HomeMy WebLinkAboutW.O. 1375-74; Rancho Carrillo Village L-Horton; Rancho Carrillo Village L; 1999-04-15HUNSAKER
^ASSOCIATES
SAN DIEGO, INC.
PLANNING
ENGINEERING
SURVEYING
IRVINE
LAS VEGAS
RIVERSIDE
SAN DIEGO
PRELIMINARY
HYDROLOGY STUDY
for
RANCHO CARRILLO
VILLAGE L
City of San Diego, California
Prepared for:
D.R. Morton
1010 South Coast Highway 101
Suite 101
Encinitas, CA 92024
W.O. 1375-74
April 15, 1999
DAVE HAMMAR
JACK HILL
LEX WILLIMAN
10179 Huennekens St.
Suite 200
San Diego, CA 92121
(619) 558-4500 PH
(619) 558-1414 FX
www. hunsaker.com
lnfo@HunsakerSD.com
Hunsaker & Associates
San Diego, Inc.
David A. Hammar, R.C.E.
President
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Rancho Carrillo - Village L
Hydrology Study
TABLE OF CONTENTS
SECTION
Executive Summary I
Introduction I
Summary of Results I
References I
Vicinity Map II
Methodology & Model Development III
Peak Flowrate Determination II!
Hydrologic Analysis -100 Year Return Interval IV
Reference Data V
Hydrology Map (pocket)
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Rancho Carrillo - Village L
Hydrology Study
EXECUTIVE SUMMARY
Introduction
Village L of the Rancho Carrillo development is located east of Melrose Drive in
the City of Carlsbad. The site, which has a drainage area of roughly 5 acres, will
drain to an existing 18-inch RCP located on the northwest side of the
development.
All site runoff will be intercepted by a series of four curb inlets, two of which will
be placed in roadway sag locations and the other two located in a flow by
location.
This hydrologic analysis determines the peak flowrates for the Village L
development based on a 6-hour rainfall duration and a 100-year return interval.
Methodology for the analysis appears in Section III, results appear in Section IV,
and reference data such as rainfall nomographs and runoff coefficients appear in
Section V.
Inlet locations and existing pipe sizes appear on the hydrology map located in
the pocket at the end of this report.
Summary of Results
Table 1 below summarizes the results of the hydrologic analysis. Curb inlets for
this analysis will be designed to intercept 100 percent of the runoff.
Table 1 - Hydrologic Results
100-Year Design Storm
Inlet
Node
Number
103.0
115.5
107.0
113.0
Flow
Condition
Flow by
Flow by
Sump
Sump
100-Year
Peak Flow
(cfs)
4.58
1.10
2.63
8.97
Drainage
Area
(acres)
1.20
0.29
0.70
2.70
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W.O. 1375-74 04/15/99
Rancho Carrillo -Village L
Hydrology Study
Table 2 below summarizes the preliminary pipe sizing for the storm drain
systems in the analysis. Final pipe sizes will be determined after a hydraulic
analysis has been performed. All pipes are assumed to be RCP.
Initial calculations show that a 24-inch RCP will convey the total runoff from the
site to the existing pipe along the property's northwest boundary.
Table 2 - Preliminary Pipe Sizing
100 Year Design Storm
Upstream
Node
Number
103.0
115.5
107.0
113.0
200.0 '
Downstream
Node
Number
115.5
200.0
200.0
200.0
500.0
Pipe
Size
(inches)
18
18
18
18
24
100-Year
Peak Flow
(cfs)
4.58
5.61
2.63
8.79
16.37
Drainage
Area
(acres)
1.2
1.5
0.7
2.7
4.9
References 1. City of San Diego Drainage Design Manual, 1984.
2. County of San Diego Drainage Design & Procedure Manual,
1985.
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W.0.1375-74 Q4/1SS9
CITY OF OCEANSIOE
PROJECT LOCATION
CITY OF
SAN MARCOS
CITY OF ENC1N1TA5
RANCHO CARRILLO
FIGURE 1
VICINITY MAP
Ill
Rancho Carrillo -Village L
Hydrology Study
METHODOLOGY &
MODEL DEVELOPMENT
Peak Flowrate Determination
Design Storm 100-year return interval
Land Use Mostly multi-family residential; some open space
Soil Type Hydrologic soil group D
Runoff Coefficient In accordance with County of San Diego standards, a runoff
coefficient of 0.7 was selected for most areas and 0.45 for
the recreational areas.
Rainfall Intensity Initial time of concentration values were determined using
the County of San Diego's overland flow nomograph for
urban watersheds. Intensity values were derived from the
County's 1985 Intensity-Duration nomograph.
