S)
3.06(S)
1.39(S)
3 11.
4.2
13.8
8.8
11.5
6.5
8.0
.86(S)
5.78(S)
4.26(S)
7.52(S)
3.02(S)
1.33(S)
3 16.
4.1
13.8
8.8
11.4
6.5
7.9
.83(S)
5.69(S)
4.20(S)
7.50(S)
2.97(S)
1.28(S)
3 21.
4.1
13.7
8.8
11.4
6.5
7.9
.80(S)
5.60(S)
4.14(S)
7.48(S)
2.93(S)
1.22(S)
3 26.
4.0
13.6
8.7
11.4
6.4
7.8
.77(S)
5.50(S)
4.08(S)
7.45(S)
2..88(S)
1.17(S)
3 31.
4.0
13.6
8.7
11.4
6.4
7.7
.74(S)
5.41(S)
4.03(S)
7.43(S)
2.84(S)
1.12(S)
3 36.
4.0
13.5
8.7
11.4
6.4
7.5
.72(S)
5.32(S)
3.97(S)
7.40(S)
2.79(S)
1.06(5)
3 41.
3.9
13.5
8.6
11.4
6.4
7.4
.69(S)
5.23(S)
3.91(S)
7.37(S)
2.75(S)
1.01(5)
3 46.
3.9
13.4
8.6
11.4
6.3
7.3
.66(S)
5.13(S)
3.85(S)
7.35(S)
2.71(S)
.96(S)
3 51.
3.8
13.3
8.5
11.4
6.3
7.,2
.64(S)
5.04(S)
3.79(S)
7.32(S)
2.66(S)
.91(S)
3 56.
3.8
13.3
8.5
11.4
6.3
7.1
.61(S)
4.95(S)
3.73(S)
7.29(S)
2.62(S)
.86(S)
4 1.
3.8
13.2
8.5
11.3
6.2
7.0
.58(S)
4.86(S)
3.67(S)
7.26(S)
2.58(S)
.81(S)
4 6.
3.7
13.1
8.4
11.3
6.2
6.9
.56(S)
4.77(S)
3.61(S)
7.23(S)
2.54(S)
.77(S)
4 11.
3.7
13.1
8.4
11.3
6.2
6.8
.53(S)
4.68(S)
3.56(S)
7.20(S)
2.49(S)
.72(S)
4 16.
3.6
13.0
8.3
11.3
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6.7
.51(S)
4.59(S)
3.50(S)
7.17(S)
2.45(S)
.67(5)
4 21.
3.6
12.9
8.3
11.3
6.1
6.6
.48(S)
4.50(S)
3.44(S)
7.14(S)
2.41(S)
.63(S)
4 26.
3.6
12.8
8.3
11.3
6.1
6.5
.46(S)
4.41(S)
3.39(S)
7.10(S)
2.37(S)
.58(S)
4 31.
3.5
12.8
8.2
11.2
6.1
6.4
.43(S)
4.32(S)
3.33(S)
7.07(S)
2.33(S)
.54(S)
4 36.
3.5
12.7
8.2
11.2
6.0
6.2
.41(S)
4.24(S)
3.27(S)
7.04(S)
2.28(S)
.50(S)
4 41.
3.4
12.6
8.1
11.2
6.0
6.0
.39(S)
4.15(S)
3.22(S)
7.00(S)
2.24(S)
.45(S)
4 46.
3.3
12.6
8.1
11.2
6.0
5.9
.36(S)
4.06(S)
3.16(S)
6.97(S)
2.20(S)
.41(S)
4 51.
3.2
12.5
8.1
11.2
5.9
5.7
.34(S)
3.9B(S)
3 11(S)
6.93(S)
2.16(S)
.37(S)
4 56.
3.2
12.4
8.0
11.2
5.9
5.5
.32(S)
3.89(S)
3.05(S)
5.89(S)
2.12(S)
.34(S)
5 1.
3.1
12.4
8.0
11.1
5.9
5.3
.30(S)
3.81(S)
3.00(S)
6.85(S)
2.08(S)
.30(S)
5 6.
3.1
12.3
7.9
11.1
5.8
5.2
.28(S)
3.72(S)
2.94(S)
6.81(S)
2.04(S)
.26(S)
5 11.
3.0
12.2
7.9
11.1
5.8
5.0
.26(S)
3.64(S)
2.89(S)
6.77(S)
2.00(S)
.23(S)
5 16.
2.9
12.2
7.%
11..1
5.8
4.9
.23(S)
3.55(S)
2.83(S)
6.73(S)
1.96(S)
.19(S)
5 21.
2.9
12.1
7.8
11.1
5.7
4.7
.21(S)
3.47(S)
2.78(S)
6.68(S)
1.92(S)
.16(S)
5 26.
2.8
12.0
7.8
11.0
5.7
4.6
.20(S)
3.39(S)
2.72(S)
6.64(S)
1.88(S)
.13(S)
5 31.
2.8
11.9
7.7
11.0
5.7
4.3
.18(S)
3.30(S)
2.67(S)
6.59(S)
1.84(S)
.10(S)
5 36.
2.7
11.8
7.7
11.0
5.6
3.2
.16(S)
3.22(S)
2.62(S)
6.54(S)
1.80(S)
.07(S)
5 41.
2.6
11.8
7.6
11.0
5.6
2.3
.14(S)
3.14(5)
2.57(S)
6.49(S)
1.76(S)
.05(S)
5 46.
2.6
11.7
7.6
10.9
5.6
1.7
.12(S)
3.06(S)
2.51(S)
6.43(S)
1.73(S)
.04(S)
5 51.
2.5
11.6
7.5
10.9
5.5
1.3
.10(S)
2.98(S)
2.46(S)
6.36(S)
1.69(S)
.03(S)
5 56.
2.4
11.5
7.5
10.8
5.5
.9
.09(S)
2.90(5)
2.41(S)
6.29(S)
1.65(S)
.02(S)
6 1.
2.0
11.4
7.4
10.8
5.5
.7
.07(S)
2.82(S)
2.36(S)
6.23(S)
1.61(S)
.02(5)
6 6.
1.6
11.3
7.4
10.8
5.4
.5
.06(S)
2.74(S)
2.31(S)
6.15(S)
1.57(S)
.01(S)
6 11.
1.3
11.2
7.4
10.7
5.4
.4
.05(S)
2.67(S)
2.26(S)
6.08(S)
1.54(S)
.01(S)
6 16.
