HomeMy WebLinkAboutW.O. 2239-01; Hadley Property-Hadley Trust; Hadley Prpoerty; 1998-09-16HUN SAKE R
^ASSOCIATES
SAN DIEGO, INC.
PLANNING
ENGINEERING
SURVEYING
IRVINE
LAS VEGAS
RIVERSIDE
SAN DIEGO
HYDROLOGY STUDY
for
HADLEY PROPERTY
in the
City of Carlsbad
Prepared for: Hadley Trust
W.O. 2239-01
September 16, 1998
DAVE HAMMAR
JACK HILL
LEXWILLIMAN
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
RA:kd k:\2239\1998\a03.doc
w.o. 2239-1
TABLE OF CONTENTS
References
Introduction
Executive Summary
Vicinity Map
Drainage Criteria and Methodology
100-year Post-Development Hydrology Study
Reference Data
Post-Development Hydrology Map
SECTION
I
I
I
II
III
IV
V
(pocket)
RA:msword\\\pcserveiMiydrology*aes92\2239M \hyd.doc
W.0.2239-1 09/25/99
References 1) The County of San Diego Drainage Design & Procedure
Manual, 1993
2) The County of San Diego Department of Public Works, Public
Roads Standards, 1992
3) Master Drainage and Storm Water Quality Management Plan,
City of Carlsbad, California, March 1994
4) P&D Technologies, Grading & Erosion Control Plans For
Carlsbad Tract 92-3, Drawings Number 341-5A
Introduction Hadley Property lies within the City of Carlsbad, California.
Development is proposed east of Interstate 5, north of Batiquitos
Lagoon, and south of Palomar Airport Road (see fig.1).
The subject project consist of 8.8 acres, made up entirely of
residential single family homes. Of the 8.8 acres, 7.4 acres are
tributary to the existing 30" RCP within Fiona Place (per dwg 341-
5A), which has been constructed to convey a 100-year storm. The
existing storm drain was designed to carry 49.6 cfs. Since the
proposed runoff from this development is 47.1 cfs, downstream
analysis is not required.
Since post-development conditions prove to be less than existing
conditions, the functionality of the existing storm drain will be
adequate. Therefore, the scope of work includes:
• Determination of 100-year peak discharge.
RA:mswort\tl:\aes92\2239V1\hyd.doc
W.0.2239-1 09/23/98
Executive
Summary The following table compares existing and post-development flows
as determined by the corresponding engineering company's
hydrology report:
Gbmparty
Dwg 341-5A
Hunsaker & Associates
Existing Flow
49.6 cfs
N/A
Post-Development Flow
N/A
47.1 cfs
In summary, the table identifies post-development flows as being
less than existing flows. Therefore, since the existing storm drain
has been designed and constructed to accomodate a 100-year
storm (see dwg 341-5A) and post-development flows are less than
existing flows, the existing storm drain does not require upsizing or
any other modifications.
RA:msword\h:\aes92\2239\1 \tiyd.doc
W.0.2239-1 09/28/98
HADLEY PROPERTY
OF
MARCOS
VICINITY MAP
N.T.S.
FIG.l
Ill
Drainage Criteria
and Methodology
Design Storm 100-year storm
Land Use Single-family
Soil Type A hydrologic soil group "D" was used for this study.
Runoff Coefficient "C" values were based on the County of San Diego
Drainage Design & Procedure Manual. The site is single-
family residential, therefore a "C" value of 0.55 was used.
Rainfall Intensity The rainfall intensity values were based on the criteria
presented in the County of San Diego Drainage Design &
Procedure Manual (see Reference Data).
RA:msworflWpcserver*ydrologyiaes92\2239M \ftyd.doc
W.O. 2239-1 09/25/98
HYDROLOGY
METHOD OF ANALYSIS
The computer generated analysis for this watershed is consistent with current
engineering standards and requirements of the County of San Diego. This report also
contains calculations for the proposed storm drain within the project limits.
RATIONAL METHOD
The most widely used hydrologic model for estimating watershed peak runoff rates is
the rational method. The rational method is applied to small urban and semi-urban
areas of less than 0.5 square miles. The rational method equation relates storm rainfall
intensity, a selected 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.
NODE-LINK STUDY
In performing a node-link study, the surface area of the basin is divided into basic areas
which discharge into different designated drainage basins. These "sub-basins" depend
upon locations of inlets and ridge lines.
SUBAREA SUMMATION MODEL
The rational method modeling approach is widely used due to its simplicity of
application, and its capability for estimating peak runoff rates throughout the interior of a
study watershed analogous to the subarea model. The procedure for the Subarea
Summation Model is as follows:
RA: msword\\\pcserver\hydrology\aes92\2239\1 Uiyd .doc
W.0.2239-1 09/25/98
(1) Subdivide the watershed into subareas with the initial subarea being less
than 10 acres in size (generally 1 lot will do), and the subsequent
subareas gradually increasing in size. Assign upstream and downstream
nodal point numbers to each subarea in order to correlate calculations to
the watershed map.
(2) Estimate a Tc by using a nomograph or overlaid flow velocity estimation.
(3) Using T, 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. These links are characterized by length, area, runoff
coefficient and cross-section. 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.