Method of Analysis - The Rational Method is the most widely used hydrologic
model for estimating peak runoff rates. Applied to small
urban and semi-urban areas with drainage areas less than
0.5 square miles, the Rational Method relates storm rainfall
intensity, a runoff coefficient, and drainage area to peak
runoff rate. This relationship is expressed by the equation:
Q = CIA, where:
Q = The peak runoff rate in cubic feet per second at the
point of analysis.
C = A runoff coefficient representing the area - averaged
ratio of runoff to rainfall intensity.
I = The time-averaged rainfall intensity in inches per hour
corresponding to the time of concentration.
A = The drainage basin area in acres.
In performing a node-link study, the total watershed area is
divided into subareas which discharge at designated nodes.
Subbasins are delineated based upon locations of inlets,
ridge lines, confluences, etc.
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Rancho Carrillo - Village L
Hydrology Study
The procedure for the Subarea Summation Model is as
follows:
(1) Subdivide the watershed into subareas with the initial
subarea being less than 10 acres in size (generally 1
lot will do), and subsequent subareas gradually
increasing in size. Assign upstream and downstream
nodal numbers to each subarea to correlate
calculations to the watershed map.
(2) Estimate a Tc by using a nomograph or overland flow
velocity estimation.
(3) Using Tc, determine the corresponding values of I.
Then Q = C I A.
(4) Using Q, estimate the travel time between this node
and the next by Manning's equation as applied to the
particular channel or conduit linking the two nodes.
The nodes are joined together by links, which may be street
gutter flows, drainage swales or drainage ditches. The
Computer subarea menu is as follows:
Enter Upstream node number
Enter Downstream node number
SUBAREA HYDROLOGIC PROCESS
1. Confluence analysis at node.
2. Initial subarea analysis.
3. Pipeflow travel time (computer estimated).
4. Pipeflow travel time (user specified).
5. Trapezoidal channel travel time.
6. Street flow analysis through subarea.
7. User - specified information at node.
8. Addition of sub area runoff to main line.
9. V-gutter flow through area.
Select subarea hydrologic process
The engineer enters in the pertinent nodes, and then the
hydrologic process. At the confluence point of two or more
basins, the following procedure is used to adjust the total
summation of peak flow rates to allow for differences in
basin times of concentration. This adjustment is based on
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Rancho Carrillo - Village L
Hydrology Study
the assumption that each basin's hydrographs are triangular
in shape.
(1). If the collection streams have the same times of
concentration, then the Q values are directly
summed,
Qp = Qa + Qb; Tp = Ta = Tb
(2). If the collection streams have different times of
concentration, the smaller of the tributary Q values
may be adjusted as follows:
(i). The most frequent case is where the collection
stream with the longer time of concentration
has the larger Q. The smaller Q value is
adjusted by the ratio of rainfall intensities.
Qp = Qa + Qb (|a/]b); Tp = Ta
(ii). In some cases, the collection stream with the
shorter time of concentration has the larger Q.
Then the smaller Q is adjusted by a ratio of the
T values.
QP = Qb + Qa (Tt/Ta); Tp = Tb
Underground storm drains are analyzed in a similar way.
Flow data obtained from the surface model for inlets and
collection points are input into the nodes representing those
structures. Design grades and lengths are used to compute
the capacity of the storm drains and to model the
downstream travel times.
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W.O. 1375-74 04H5/99
IV
****************************************************************************
RATIONAL METHOD HYDROLOGY COMPUTER PROGRAM PACKAGE
Reference: SAN DIEGO COUNTY FLOOD CONTROL DISTRICT
1985,1981 HYDROLOGY MANUAL
(c) Copyright 1982-93 Advanced Engineering Software (aes)
Ver. 1.5A Release Date: 7/10/93 License ID 1239
Analysis prepared by:
HUNSAKER & ASSOCIATES
Irvine, Inc.