1.1
11.2
7.3
10.7
5.4
.3
.04(S)
2.59(S)
2.21(S)
6.01(S)
1.50(S)
.01(S)
6 21.
.9
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7.3
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5.3
.2
.03(S)
2.51(S)
2.16(S)
5.94(S)
1.46(S)
.00(5)
6 26.
.8
11.0
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.1
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2.44(S)
2.11(S)
5.87(S)
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6 31.
.6
10.9
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.1
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6 36.
.5
10.8
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.1
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2.01(S)
5.72(S)
1.36(S)
.00(S)
6 41.
.4
10.7
7.1
10.5
5.2
.1
C:\SWMM\HTPMasterFinai100 revised5-16-08.out
16
Printed: 5/1612008
LIB
1
1
�I
1
I
1
II
Stantse
.02(S)
2.21(S)
1.96(S)
5.65(S)
1.32(S)
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6
46.
.4
10.7
7.0
10.5
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.0
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2.14(S)
1.91(S)
5.58(S)
1.28(S)
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6
51.
.3
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7.0
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.0
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2.07(S)
1.86(S)
5.51(S)
1.25(S)
.00(S)
6
56.
.2
10.5
7.0
10.4
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.0
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1.99(S)
1.81(S)
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1.21(S)
.00(S)
7
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.2
10.4
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101(S)
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1.77(S)
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1.18(S)
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7
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.2
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.0
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1.85(S)
1.72(S)
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7
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.1
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.0
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1.78(S)
1.67(S)
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7
16.
.1
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.0
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1.71(S)
1.62(S)
5.15(S)
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7
21.
.1
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6.7
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.0
.00(5)
1.64(S)
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7
26.
.1
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6.6
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.0
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1.57(S.)
1.53(S)
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7
31.
.1
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.0
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.1
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.0
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7
41.
.0
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.0
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7
46.
.0
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.0
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7
51.
.0
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.0
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7
56.
.0
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.0
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4.60(S)
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8
1.
.0
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.0
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8
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.0
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8
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.0
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8
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.0
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.0
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.0
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.0
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8
26.
.0
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.0
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.0
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9
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.0
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9
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.0
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9
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9
26.
.0
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C:\SWMM\HTPMasterFinall 00 revised5-16-08.out
17
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C:\SWMM\HTPMasterFina1100 revised5-18-08.out 18 Pdnted: 5/16/2008
Stantac
HARMONY TECHNOLOGY PARK
100-YEAR EVENT FILE: HTPMasterFina1100.IN STANTEC; 3/6/08
*** PEAK
FLOWS, STAGES
AND STORAGES OF GUTTERS
AND DETENTION
DAMS ***
*** NOTE
:S IMPLIES A
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-->>
ENDPROGRAM PROGRAM CALLED
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POND SIZING CALCULATIONS:
RATING CURVES, WQCV
1
'
tmp#Sl.txt
POND 101
#Units=Elevation,ft,Area,ft2,volume,acft,volume,acft
'
# Elev
Area
Cumml Avg Cumml
Conic
# ft
ft2
acft acft
4914.0000
27S95.1368
1.5928
1.5539
4913.0000
24272.6603
0.9974
0.9589
'
4912.0000
21050.7235
0.4772
0.4391
4911.0000
10194.2622
0.1185
0.0879
4910.0000
132.4730
0.0000
0.0000
1
1
1
1
Page 1
1
I
Harmony Technology Park STANTEC
Pond 101 Orifice Calculation 187710640
100-Year Pond Orifice Plate
Basic Equation:
Q=Cd•A•(2g•(hl-h2))o.5
Revised Equation:
A=Q/(Cd • (2g • (hl - h2 ))0.5
Input
Basin Area =
6.90
Contributing Drainage Area
Cd=
0.65
Input
g=
32.20 ft/s2
Gravitational Constant
h1=
4914.00
100 year WSEL
h2=
4910.00
Invert Elevation of Pipe
Q=
5.00 cfs
Input
A= 0.48 fit` Calculated orifice area
'r- 4.69 Calculated radius (inches)
" Orifice opening bottom aligned with invert of pipe, difference in
head on the orifice measured from the centerline of the orifice opening
Orifice Dia. = 9.3741 inches
0.7812 feet
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Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 1 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 101)
1. Basin Storage Volume
Ia = 80.00 %
A) Tributary Area's Imperviousness Ratio (i = le / 100) i = 0.80
B) Contributing Watershed Area (Area) Area = 6.90 acres
C) Water Quality Capture Volume (WQCV) WQCV = 0.33 watershed inches
(WQCV =1.0'(0.91'13-1.1912+0.78.1))
D) Design Volume: Vol = (WQCV / 12)' Area' 1.2 Vol = 0.227 acre-feet
2. Outlet Works
A) Outlet Type (Check One) x Orifice Plate
Perforated Riser Pipe
Other:
B) Depth at Outlet Above Lowest Perforation (H)
H =
1.40
feet
C) Required Maximum Outlet Area per Row, (A,)
A. =
0.81
square inches
D) Perforation Dimensions (enter one only):
i) Circular Perforation Diameter OR
D =
1.0000
inches, OR
ii) 2" Height Rectangular Perforation Width
W =
inches
E) Number of Columns (nc, See Table 6a-1 For Maximum)
nc =
1
number
F) Actual Design Outlet Area per Row (k)
A. =
0.79
square inches
G) Number of Rows (nr)
nr =
4
number
H) Total Outlet Area (A,J
Ao, =
3.30
square inches
3. Trash Rack
A) Needed Open Area: A, = 0.5' (Figure 7 Value)' Ao, At = 112 square inches
B) Type of Outlet Opening (Check One) x < 2" Diameter Round
2" High Rectangular
Other:
C) For 2", or Smaller, Round Opening (Ref.: Figure 6a):
i) Width of Trash Rack and Concrete Opening (W.on.)
from Table 6a-1 Mom = 6 inches
ii) Height of Trash Rack Screen (HTR) HTR = 41 inches
WQCV Pond 101.xls, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 2 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 101)
iii) Type of Screen (Based on Depth H), Describe if "Other"
x
S.S. #93 VEE Wire (US Filter)
Other:
iv) Screen Opening Slot Dimension, Describe if "Other"
x
0.139" (US Filter)
Other:
v) Spacing of Support Rod (O.C.)
0.75
inches
Type and Size of Support Rod (Ref.: Table 6a-2)
#156 VEE
vi) Type and Size of Holding Frame (Ref.: Table 6a-2)
3/8 in. x 1.0 in. flat bar
D) For 2" High Rectangular Opening (Refer to Figure 6b):
1) Width of Rectangular Opening (W)
W=
inches
ii) Width of Perforated Plate Opening (W„n, = W + 12")
Woo c =
inches
iii) Width of Trashrack Opening (W. , ,,g) from Table 6b-1
WoGenI,q =
inches
iv) Height of Trash Rack Screen (HTR)
HTR =
inches
v) Type of Screen (based on depth H) (Describe if "Other")
KlempT" KPP Series Aluminum
Other.
vi) Cross -bar Spacing (Based on Table 6b-1, KlempT"" KPP
inches
Grating). Describe if "Other"
Other:
vii) Minimum Bearing Bar Size (KlempT"" Series, Table 6b-2)
4. Detention Basin length to width ratio I (L/W )
5 Pre -sedimentation Forebay Basin - Enter design values
A) Volume (5 to 10% of the Design Volume in 1 D) acre-feet
B) Surface Area acres
C) Connector Pipe Diameter inches
(Size to drain this volume in 5-minutes under inlet control)
D) Paved/Hard Bottom and Sides yes/no
WQCV Pond 101.x1s, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 3 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 101)
6.
Two -Stage Design
A) Top Stage (Dwo = 2' Minimum)
Dwo =
feet
Storage=
acre-feet
B) Bottom Stage (DBs = Dwo+ 1.5' Minimum, Dwo+ 3.0' Maximum,
DBs =
feet
Storage = 5% to 15% of Total W QCV)
Storage=
acre-feet
Surf. Area=
acres
C) Micro Pool (Minimum Depth = the Larger of
Depth=
feet
0.5' Top Stage Depth or 2.5 Feet)
Storage=
acre-feet
Surf. Area=
acres
D) Total Volume: Vol„ , = Storage from 5A + 6A + 6B
Volt , =
acre-feet
Must be > Design Volume in 1 D
7.
Basin Side Slopes (Z, horizontal distance per unit vertical)
Z =
(horizontal/vertical)
Minimum Z = 4, Flatter Preferred
8.
Dam Embankment Side Slopes (Z, horizontal distance)
Z =
4.00 (horizontal/vertical)
per unit vertical) Minimum Z = 3, Flatter Preferred
9.
Vegetation (Check the method or describe "Other")
Native Grass
Irrigated Turf Grass
Other:
Notes:
WQCV Pond 101.xls, EDB
I
POND 110
tmp#67.txt
'
#units=Elevation,ft,Area,ft2,volume,acft,volume,acft
# Elev
Area
Cumml Avg Cumml
Conic
# ft
ft2
acft acft
'
4906.0000
4905.0000
137622.9646
121394.0787
13.0348
10.0617
12.9345
9.9634
4904.0000
103363.9981
7.4818
7.3863
4903.0000
86427.8780
5.3033
5.2106
t
4902.0000
4901.0000
70411.6478
58718.1104
3.5030
2.0208
3.4135
1.9333
4900.0000
43170.3898
0.8513
0.7684
4899.0000
15492.8019
0.1779
0.1216
'
4898.0000
9.5781
0.0000
0.0000
1
1
1
i
Harmony Technology Park
Pond 110 Orifice Calculation
100-Year Pond Orifice Plate
Basic Equation:
Q=Cd•A•(2g•(h1-h2))0.5
Revised Equation:
A=Q/(Cd • (2g • (h1 - h2 ))0.5
In
Basin Area =
32.92
Cd=
0.65
g=
32.20 fUs2
h1=
4904.20
h2=
4898.00
Q =
15.00 cfs
Contributing Drainage Area
Input
Gravitational Constant
100 year WSEL
Invert Elevation of Pipe
Input
A= 1.15 ft` Calculated orifice area
'r- 7.28 Calculated radius (inches)
Orifice opening bottom aligned with invert of pipe, difference in
head on the orifice measured from the centerline of the orifice opening
Orifice Dia. = 14.5514 inches
1.2126 feet
STANTEC
187710640
w
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Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 1 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
May 16, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 110)
1. Basin Storage Volume
la =
80.00
%
A) Tributary Area's Imperviousness Ratio (i = la / 100)
i =
0.80
B) Contributing Watershed Area (Area)
Area =
32.92
acres
C) Water Quality Capture Volume (WQCV)
WQCV =
0.33
watershed inches
(WQCV=1.0-(0.91 `13-1.19.I2+0.78.1))
D) Design Volume: Vol = (WQCV / 12)' Area ` 1.2
Vol =
1.081
acre-feet
2. Outlet Works
A) Outlet Type (Check One) x Orifice Plate
Perforated Riser Pipe
Other:
B) Depth at Outlet Above Lowest Perforation (H)
H =
2.27
feet
C) Required Maximum Outlet Area per Row, (k)
A. =
1.93
square inches
D) Perforation Dimensions (enter one only):
i) Circular Perforation Diameter OR
D =
1.5000
inches, OR
ii) 2" Height Rectangular Perforation Width
W =
inches
E) Number of Columns (nc, See.Table 6a-1 For Maximum)
nc =
1
number
F) Actual Design Outlet Area per Row (k)
At, =
1.77
square inches
G) Number of Rows (nr)
nr =
7
number
H) Total Outlet Area (k,)
Ao, =
12.03
square inches
3. Trash Rack
A) Needed Open Area: A, = 0.5' (Figure 7 Value)' Ao, A, = 385 square inches
B) Type of Outlet Opening (Check One) x < 2" Diameter Round
2" High Rectangular
Other:
C) For 2", or Smaller, Round Opening (Ref.: Figure 6a):
i) Width of Trash Rack and Concrete Opening (Wro .)
from Table 6a-1 Wconc = 15 inches
ii) Height of Trash Rack Screen (HTR) HTe = 51 inches
WQCV Pond 110.xls, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 2 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
May 16, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 110)
iii) Type of Screen (Based on Depth H), Describe if "Other"
X
S.S. #93 VEE Wire (US Filter)
Other:
iv) Screen Opening Slot Dimension, Describe if "Other"
X
0.139" (US Filter)
Other:
v) Spacing of Support Rod (O.C.)