Planning * Engineering * Surveying
Three Hughes * Irvine , California 92718 * (714) 538-1010
************************** DESCRIPTION OF STUDY **************************
* RANCHO CARRILLO VILLAGE "L" *
* W0# 1375-74 *
* 100 YEAR - 6 HOUR PRECIPITATION *
**************************************************************************
FILE NAME: 1375\74\RC500.RAT
TIME/DATE OF STUDY: 16: 7 4/ 8/1999
USER SPECIFIED HYDROLOGY AND HYDRAULIC MODEL INFORMATION:
1985 SAN DIEGO MANUAL CRITERIA
USER SPECIFIED STORM EVENT(YEAR) = 100.00
6-HOUR DURATION PRECIPITATION (INCHES) = 2.900
SPECIFIED MINIMUM PIPE SIZE(INCH) = 18.00
SPECIFIED PERCENT OF GRADIENTS(DECIMAL) TO USE FOR FRICTION SLOPE = .90
SAN DIEGO HYDROLOGY MANUAL "C"-VALUES USED
NOTE: ONLY PEAK CONFLUENCE VALUES CONSIDERED
****************************************************************************
FLOW PROCESS FROM NODE 114.00 TO NODE 114.50 IS CODE = 21
>»»RATIONAL METHOD INITIAL SUBAREA ANALYSIS<««
*USER SPECIFIED(SUBAREA):
RURAL DEVELOPMENT RUNOFF COEFFICIENT = .6500
INITIAL SUBAREA FLOW-LENGTH = 90.00
UPSTREAM ELEVATION = 353.50
DOWNSTREAM ELEVATION = 352.00
ELEVATION DIFFERENCE = 1.50
URBAN SUBAREA OVERLAND TIME OF FLOW(MINUTES) = 6.481
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 6.463
SUBAREA RUNOFF(CFS) = .38
TOTAL AREA(ACRES) = .09 TOTAL RUNOFF(CFS) = .38
****************************************************************************
FLOW PROCESS FROM NODE 115.00 TO NODE 115.50 IS CODE = 6
_____ — __ — _____ — — — — ____ — _. _ ___._.__,-i_.__--.--_.-._ --i — — — — — — — — — — — — — •-.— — __ — — -_. — — — _ — ._. — — — -..-._-. — .-•.-,_____.
>»»COMPUTE STREETFLOW TRAVELTIME THRU SUBAREA<««
UPSTREAM ELEVATION = 353.00 DOWNSTREAM ELEVATION = 350.00
STREET LENGTH(FEET) = 200.00 CURB HEIGHT(INCHES) = 6.
STREET HALFWIDTH(FEET) = 15.00
DISTANCE FROM CROWN TO CROSSFALL GRADEBREAK 7.50
INTERIOR STREET CROSSFALL(DECIMAL) = .020
OUTSIDE STREET CROSSFALL(DECIMAL) = .020
SPECIFIED NUMBER OF HALFSTREETS CARRYING RUNOFF = 1
**TRAVELTIME COMPUTED USING MEAN FLOW(CFS) = .74
STREETFLOW MODEL RESULTS:
STREET FLOWDEPTH(FEET) = .23
HALFSTREET FLOODWIDTH(FEET) = 5.30
AVERAGE FLOW VELOCITY (FEET/SEC.) = 1.86
PRODUCT OF DEPTH&VELOCITY = .43
STREETFLOW TRAVELTIME(MIN) = 1.79 TC(MIN) = 8.28
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 5.521
*USER SPECIFIED(SUBAREA):
RURAL DEVELOPMENT RUNOFF COEFFICIENT = .6500
SUBAREA AREA(ACRES) = .20 SUBAREA RUNOFF(CFS) = .72
SUMMED AREA(ACRES) = .29 TOTAL RUNOFF(CFS) = 1.10
END OF SUBAREA STREETFLOW HYDRAULICS:
DEPTH(FEET) = .25 HALFSTREET FLOODWIDTH(FEET) = 6.14
FLOW VELOCITY(FEET/SEC.) = 2.21 DEPTH*VELOCITY = .55
*************************************************************************
FLOW PROCESS FROM NODE 115.50 TO NODE 115.50 IS CODE = 1
____________.__-„ — — — __• — _______-_-^ — — — — — «_______ — — — _»___*. — — — — — _ __ — _____-_ — — — _ _ — ™ ™ — — —
>»»DESIGNATE INDEPENDENT STREAM FOR CONFLUENCE«<«
TOTAL NUMBER OF STREAMS = 2
CONFLUENCE VALUES USED FOR INDEPENDENT STREAM 1 ARE:
TIME OF CONCENTRATION(MIN.) = 8.28
RAINFALL INTENSITY(INCH/HR) = 5.52
TOTAL STREAM AREA(ACRES) = .29
PEAK FLOW RATE(CFS) AT CONFLUENCE = 1.10
****************************************************************
FLOW PROCESS FROM NODE 100.00 TO NODE 101.00 IS CODE = 21
>»»RATIONAL METHOD INITIAL SUBAREA ANALYSIS<««
SOIL CLASSIFICATION IS "D"
MULTI-UNITS DEVELOPMENT RUNOFF COEFFICIENT = .7000
INITIAL SUBAREA FLOW-LENGTH = 115.00
UPSTREAM ELEVATION = 363.60
DOWNSTREAM ELEVATION = 362.20
ELEVATION DIFFERENCE = 1.40
URBAN SUBAREA OVERLAND TIME OF FLOW(MINUTES) = 7.231
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 6.023
SUBAREA RUNOFF(CFS) = 1.26
TOTAL AREA(ACRES) - .30 TOTAL RUNOFF(CFS) = 1.26
*******************************************************
FLOW PROCESS FROM NODE 102.00 TO NODE 103.00 IS CODE =
>»»COMPUTE STREETFLOW TRAVELTIME THRU SUBAREA<««
UPSTREAM ELEVATION = 358.00 DOWNSTREAM ELEVATION = 350.00
STREET LENGTH(FEET) = 340.00 CURB HEIGHT(INCHES) =6.
STREET HALFWIDTK(FEET) = 15.00
DISTANCE FROM CROWN TO CROSSFALL GRADEBREAK = 7.50
INTERIOR STREET CROSSFALL(DECIMAL) = .020
OUTSIDE STREET CROSSFALL(DECIMAL) = .020
SPECIFIED NUMBER OF HALFSTREETS CARRYING RUNOFF = 1
**TRAVELTIME COMPUTED USING MEAN FLOW(CFS) = 2.90
STREETFLOW MODEL RESULTS:
STREET FLOWDEPTH(FEET) = .30
HALFSTREET FLOODWIDTH(FEET) = 8.67
AVERAGE FLOW VELOCITY(FEET/SEC.) = 3.34
PRODUCT OF DEPTH&VELOCITY = 1.00
STREETFLOW TRAVELTIME(MIN) = 1.70 TC(MIN) = 8.93
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 5.257
SOIL CLASSIFICATION IS "D"
MULTI-UNITS DEVELOPMENT RUNOFF COEFFICIENT = .7000
SUBAREA AREA(ACRES) = .90 SUBAREA RUNOFF(CFS) = 3.31
SUMMED AREA(ACRES) = 1.20 TOTAL RUNOFF(CFS) = 4.58
END OF SUBAREA STREETFLOW HYDRAULICS:
DEPTH(FEET) = .33 HALFSTREET FLOODWIDTH(FEET) = 10.36
FLOW VELOCITY(FEET/SEC.) = 3.84 DEPTH*VELOCITY = 1.28
************************************************************
FLOW PROCESS FROM NODE 103.00 TO NODE 115.50 IS CODE = 3
>»»COMPUTE PIPEFLOW TRAVELTIME THRU SUBAREA<««
>»»USING COMPUTER-ESTIMATED PIPESIZE (NON-PRESSURE FLOW) <««
ESTIMATED PIPE DIAMETER(INCH) INCREASED TO 18.000
DEPTH OF FLOW IN 18.0 INCH PIPE IS 8.6 INCHES
PIPEFLOW VELOCITY(FEET/SEC.) = 5.5
UPSTREAM NODE ELEVATION = 344.00
DOWNSTREAM NODE ELEVATION = 343.70
FLOWLENGTH(FEET) = 30.00 MANNING'S N = .013
ESTIMATED PIPE DIAMETER(INCH) = 18.00 NUMBER OF PIPES = 1
PIPEFLOW THRU SUBAREA(CFS) = 4.58
TRAVEL TIME(MIN.) = .09 TC(MIN.) = 9.02
****************************************************************************
FLOW PROCESS FROM NODE 115.50 TO NODE 115.50 IS CODE - 1
>»»DESIGNATE INDEPENDENT STREAM FOR CONFLUENCE<««
>»»AND COMPUTE VARIOUS CONFLUENCED STREAM VALUES<««
TOTAL NUMBER OF STREAMS = 2
CONFLUENCE VALUES USED FOR INDEPENDENT STREAM 2 ARE:
TIME OF CONCENTRATION(MIN.) = 9.02
RAINFALL INTENSITY(INCH/HR) = 5.22
TOTAL STREAM AREA(ACRES) = 1.20
PEAK FLOW RATE(CFS) AT CONFLUENCE = 4.58
** CONFLUENCE DATA **
STREAM RUNOFF Tc
NUMBER (CFS) (MIN.
1 1.10 8.28
2 4.58 9.02
INTENSITY
(INCH/HOUR)
5.521
5.223
AREA
(ACRE)
.29
1.20
— RAINFALL INTENSITY AND TIME OF CONCENTRATION RATIO
CONFLUENCE FORMULA USED FOR 2 STREAMS.
** PEAK FLOW RATE TABLE **
STREAM RUNOFF Tc
NUMBER (CFS) (MIN.