1.00
inches
Type and Size of Support Rod (Ref.: Table 6a-2)
TE 0.074 in. x 0.50 in.
vi) Type and Size of Holding Frame (Ref.: Table 6a-2)
0.75 in, x 1.00 in. angle
D) For 2" High Rectangular Opening (Refer to Figure 6b):
1) Width of Rectangular Opening (W)
W =
inches
ii) Width of Perforated Plate Opening (W�n, = W + 12")
Wconc =
inches
iii) Width of Trashrack Opening (W,mng) from Table 6b-1
W,ening =
inches
iv) Height of Trash Rack Screen (HTR)
HTR =
inches
v) Type of Screen (based on depth H) (Describe if "Other")
Klemprm KPP Series Aluminum
Other:
vi) Cross -bar Spacing (Based on Table 6b-1, KlempTm KPP
inches
Grating). Describe if "Other"
Other:
vii) Minimum Bearing Bar Size (KlempTM Series, Table 6b-2)
(Based on depth of WQCV surcharge)
4. Detention Basin length to width ratio (UW )
5 Pre -sedimentation Forebay Basin - Enter design values
A) Volume (5 to 10% of the Design Volume in 1 D) acre-feet
B) Surface Area acres
C) Connector Pipe Diameter inches
(Size to drain this volume in 5-minutes under inlet control)
D) Paved/Hard Bottom and Sides yes/no
WQCV Pond 110.xis, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 3 of 3
1
t
1
I 1
I
II
II
II
II
II
Designer.
Brad Kugler
Company:
Stantec
Date:
May 16, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 110)
6. Two -Stage Design
A) Top Stage (Dwo = 2' Minimum)
Dwo =
feet
Storage=
acre-feet
B) Bottom Stage (Des = Dwo+ 1.5' Minimum, Dwo+ 3.0' Maximum,
Des =
feet
Storage = 5% to 15% of Total W QCV)
Storage=
acre-feet
Surf. Area=
acres
C) Micro Pool (Minimum Depth = the Larger of
Depth=
feet
0.5' Top Stage Depth or 2.5 Feet)
Storage=
acre-feet
Surf. Area=
acres
D) Total Volume: Vol,,, = Storage from 5A + 6A + 6B
Volio =
acre-feet
Must be > Design Volume in 1 D
7. Basin Side Slopes (Z, horizontal distance per unit vertical)
Z =
(horizontallvertical)
Minimum Z = 4, Flatter Preferred
8. Dam Embankment Side Slopes (Z, horizontal distance)
Z =
4.00 (horizontal/vertical)
per unit vertical) Minimum Z = 3, Flatter Preferred
9. Vegetation (Check the method or describe "Other")
Native Grass
Irrigated Turf Grass
Other:
Notes:
II
WQCV Pond 110.x1s, EDB
I
POND 201
tmp#53.txt
#Units=Elevation,ft,Area,ft2,volume,acft,volume,acft
t # Elev
Area
Cumml Avg Cumml
Conic
# ft
ft2
acft acft
4912.0000
60937.5165
6.4234
6.3841
4911.0000
56011.1344
5.0811
5.0421
'
4910.0000
51185.3016
3.8506
3.8121
4909.0000
46460.0268
2.7298
2.6917
4908.0000
41835.3295
1.7163
1.6787
4907.0000
33206.1554
0.8549
0.8192
'
4906.0000
18178.3167
0.2651
0.2380
4905.0000
3232.3367
0.0194
0.0155
4904.5000
142.7907
0.0000
0.0000
k
II
II
II
II
II
1
Page I
II
Harmony Technology Park
Pond 201 Orifice Calculation
100-Year Pond Orifice Plate
Basic Equation:
Q=Cd•A•(2g•(h1-h2))0.5
Revised Equation:
A=Q/(Cd • (2g • (h1 - h2 ))0.5
Basin Area =
23.02
Cd=
0.65
g=
32.20 fUS2
h1=
4912.00
h2=
4904.50
Q =
10.00 cfs
Contributing Drainage Area
Input
Gravitational Constant
100 year WSEL
Invert Elevation of Pipe
Input
"r- 5.66 Calculated radius (inches)
Orifice opening bottom aligned with invert of pipe, difference in
head on the orifice measured from the centerline of the orifice opening
Orifice Dia. = 11.3290 inches
0.9441 feet
STANTEC
187710640
c0
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Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 1 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 201)
1. Basin Storage Volume
I, = 80.00 %
A) Tributary Area's Imperviousness Ratio (i = I, / 100) i = 0.80
B) Contributing Watershed Area (Area) Area = 23.02 acres
C) Water Quality Capture Volume (WQCV) WQCV = 0.33 watershed inches
(WQCV =1.0`(0.91 `13-1.19`1'+0.78'1))
D) Design Volume: Vol = (WQCV / 12) "Area ` 1.2 Vol = 0.756 acre-feet
2. Outlet Works
A) Outlet Type (Check One) x Orifice Plate
Perforated Riser Pipe
Other:
B) Depth at Outlet Above Lowest Perforation (H)
H =
2.39
feet
C) Required Maximum Outlet Area per Row, (Ao)
A„ =
1.26
square inches
D) Perforation Dimensions (enter one only):
i) Circular Perforation Diameter OR
D =
0.8500
inches, OR
ii) 2" Height Rectangular Perfgration Width
W =
inches
E) Number of Columns Inc, See Table 6a-1 For Maximum)
nc =
2
number
F) Actual Design Outlet Area per Row (Ao)
A. =
1.13
square inches
G) Number of Rows (nr)
nr =
7
number
H) Total Outlet Area (A.,)
Ao, =
8.14
square inches
3. Trash Rack
A) Needed Open Area: A, = 0.5 ` (Figure 7 Value)' Ao, A, = 282 square inches
B) Type of Outlet Opening (Check One) X < 2" Diameter Round
2" High Rectangular
Other:
C) For 2", or Smaller, Round Opening (Ref.: Figure 6a):
i) Width of Trash Rack and Concrete Opening (Wconc)
from Table 6a-1 Wm o = 12 inches
ii) Height of Trash Rack Screen (HM) HTR = 53 inches
WQCV Pond 201.xis, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 2 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 201)
iii) Type of Screen (Based on Depth H), Describe if "Other"
x
S.S. 493 VEE Wire (US Filter)
Other:
iv) Screen Opening Slot Dimension, Describe if "Other"
X
0.139" (US Filter)
Other:
v) Spacing of Support Rod (O.C.)