1 5.43 8.28
2 5.61 9.02
INTENSITY
(INCH/HOUR)
5.521
5.223
COMPUTED CONFLUENCE ESTIMATES ARE AS FOLLOWS
PEAK FLOW RATE(CFS) = 5.61 Tc(MIN.) =
TOTAL AREA(ACRES) = 1.49
9.02
*****************************************************************
FLOW PROCESS FROM NODE 115.50 TO NODE 200.00 IS CODE =
>»»COMPUTE PIPEFLOW TRAVELTIME THRU SUBAREA<««
»»>USING COMPUTER-ESTIMATED PIPESIZE (NON-PRESSURE FLOW)
ESTIMATED PIPE DIAMETER(INCH) INCREASED
DEPTH OF FLOW IN 18.0 INCH PIPE IS 9
PIPEFLOW VELOCITY(FEET/SEC.
UPSTREAM NODE ELEVATION =
DOWNSTREAM NODE ELEVATION =
FLOWLENGTH(FEET) = 200.00
5.8
343.70
341.70
MANNING'S
ESTIMATED PIPE DIAMETER(INCH) = 18.00
PIPEFLOW THRU SUBAREA(CFS) = 5.61
TRAVEL TIME(MIN.) = .57 TC(MIN.)
TO 18.000
7 INCHES
N = .013
NUMBER OF PIPES
9.59
****************************************************************************
FLOW PROCESS FROM NODE 200.00 TO NODE 200.00 IS CODE = 10
»»>MAIN-STREAM MEMORY COPIED ONTO MEMORY BANK # 1 ««<
****************************************************************************
FLOW PROCESS FROM NODE 104.00 TO NODE 105.00 IS CODE = 21
>»»RATIONAL METHOD INITIAL SUBAREA ANALYSIS«<«
SOIL CLASSIFICATION IS "D"
MULTI-UNITS DEVELOPMENT RUNOFF COEFFICIENT = .7000
INITIAL SUBAREA FLOW-LENGTH = 100.00
UPSTREAM ELEVATION = 350.20
DOWNSTREAM ELEVATION = 349.50
ELEVATION DIFFERENCE = .70
URBAN SUBAREA OVERLAND TIME OF FLOW(MINUTES) = 8.109
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 5.594
SUBAREA RUNOFF(CFS) = 1.17
TOTAL AREA(ACRES) = .30 TOTAL RUNOFF(CFS) = 1.17
****************************************************************************
FLOW PROCESS FROM NODE 106.00 TO NODE 107.00 IS CODE = 6
>»»COMPUTE STREETFLOW TRAVELTIME THRU SUBAREA«<«
- UPSTREAM ELEVATION = 349.00 DOWNSTREAM ELEVATION = 347.70
STREET LENGTH(FEET) = 130.00 CURB HEIGHT(INCHES) = 6.
— STREET HALFWIDTH(FEET) = 15.00
"" DISTANCE FROM CROWN TO CROSSFALL GRADEBREAK = 7.50
« INTERIOR STREET CROSSFALL(DECIMAL) = .020
OUTSIDE STREET CROSSFALL(DECIMAL) = .020
-«M
SPECIFIED NUMBER OF HALFSTREETS CARRYING RUNOFF = 1•m
« **TRAVELTIME COMPUTED USING MEAN FLOW(CFS) = 1.90
STREETFLOW MODEL RESULTS:
STREET FLOWDEPTH(FEET) = .30
m HALFSTREET FLOODWIDTH(FEET) = 8.67
AVERAGE FLOW VELOCITY(FEET/SEC.) = 2.19
PRODUCT OF DEPTH&VELOCITY = .66
STREETFLOW TRAVELTIME(MIN) = .99 TC(MIN) = 9.10
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 5.193
*" SOIL CLASSIFICATION IS "D"
M MULTI-UNITS DEVELOPMENT RUNOFF COEFFICIENT = .7000
SUBAREA AREA (ACRES) = .40 SUBAREA RUNOFF (CFS) = 1.45
- SUMMED AREA(ACRES) = .70 TOTAL RUNOFF(CFS) = 2.63
END OF SUBAREA STREETFLOW HYDRAULICS:
"" DEPTH(FEET) = .33 HALFSTREET FLOODWIDTH(FEET) = 10.36
„. FLOW VELOCITY(FEET/SEC.) = 2.21 DEPTH*VELOCITY = .74
**************************
FLOW PROCESS FROM NODE 107.00 TO NODE 200.00 IS CODE =
>»»COMPUTE PIPEFLOW TRAVELTIME THRU SUBAREA<««
>»»USING COMPUTER-ESTIMATED PIPESIZE (NON-PRESSURE FLOW).