1.00
inches
Type and Size of Support Rod (Ref.: Table 6a-2)
TE 0.074 in.
x 0.50 in.
vi) Type and Size of Holding Frame (Ref.: Table 6a-2)
0.75 in. x 1.00 in. angle
D) For 2" High Rectangular opening (Refer to Figure 6b):
1) Width of Rectangular Opening (W)
W =
inches
ii) Width of Perforated Plate Opening (W.,,, = W + 12")
WPPnc =
inches
iii) Width of Trashrack Opening (WoPen;nd from Table 6b-1
W,emng =
inches
iv) Height of Trash Rack Screen (HTR)
HTR =
inches
v) Type of Screen (based on depth H) (Describe if "Other")
KlempTm KPP Series Aluminum
Other:
vi) Cross -bar Spacing (Based on Table 6b-1, KlempTm KPP
inches
Grating). Describe if "Other"
Other:
vii) Minimum Bearing Bar Size (KlempTM Series, Table 6b-2)
4. Detention Basin length to width ratio I _ (L/W )
5 Pre -sedimentation Forebay Basin - Enter design values
A) Volume (5 to 10% of the Design Volume in 1 D) acre-feet
B) Surface Area acres
C) Connector Pipe Diameter inches
(Size to drain this volume in 5-minutes under inlet control)
D) Paved/Hard Bottom and Sides yes/no
WQCV Pond 201.xls, EDB
I
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 3 of 3
Designer: Brad Kugler
1
i
1
1
I
1
1
1
I
II
II
II
II
II
II
II
II
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 201
6.
Two -Stage Design
A) Top Stage (Dwo = 2' Minimum)
DWo =
feet
Storage=
acre-feet
B) Bottom Stage (Dss = DWo+ 1.5' Minimum, Dwo+ 3.0' Maximum,
Dss =
feet
Storage = 5% to 15% of Total W QCV)
Storage=
acre-feet
Surf. Area=
acres
C) Micro Pool (Minimum Depth = the Larger of
Depth=
feet
0.5' Top Stage Depth or 2.5 Feet)
Storage=
acre-feet
Surf. Area=
acres
D) Total Volume: Vol,,, = Storage from 5A + 6A + 6B
Volio, =
acre -feel
Must be > Design Volume in 1 D
7.
Basin Side Slopes (Z, horizontal distance per unit vertical)
Z =
(horizontal/vertical)
Minimum Z = 4, Flatter Preferred
8.
Dam Embankment Side Slopes (Z, horizontal distance)
Z =
4.00 (horizontal/vertical)
per unit vertical) Minimum Z = 3, Flatter Preferred
9.
Vegetation (Check the method or describe "Other")
Native Grass
Irrigated Turf Grass
Other:
Notes:
IWCCV Pond 201.xls, EDB
tmp#54.txt
POND 301
#Units=Elevation,ft,Area,ft2,volume,acft,volume,acft
'
# Elev
Area
Cumml Avg Cumml
Conic
# ft
ft2
acft acft
4909.0000
85813.3071
8.7577
8.6796
4908.0000
80152.2235
6.8527
6.7749
4907.0000
74590.8191
5.0765
4.9991
4906.0000
69128.9262
3.4268
3.3498
4905.0000
59929.5117
1.9454
1.8697
4904.0000
39213.9360
0.8074
0.7400
4903.0000
15466.6723
0.1798
0.1331
4902.0000
195.0938
0.0000
0.0000
I
1
p
Page 1
t
1
1
Harmony Technology Park STANTEC
Pond 301 Orifice Calculation 187710640
100-Year Pond Orifice Plate
Basic Equation:
Q=Cd•A•(2g•(h1-h2))0.5
Revised Equation:
A=Q/(Cd • (2g • (h1 - h2 ))0.5
Input
Basin Area =
29.00
Contributing Drainage Area
Cd=
0.65
Input
g=
32.20 ft/s2
Gravitational Constant
h1=
4909.00
100 year WSEL
h2=
4902.00
Invert Elevation of Pipe
Q =
12.00 cfs
Input
A= 0.87 ft` Calculated orifice area
*r— 6.31 Calculated radius (inches)
Orifice opening bottom aligned with invert of pipe, difference in
head on the orifice measured from the centerline of the orifice opening
Orifice Dia. = 12.6262 inches
1.0522 feet
O
M
c
0
a
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Z
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r`
00
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 1 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 301)
1. Basin Storage Volume
la = 80.00 %
A) Tributary Area's Imperviousness Ratio (i = la / 100) i = 0.80
B) Contributing Watershed Area (Area) Area = 29.00 acres
C) Water Quality Capture Volume (WQCV) WQCV = 0.33 watershed inches
(WQCV =1.0"(0.91'I3_1.19"1'+0.78"1))
D) Design Volume: Vol = (WQCV / 12) " Area " 1.2 Vol = 0.952 acre-feet
2. Outlet Works
A) Outlet Type (Check One) x Orifice Plate
Perforated Riser Pipe
Other:
B) Depth at Outlet Above Lowest Perforation (H)
H =
2.19
feet
C) Required Maximum Outlet Area per Row, (Ao)
At, =
1.79
square inches
D) Perforation Dimensions (enter one only):
i) Circular Perforation Diameter OR
D =
1.5000
inches, OR
ii) 2" Height Rectangular Perforation Width
W =
inches
E) Number of Columns (nc, See Table 6a-1 For Maximum)
nc =
1
number
F) Actual Design Outlet Area per Row (A,)
Ao =
1.77
square inches
G) Number of Rows (nr)
nr =
7
number
H) Total Outlet Area (A,,)
A„ =
11.61
square inches
3. Trash Rack
A) Needed Open Area: A, = 0.5 " (Figure 7 Value)A, = 371 square inches
B) Type of Outlet Opening (Check One) x < 2" Diameter Round
2" High Rectangular
Other:
C) For 2", or Smaller, Round Opening (Ref.: Figure 6a):
i) Width of Trash Rack and Concrete Opening (Ww,,)
from Table 6a-1 Wwnc = 15 inches
ii) Height of Trash Rack Screen (HTR) HTR = 50 inches
WQCV Pond 301.x1s, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 2 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 301)
iii) Type of Screen (Based on Depth H), Describe if "Other"
x
S.S. #93 VEE Wire (US Filter)
Other:
iv) Screen Opening Slot Dimension, Describe if "Other"
x
0.139" (US Filter)
Other:
v) Spacing of Support Rod (O.C.)