ESTIMATED PIPE DIAMETER (INCH) INCREASED
DEPTH OF FLOW IN 18.0 INCH PIPE IS 6
PIPEFLOW VELOCITY (FEET/SEC.) = 4.8
UPSTREAM NODE ELEVATION = 341.90
DOWNSTREAM NODE ELEVATION = 341.70
FLOWLENGTH(FEET) = 20.00 MANNING'S
TO
.3
N
18.000
INCHES
= .013
ESTIMATED PIPE DIAMETER(INCH) = 18.00 NUMBER OF PIPES = 1
PIPEFLOW THRU SUBAREA(CFS) = 2.63
TRAVEL TIME(MIN.) = .07 TC{MIN.) = 9.17
****************************************************************************
FLOW PROCESS FROM NODE 200.00 TO NODE 200.00 IS CODE = 1
>»»DESIGNATE INDEPENDENT STREAM FOR CONFLUENCE<««
TOTAL NUMBER OF STREAMS = 2
CONFLUENCE VALUES USED FOR INDEPENDENT STREAM 1 ARE:
TIME OF CONCENTRATION(MIN.) = 9.17
RAINFALL INTENSITY(INCH/HR) = 5.17
TOTAL STREAM AREA(ACRES) = .70
PEAK FLOW RATE(CFS) AT CONFLUENCE = 2.63
************************************************************
FLOW PROCESS FROM NODE 110.00 TO NODE 111.00 IS CODE = 21
>»»RATIONAL METHOD INITIAL SUBAREA ANALYSIS<««
SOIL CLASSIFICATION IS "D"
MULTI-UNITS DEVELOPMENT RUNOFF COEFFICIENT = .7000
INITIAL SUBAREA FLOW-LENGTH - 290.00
UPSTREAM ELEVATION = 366.00
DOWNSTREAM ELEVATION = 353.00
ELEVATION DIFFERENCE = 13.00
URBAN SUBAREA OVERLAND TIME OF FLOW(MINUTES) = 7.437
*CAUTION: SUBAREA SLOPE EXCEEDS COUNTY NOMOGRAPH
DEFINITION. EXTRAPOLATION OF NOMOGRAPH USED.
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 5.915
SUBAREA RUNOFF(CFS) = 2.07
TOTAL AREA(ACRES) = .50 TOTAL RUNOFF{CFS) = 2.07
****************************************************************************
FLOW PROCESS FROM NODE 112.00 TO NODE 113.00 IS CODE = 6
>»»COMPUTE STREETFLOW TRAVELTIME THRU SUBAREA<««
UPSTREAM ELEVATION = 354.00 DOWNSTREAM ELEVATION - 347.70
STREET LENGTH(FEET) = 485.00 CURB HEIGHT(INCHES) = 6.
STREET HALFWIDTH(FEET) = 15.00
DISTANCE FROM CROWN TO CROSSFALL GRADEBREAK = 7.50
INTERIOR STREET CROSSFALL(DECIMAL) = .020
OUTSIDE STREET CROSSFALL(DECIMAL) = .020
SPECIFIED NUMBER OF HALFSTREETS CARRYING RUNOFF = 2
**TRAVELTIME COMPUTED USING MEAN FLOW(CFS) = 5.01
STREETFLOW MODEL RESULTS:
STREET FLOWDEPTH(FEET) = .32
HALFSTREET FLOODWIDTH(FEET) = 9.52
AVERAGE FLOW VELOCITY(FEET/SEC.) = 2.45
PRODUCT OF DEPTH&VELOCITY = .77
STREETFLOW TRAVELTIME(MIN) = 3.31 TC(MIN) = 10.74
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 4.666
SOIL CLASSIFICATION IS "D"
MULTI-UNITS DEVELOPMENT RUNOFF COEFFICIENT = .7000
SUBAREA AREA(ACRES) = 1.80 SUBAREA RUNOFF(CFS) = 5.88
SUMMED AREA(ACRES) = 2.30 TOTAL RUNOFF(CFS) = 7.95
END OF SUBAREA STREETFLOW HYDRAULICS:
DEPTH(FEET) = .35 HALFSTREET FLOODWIDTH(FEET) = 11.20
FLOW VELOCITY(FEET/SEC.) = 2.89 DEPTH*VELOCITY - 1.01
FLOW PROCESS FROM NODE 116.00 TO NODE 117.00 IS CODE =
>»»ADDITION OF SUBAREA TO MAINLINE PEAK FLOW««<
,, 100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 4.666
*USER SPECIFIED(SUBAREA):
— RURAL DEVELOPMENT RUNOFF COEFFICIENT = .4500
SUBAREA AREA(ACRES) = .20 SUBAREA RUNOFF(CFS) = .42
*" TOTAL AREA (ACRES) = 2.50 TOTAL RUNOFF (CFS) = 8.37
_ TC(MIN) = 10.74
urn
**********************************************************
"* FLOW PROCESS FROM NODE 118.00 TO NODE 119.00 IS CODE = 8
*" >»»ADDITION OF SUBAREA TO MAINLINE PEAK FLOW<««
*»_________________,__________._________..____.__._.__ = =: = = = = = = = = = = = — ==: = = = =; = = = = = = = = =:
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 4.666
- *USER SPECIFIED(SUBAREA):
«. INDUSTRIAL DEVELOPMENT RUNOFF COEFFICIENT = .4500
SUBAREA AREA(ACRES) = .20 SUBAREA RUNOFF(CFS) = .42
- TOTAL AREA(ACRES) = 2.70 TOTAL RUNOFF(CFS) = 8.79
TC(MIN) = 10.74mm
-••»
****************************************************************************
- FLOW PROCESS FROM NODE 113.00 TO NODE 200.00 IS CODE = 3
*" >»»COMPUTE PIPEFLOW TRAVELTIME THRU SUBAREA<««
^ >»»USING COMPUTER-ESTIMATED PIPESIZE (NON-PRESSURE FLOW) ««<
- DEPTH OF FLOW IN 18.0 INCH PIPE IS 13.1 INCHES
PIPEFLOW VELOCITY(FEET/SEC.) = 6.4
"" UPSTREAM NODE ELEVATION = 341.80
_ DOWNSTREAM NODE ELEVATION = 341.70
FLOWLENGTH(FEET) = 10.00 MANNING'S N = .013
— ESTIMATED PIPE DIAMETER(INCH) = 18.00 NUMBER OF PIPES = 1
PIPEFLOW THRU SUBAREA(CFS) = 8.79
~ TRAVEL TIME(MIN.) = .03 TC(MIN.) = 10.77
_****************************************************************************
FLOW PROCESS FROM NODE 200.00 TO NODE 200.00 IS CODE = 1
»>»DESIGNATE INDEPENDENT STREAM FOR CONFLUENCE<««
>»»AND COMPUTE VARIOUS CONFLUENCED STREAM VALUES«<«
TOTAL NUMBER OF STREAMS = 2
- CONFLUENCE VALUES USED FOR INDEPENDENT STREAM 2 ARE:
— TIME OF CONCENTRATION(MIN.) = 10.77
RAINFALL INTENSITY(INCH/HR) = 4.66
-. TOTAL STREAM AREA (ACRES) =2.70
PEAK FLOW RATE(CFS) AT CONFLUENCE = 8.79
WM
** CONFLUENCE DATA **
"" STREAM RUNOFF Tc INTENSITY AREA
~ NUMBER {CFS) (MIN.) (INCH/HOUR) (ACRE)
1 2.63 9.17 5.167 .70
2 8.79 10.77 4.658 2.70
- RAINFALL INTENSITY AND TIME OF CONCENTRATION RATIO
« CONFLUENCE FORMULA USED FOR 2 STREAMS.
** PEAK FLOW RATE TABLE **
^ STREAM RUNOFF Tc
NUMBER (CFS) (MIN.
** 1 10.55 9.17
2 11.16 10.77
INTENSITY
{INCH/HOUR)
5.167
4.658
<• COMPUTED CONFLUENCE ESTIMATES ARE AS FOLLOWS
PEAK FLOW RATE(CFS) = 11.16 Tc(MIN.) =
- TOTAL AREA (ACRES) = 3.40
10.77
*****************************************************************
FLOW PROCESS FROM NODE 200.00 TO NODE 200.00 IS CODE = 11
>»»CONFLUENCE MEMORY BANK # 1 WITH THE MAIN-STREAM MEMORY<««
** MAIN STREAM CONFLUENCE DATA **
STREAM RUNOFF Tc INTENSITY
NUMBER (CFS) (MIN.) (INCH/HOUR)
1 11.16 10.77 4.658
** MEMORY BANK # 1 CONFLUENCE DATA **
STREAM RUNOFF Tc INTENSITY
NUMBER (CFS) (MIN.) (INCH/HOUR)
1 5.61 9.59 5.019
** PEAK FLOW RATE TABLE **
STREAM RUNOFF Tc
NUMBER (CFS) (MIN.)