1.00
inches
Type and Size of Support Rod (Ref.: Table 6a-2)
TE 0.074 in.
x 0.50 In.
vi) Type and Size of Holding Frame (Ref.: Table 6a-2)
0.75 in. x 1.00 in. angle
D) For 2" High Rectangular Opening (Refer to Figure 6b):
1) Width of Rectangular Opening (W)
W =
inches
ii) Width of Perforated Plate Opening (Mon, = W + 12")
Wconc =
inches
iii) Width of Trashrack Opening (W,p,,,;,,9) from Table 6b-1
Wopwing =
inches
iv) Height of Trash Rack Screen (HTR)
HTR =
inches
v) Type of Screen (based on depth H) (Describe if "Other")
KlempTm KPP Series Aluminum
Other:
vi) Cross -bar Spacing (Based on Table 6b-1, KlempTm KPP
inches
Grating). Describe if "Other"
Other:
vii) Minimum Bearing Bar Size (KlempTM Series, Table 6b-2)
Based on depth of WQCV surcharge)
4. Detention Basin length to width ratio (L/W )
5 Pre -sedimentation Forebay Basin - Enter design values
A) Volume (5 to 10% of the Design Volume in 1 D) acre-feet
B) Surface Area acres
C) Connector Pipe Diameter inches
(Size to drain this volume in 5-minutes under inlet control)
D) Paved/Hard Bottom and Sides yestno
WQCV Pond 301.xls, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 3 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 301)
6.
Two -Stage Design
A) Top Stage (Dwo = 2' Minimum)
Dwo =
feet
Storage=
acre-feet
B) Bottom Stage (DBs = Dwo+ 1.5' Minimum, Dwo+ 3.0' Maximum,
Dss =
feet
Storage = 5% to 15% of Total W QCV)
Storage=
acre-feet
Surf. Area=
acres
C) Micro Pool (Minimum Depth = the Larger of
Depth=
feet
0.5 ' Top Stage Depth or 2.5 Feet)
Storage=
acre-feet
Surf. Area=
acres
D) Total Volume: Volt,, = Storage from 5A + 6A + 6B
Vol'o' =
acre-feet
Must be> Design Volume in 1D
7.
Basin Side Slopes (Z. horizontal distance per unit vertical)
Z =
(horizontal/vertical)
Minimum Z = 4, Flatter Preferred
8.
Dam Embankment Side Slopes (Z, horizontal distance)
Z =
4.00 (horizontal/vertical)
per unit vertical) Minimum Z = 3, Flatter Preferred
9.
Vegetation (Check the method or describe "Other")
Native Grass
Irrigated Turf Grass
Other:
Notes:
WQCV Pond 301.xls, EDB
I
1 tmp#55.txt
POND 501
#Units=Elevation,ft,Area,ft2,volume,acft,volume,acft
1
# Elev
Area
Cumml Avg Cumml
Conic
# ft
ft2
acft acft
4911.0000
46747.6934
4.9266
4.8934
4910.0000
42110.0118
3.9067
3.8740
1
4909.0000
37572.8774
2.9920
2.9598
4908.0000
33136.2945
2.1804
2.1487
4907.0000
28800.2696
1.4695
1.4384
4906.0000
24564.8139
0.8569
0.8265
1
4905.0000
17382.1399
0.3754
0.3473
4904.0000
7565.6240
0.0891
0.0687
4903.0000
195.1957
0.0000
0.0000
1
1
1
1
i
1
1
II
II
II
II
II
'1
P<1ge ,
1
Harmony Technology Park STANTEC
Pond 501 Orifice Calculation 187710640
100-Year Pond Orifice Plate
Basic Equation:
Q=Cd•A•(2g•(h1-h2))0.5
Revised Equation:
A=Q/(Cd • (2g • (h1 - h2 ))0.5
Input
Basin Area =
16.50
Contributing Drainage Area
Ca=
0.65
Input
g=
32.20 fUs2
Gravitational Constant
h1=
4911.00
100 year WSEL
h2=
4903.00
Invert Elevation of Pipe
Q =
7.50 cfs
Input
A= 0.51 ft` Calculated orifice area
*r- 4.83 Calculated radius (inches)
* Orifice opening bottom aligned with invert of pipe, difference in
head on the orifice measured from the centerline of the orifice opening
Orifice Dia. = 9.6542 inches
0.8045 feet
r=
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Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 1 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
May 15, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 501)
1. Basin Storage Volume
Ia =
80.00
%
A) Tributary Area's Imperviousness Ratio (i = I, / 100)
i =
0.80
B) Contributing Watershed Area (Area)
Area =
16.50
acres
C) Water Quality Capture Volume (WQCV)
WQCV =
0.33
watershed inches
(WQCV =1.0 - (0.91 1' - 1.19IZ + 0.78 - 1))
D) Design Volume: Vol = (WQCV / 12) `Area' 1.2
Vol =
0.542
acre-feet
2. Outlet Works
A) Outlet Type (Check One) x Orifice Plate
Perforated Riser Pipe
Other:
B) Depth at Outlet Above Lowest Perforation (H)
H =
2.40
feet
C) Required Maximum Outlet Area per Row, (A.)
A. =
0.90
square inches
D) Perforation Dimensions (enter one only):
i) Circular Perforation Diameter OR
D =
1.0000
inches, OR
ii) 2" Height Rectangular Perforation Width
W =
inches
E) Number of Columns (nc, See Table 6a-1 For Maximum)
nc =
1
number
F) Actual Design Outlet Area per Row (Ao)
A. =
0.79
square inches
G) Number of Rows (nr)
nr =
7
number
H) Total Outlet Area (k,)
Ao, =
5.65
square inches
3. Trash Rack
A) Needed Open Area: A, = 0.5 " (Figure 7 Value)' A.,
A, =
192 square inches
B) Type of Outlet Opening (Check One)
x
< 2" Diameter Round
2" High Rectangular
Other:
C) For 2", or Smaller, Round Opening (Ref.: Figure 6a):
i) Width of Trash Rack and Concrete Opening (W,o„ c)
from Table 6a-1
-
Wcoot -
9 inches
ii) Height of Trash Rack Screen (HTR)
HTR =
53 inches
WQCV Pond 501.xis, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 2 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
May 15, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 501)
iii) Type of Screen (Based on Depth H), Describe if "Other" I x S.S. #93 VEE Wire (US Filter)
Other:
iv) Screen Opening Slot Dimension, Describe if "Other"
X
0.139"
(US Filter)
Other:
v) Spacing of Support Rod (D.C.)
0.75
inches
Type and Size of Support Rod (Ref.: Table 6a-2)
#156 VEE
vi) Type and Size of Holding Frame (Ref.: Table 6a-2)
3/8 in. x 1.0 in. flat bar
D) For 2" High Rectangular Opening (Refer to Figure 6b):
1) Width of Rectangular Opening (W)
W =
inches
ii) Width of Perforated Plate Opening (Wca , = W + 12")
Wmnc =
inches
iii) Width of Trashrack Opening (Wapen,ng) from Table 6b-1
Wwen;ng =
inches
iv) Height of Trash Rack Screen (HTR)
HTR =
inches
v) Type of Screen (based on depth H) (Describe if "Other")
KlempTm
KPP Series Aluminum
Other.
vi) Cross -bar Spacing (Based,on Table 6b-1, KlempT" KPP
inches
Grating). Describe if "Other"
Other:
vii) Minimum Bearing Bar Size (KlempTm Series, Table 6b-2)
4. Detention Basin length to width ratio I (L/W )
5 Pre -sedimentation Forebay Basin - Enter design values
A) Volume (5 to 10% of the Design Volume in 1 D) acre-feet
B) Surface Area acres
C) Connector Pipe Diameter inches
(Size to drain this volume in 5-minutes under inlet control)
D) Paved/Hard Bottom and Sides yes/no
WQCV Pond 501.xls, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 3 of 3
Designer: Brad Kugler
Company: Stantec
Date: May 15, 2008
Project: Harmony Tech Park
Location: Fort Collins (Pond 501)
6. Two -Stage Design
A) Top Stage (Dwo = 2' Minimum)
Dwo =
feet
Storage=
acre-feet
B) Bottom Stage (DBs = Dwo+ 1.5' Minimum, Dwo+ 3.0' Maximum,
D� =
feet
Storage = 5% to 15% of Total W OCV)
Storage=
acre-feet
Surf. Area=
acres
C) Micro Pool (Minimum Depth = the Larger of
Depth=
feet
0.5 " Top Stage Depth or 2.5 Feet)
Storage=
acre-feet
Surf. Area=
acres
D) Total Volume: Vol,,, = Storage from 5A + 6A + 6B
Vol,o, =
acre-feet
Must be > Design Volume in 1 D
7. Basin Side Slopes (Z, horizontal distance per unit vertical)
Z =
(horizontal/vertical)
Minimum Z = 4, Flatter Preferred
8. Dam Embankment Side Slopes (Z, horizontal distance)
Z =
4,00 (horizontal/vertical)
per unit vertical) Minimum Z = 3, Flatter Preferred
9. Vegetation (Check the method or describe "Other")
Native Grass
Irrigated Turf Grass
Other:
Notes'
WQCV Pond 501.xls, EDB
tmp#56.txt
POND 600
#Units=Elevation,ft,Area,ft2,volume,acft,volume,acft
# Elev Area Cumml Avg Cumml Conic
# ft ft2 acft acft
4911.0000 35026.0383 2.6878 2.6420
4910.0000
32167.9764
1.9165
1.8709
'
4909.0000
29410.4444
1.2097
1.1643
4908.0000
26753.4422
0.5650
0.5199
4907.0000
11140.3293
0.1300
0.0978
1
II
4906.0000 189.2611 0.0000 0.0000
rage 1
91
Harmony Technology Park STANTEC
Pond 600 Orifice Calculation 187710640
100-Year Pond Orifice Plate
Basic Equation:
Q=Cd•A•(2g•(h1-h2))0.5
Revised Equation:
A=Q/(Cd • (2g • (h1 - h2 ))0.5
Input
Basin Area =
12.38
Contributing Drainage Area
Cd=
0.65
Input
g=
32.20 ftls2
Gravitational Constant
h1=
4911.00
100 year WSEL
h2=
4906.00
Invert Elevation of Pipe
Q =
10.00 cfs
Input
A= 0.86 ft` Calculated orifice area
`r— 6.27 Calculated radius (inches)
Orifice opening bottom aligned with invert of pipe, difference in
head on the orifice measured from the centerline of the orifice opening
Orifice Dia. = 12.5376 inches
1.0448 feet
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Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 1 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 600)
1. Basin Storage Volume
Ia = 80.00 %
A) Tributary Area's Imperviousness Ratio (i = Ie / 100) = 0.80
B) Contributing Watershed Area (Area) Area = 12.38 acres
C) Water Quality Capture Volume (WQCV) WQCV = 0.33 watershed inches
(WQCV=1.0*(0.91 *13-1.19*12+0.78*1))
D) Design Volume: Vol = (WQCV / 12) * Area * 1.2 Vol = 0.406 acre-feet
2. Outlet Works
A) Outlet Type (Check One) X Orifice Plate
Perforated Riser Pipe
Other.
B) Depth at Outlet Above Lowest Perforation (H)
H =
1.73
feet
C) Required Maximum Outlet Area per Row, (A.)
A. =
1.06
square inches
D) Perforation Dimensions (enter one only):
i) Circular Perforation Diameter OR
D =
0.8000
inches, OR
ii) 2" Height Rectangular Perforation Width
W =
inches
E) Number of Columns (nc, See Table 6a-1 For Maximum)
nc =
2
number
F) Actual Design Outlet Area per Row (AJ
Ao =
1.01
square inches
G) Number of Rows (nr)
nr =
5
number
H) Total Outlet Area (Ao,)
Ao, =
5.22
square inches
3. Trash Rack
A) Needed Open Area: A, = 0.5 * (Figure 7 Value) * Ao, A, = 182 square inches
B) Type of Outlet Opening (Check One) x < 2" Diameter Round
2" High Rectangular
Other:
C) For 2", or Smaller, Round Opening (Ref.: Figure 6a):
I) Width of Trash Rack and Concrete Opening (W,o ,)
from Table 6a-1 W co„c = 12 inches
ii) Height of Trash Rack Screen (HTR) HTR = 45 inches
WQCV Pond 600.x1s, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 2 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 600)
iii) Type of Screen (Based on Depth H), Describe if "Other"
x
S.S. #93 VEE Wire (US Filter)
Other:
iv) Screen Opening Slot Dimension, Describe if "Other"
X
0.139" (US Filter)
Other:
v) Spacing of Support Rod (O.C.)