1 15.97 9.59
2 16.37 10.77
INTENSITY
(INCH/HOUR)
5.019
4.658
AREA
(ACRE)
3.40
AREA
(ACRE)
1.49
COMPUTED CONFLUENCE ESTIMATES ARE AS FOLLOWS
PEAK FLOW RATE(CFS) = 16.37 Tc(MIN.) =
TOTAL AREA(ACRES) = 4.89
10.77
****************************************************************************
FLOW PROCESS FROM NODE 200.00 TO NODE 200.00 IS CODE = 12
>»»CLEAR MEMORY BANK # 1 «<«
************************************************************
FLOW PROCESS FROM NODE 200.00 TO NODE 500.00 IS CODE =
»»>COMPUTE PIPEFLOW TRAVELTIME THRU SUBAREA<««
»»>USING COMPUTER-ESTIMATED PIPESIZE (NON-PRESSURE FLOW).
DEPTH OF FLOW IN 24.0 INCH PIPE IS 15.7 INCHES
PIPEFLOW VELOCITY(FEET/SEC.:
UPSTREAM NODE ELEVATION =
DOWNSTREAM NODE ELEVATION =
FLOWLENGTH(FEET) = 130.00
7.5
341.70
340.40
MANNING'S
ESTIMATED PIPE DIAMETER(INCH) = 24.00
PIPEFLOW THRU SUBAREA(CFS) = 16.37
TRAVEL TIME(MIN.) = .29 TCfMIN.)
N = .013
NUMBER OF PIPES
= 11.06
END OF STUDY SUMMARY:
PEAK FLOW RATE(CFS) = 16.37 Tc(MIN.) = 11.06
TOTAL AREA(ACRES) = 4.89
END OF RATIONAL METHOD ANALYSIS
V
TABLE 2
P1 RUNOFF COEFFICIENTS (RATIONAL METHOD)-"^
L. DEVELOPED AREAS (URBAN)
"* Land Use Coefficient. C
• Soil Type (l)r** Residential: E)
IT Single Family .55
Multi-Units .70
fc"• -. Mobile Homes . .65™>
^ Rural (lots greater than 1/2 acre) .45 .
— Commercial (2)
80% Impervious ' .85
Industrial (2)
90% Impervious .95
NOTES:
(.1) Type D soil to be used for all areas.
(2) Where actual conditions deviate significantly from the tabulated
imperviousness values of 80% or 90%T the values given for coefficient C,
may be revised by multiplying 80% or 90% by the ratio of actual
imperviousness to the tabulated imperviousness. However, in no case shall
the final coefficient be less than 0.50. For example: Consider commercial
property on D soil.
Actual imperviousness = 50%
Tabulated imperviousness = 80%
Revised C = |g- x 0.85 = 0.53
82
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SAN DIEGO COUNTY
DEPARTMENT OF SPECIAL DISTRICT SERVICES
DESIGN MANUAL
/-• ' V-/',- - ,r ( T:----
URBAN AREAS OVERLAND TIME
OF FLOW CURVES
fWiTF APPENDIX X-C
i m i
I CHART
! Equation: I • * 7.44 P, D "*645
4~ £
I « Intensity (In./Hr.)
Pfi « 6 Hr. Precipitation (In.)
D * Duration (Min.)
lii
30 40 50 1 5 6
Directions for Application;
1) From precipitation naps determine 6 hr. and
24 hr. amounts for the selected frequency.
These maps are printed 1n the County Hydrolon)
Manual (10, 50 And 100 yr. maps included in tfr
Design and Procedure Manual).
2) Adjust 6 hr. precipitation (if necessary) so
that It 1s within the range of 452 to 65% of
the 24 hr. precipitation. (Not applicable
to Desert)
3) Plot 6 hr. precipitation on the right side
of the chart.
4) Draw a line through the point parallel to theplotted lines.
5) This line 1s the intensity-duration curve for
the location being analyzed.
Application Form:
0) Selected Frequency
1) PC s Jn., P0|
yr.
5S*
2) Adjusted *P6«
3) r -
24
In.
m1n.
4) I In/hr.
*Not Applicable to Desert Region
APPENDIX XI
IV-A-14
Rpvi if-d 1
CO, ..i'Y OF SAN DIEGO
DEPARTMENT OF SANITATION
FLOOD CONTROL 100-YEAR 6-HOUR PRECIPITATION
ISOPLUVIALS
PRECIPITATION IN
OF 100-YEAR 6-HOUR
terms or AM IKCII
33'
U.S. DEPARTMEN
NATIONAL OCEANIC AND AT
SPECIAL STUDIES URANC1I, OFFICE OF II
JSPHEHIC ADMINISTRATION
>ROLOGV. NATIONAL WEATHER SERVICE
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