1.00
inches
Type and Size of Support Rod (Ref.: Table 6a-2)
TE 0.074 in. x 0.50 in.
vi) Type and Size of Holding Frame (Ref.: Table 6a-2)
0.75 in. x 1.00 in. angle
D) For 2" High Rectangular Opening (Refer to Figure 6b):
1) Width of Rectangular Opening (W)
W =
inches
ii) Width of Perforated Plate Opening (W,oe, = W + 12")
W�„e =
inches
iii) Width of Trashrack Opening (Wope ing) from Table 6b-1
Wopee;,,g =
inches
iv) Height of Trash Rack Screen (HTR)
HTR =
inches
v) Type of Screen (based on depth H) (Describe if "Other")
KlempTm KPP Series Aluminum
Other:
vi) Cross -bar Spacing (Based on Table 6b-1, KlempTm KPP
inches
Grating). Describe if "Other"
Other:
vii) Minimum Bearing Bar Size (KlempTM Series, Table 6b-2)
(Based on depth of WOCV surcharge)
4. Detention Basin length to width ratio (L/W)
5 Pre -sedimentation Forebay Basin - Enter design values
A) Volume (5 to 10% of the Design Volume in 1 D) acre-feet
B) Surface Area acres
C) Connector Pipe Diameter inches
(Size to drain this volume in 5-minutes under inlet control)
D) Paved/Hard Bottom and Sides yes/no
WCCV Pond 600.xls, EDB
Design Procedure Form: Extended Detention Basin (EDB) - Sedimentation Facility
Sheet 3 of 3
Designer:
Brad Kugler
Company:
Stantec
Date:
March 13, 2008
Project:
Harmony Tech Park
Location:
Fort Collins (Pond 600)
6.
Two -Stage Design
A) Top Stage (Dwo = 2' Minimum)
Dwo =
feet
Storage=
acre-feet
B) Bottom Stage (DBs = Dwo+ 1.5' Minimum, Dwo+ 3.0' Maximum,
Das =
feet
Storage = 5% to 15% of Total W QCV)
Storage=
acre-feet
Surf. Area=
acres
C) Micro Pool (Minimum Depth = the Larger of
Depth=
feet
0.5' Top Stage Depth or 2.5 Feet)
Storage=
acre-feet
Surf. Area=
acres
D) Total Volume: Vol,,, = Storage from 5A + 6A + 6B
Vol,o, =
acre-feet
Must be > Design Volume in 1 D
7.
Basin Side Slopes (Z, horizontal distance per unit vertical)
Z =
(horizontal/vertical)
Minimum Z = 4, Flatter Preferred
8.
Dam Embankment Side Slopes (Z, horizontal distance)
Z =
4.00 (horizontal/vertical)
per unit vertical) Minimum Z = 3, Flatter Preferred
9.
Vegetation (Check the method or describe "Other")
Native Grass
Irrigated Turf Grass
Other:
Notes:
WQCV Pond 600.x1s, EDB
I
1
1
1
1
1
J
H
I
1
5
1
i
1
1
1
1
1
APPENDIX E
1
I
1
1
1
1 SWMM AND RATIONAL EXHIBITS
1
1
1
i
1
r
1
i
1
1
1
1
1
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Bill
s'I
\ INTEL
,il j rr j, / �_-\ (HTP FIRST FILING)
pRwl ei
/ fin` lcnol��
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I I
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PIPEB DITCH I \\
I l 11 \
/ I I
II l ,got
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V A A 1 A
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wooloolI
EXISTING
INLET AND IT
STORM PIPE
IwT1*1
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1\ \PIPEBDR I DRAINAGE DITCH ;l
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1
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I
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EXISTING DETENTION
24-STORM
15' STORM
IIG DETENTION
EXISTING 30- STORM
EXISTING W-STORM
EXISTING 38' STORM
ELLIPTICAL STORM
36- STORM
LEGEND
—(4915)— EXISTING INDE%CONTOUR -S ET IMERbLL
--(4916)-- EXISTING INTERMEONRECONTOUR-1 Fftl
DRAINTGE BRSIN ROUNI LINE
ID1 BPSIN ID
&25 - AGRES
® - - INAGE DESIGN POINT
HYDROLOGY TABLE
Design
III
Baalnlal
Area
lacnl
compos8a
G.
010 (c1e)
aim (cb)
EX-1
EX-1
6708
0.32
2728
72.86
EXE
EX-2
0.55
085
1.85
4.24
EXE
IX-3
a."
0.85
261
8.4E
EXE
EX-4
1099
0.32
6.08
16,41
EX-5
IX-5
0.E4
085
1,91
5.01
EXE
EXE
0.97
DES
3.39
8.92
EX-7
EX-7
47,83
0.32
22.33
59.53
EXE
EX-8
3.25
085
535
14.75
06-1
OS-1
TAB
0.85
4.W
12,40
06-2
OS-2
1,03
085
3.40
aBE
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EXHIBIT
NOTFOR
C NSTRUCTON
M*t wmem. 1877108C0
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u -- xr IIr m.1eu
M1m
DNNinTNo. RATIONAL
Reason Stan
loft
Y �I
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J11<<`
I iv
I.J �
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RIII
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s9�o
501
/
/
-
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/
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PROPQS
D2d'ST(
801
I]Z]S+bY� iL•ti
O
449 HP
Ir
1
/ /
PROPOSE V9TORM /
00
210 OT=5c(s /. 60 /OT=10dsJ/
/ PROPOSEDSTORM
12
Q1 � OUTLET
S� // ���✓///
1 PROjps Es 8'STORM
205
OT = 10 cfs I
—+MRivIONYTECHNOLOGY PARRKi
° ----- 7 ` ----/ -
U PROPOSED 30'IISTORM
I / / RPPOSE9124' STORM f� /
PROPpSEO'✓o" STORM
/
100 V ��
II
rl
STORM OUTLET
� EXISTING 24' STORM
TO BE ABANDONED
PROPOSED 46' STORM
U-STORM
PROPOSED 24' STORM
� PROPOSED STORM OUTLET
EXISTING IT STORM
TOSEABANDONED
`-EXISTING 30' STORM
PROPOSED 46' STORM
,�EXISTING 36- STORM
TOSEASANDONED
EXISTING 38' STORM
O�= 15 cfs
PROPOSED 24-STORM
EXISTING 0' X 0'
ELLIP ICALSTORM
36'STORM
LEGEND
—(4915)—EXIBTNG
INDEXW OJR-6 FT INTERN&
----(4916)----
EXI5TNGINTEPMEGIATECONT0UR-1 71NMWR
8
SWMM BASIN
1W
DETEMIONPo D
201
NDOE
SUBBASIN W NIMN
500
ROUTNG ELEMENT
—
BP.4NB ND Y
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EXHIBR
NM FM
CONSTRUCTION
18771WO
R Nm:SIW_EANdLO]-IFIR
IB N 1m[ N.16m
IXJ. pw. 1YLBm
DmNNO. SWMM
Rm& SNlet
1 0l 1