Where two or more links join together, the node is analyzed by the confluence method
described as follows:
RA:mswordWpcserver\hyc!rology\aes92\2239\1 \hyd.doc
W.0.2239-1 09/25/98
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 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 (I A); 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 (VTa); Tp = Tb
In a similar way, the underground storm drains are analyzed. The data obtained from
the surface model for the flow rates present at the inlets and collection points are input
into the nodes representing those structures. The design grades and lengths are used
to compute the capacity of the storm drains and to model the travel time into the
adjustment of the times of concentration for downstream inlets.
REFERENCE
1. Hydrology Manual, County of San Diego, January 1985.
2. Hromadka, Theodore: COMPUTER METHODS IN URBAN HYDROLOGY:
Lighthouse Publications, 1983.
RA: mswori\\\pcserveiMiydrologyVaes92\2239\1Uiyd.doc
W.O. 2239-1 09/25/98
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 **************************
* HADLEY PROPERTY *
* POST-DEVELOPMENT 100-YEAR STORM ANALYSIS *
* W.O. #2239-1 SEPTEMBER 24, 1998 *
**************************************************************************
FILE NAME: 2239\1\DEV100.RAT
TIME/DATE OF STUDY: 15: 7 9/24/1998
USER SPECIFIED HYDROLOGY AND HYDRAULIC MODEL INFORMATION:
1985 SAN DIEGO MANUAL CRITERIA
USER SPECIFIED STORM EVENT(YEAR) = 100.00
6-HOUR DURATION PRECIPITATION (INCHES) = 2.700
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 10.00 TO NODE 11.00 IS CODE = 21
>»»RATIONAL METHOD INITIAL SUBAREA ANALYSIS<««
SOIL CLASSIFICATION IS "D"
SINGLE FAMILY DEVELOPMENT RUNOFF COEFFICIENT = .5500
INITIAL SUBAREA FLOW-LENGTH = 500.00
UPSTREAM ELEVATION = 366.00
DOWNSTREAM ELEVATION = 350.20
ELEVATION DIFFERENCE = 15.80
URBAN SUBAREA OVERLAND TIME OF FLOW(MINUTES) = 15.086
*CAUTION: SUBAREA SLOPE EXCEEDS COUNTY NOMOGRAPH
DEFINITION. EXTRAPOLATION OF NOMOGRAPH USED.
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 3.489
SUBAREA RUNOFF(CFS) = 4.99
TOTAL AREA(ACRES) = 2.60 TOTAL RUNOFF(CFS) = 4.99
****************************************************************************
FLOW PROCESS FROM NODE 11.00 TO NODE 12.00 IS CODE = 6
>»»COMPUTE STREETFLOW TRAVELTIME THRU SUBAREA<««
UPSTREAM ELEVATION = 350.20 DOWNSTREAM ELEVATION = 339.80
STREET LENGTH(FEET) = 300.00 CURB HEIGHT(INCHES) = 6.
STREET HALFWIDTK(FEET) = 28.00
DISTANCE FROM CROWN TO CROSSFALL GRADEBREAK = 14.00
INTERIOR STREET CROSSFALL(DECIMAL) = .020
OUTSIDE STREET CROSSFALL(DECIMAL) = .020
SPECIFIED NUMBER OF HALFSTREETS CARRYING RUNOFF = 2
**TRAVELTIME COMPUTED USING MEAN FLOW(CFS) = 7.00
STREETFLOW MODEL RESULTS:
STREET FLOWDEPTH(FEET) = .30
HALFSTREET FLOODWIDTK(FEET) = 8.54
AVERAGE FLOW VELOCITY(FEET/SEC.) = 4.13
PRODUCT OF DEPTH&VELOCITY = 1.23
STREETFLOW TRAVELTIME(MIN) = 1.21 TC(MIN) = 16.30
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 3.320
SOIL CLASSIFICATION IS "D"
SINGLE FAMILY DEVELOPMENT RUNOFF COEFFICIENT = .5500
SUBAREA AREA(ACRES) = 2.20 SUBAREA RUNOFF(CFS) = 4.02
SUMMED AREA(ACRES) = 4.80 TOTAL RUNOFF(CFS) = 9.01
END OF SUBAREA STREETFLOW HYDRAULICS:
DEPTH(FEET) = .33 HALFSTREET FLOODWIDTH(FEET) = 10.20
FLOW VELOCITY(FEET/SEC.) = 3.89 DEPTH*VELOCITY = 1.28
c*****************************************************************
FLOW PROCESS FROM NODE 12.00 TO NODE 13.00 IS CODE = 6
>»»COMPUTE STREETFLOW TRAVELTIME THRU SUBAREA<««
UPSTREAM ELEVATION = 339.80 DOWNSTREAM ELEVATION = 334.60
STREET LENGTH(FEET) = 368.00 CURB HEIGHT(INCHES) = 6.
STREET HALFWIDTH(FEET) = 28.00
DISTANCE FROM CROWN TO CROSSFALL GRADEBREAK = 14.00
INTERIOR STREET CROSSFALL(DECIMAL) = .020
OUTSIDE STREET CROSSFALL(DECIMAL) = .020
SPECIFIED NUMBER OF HALFSTREETS CARRYING RUNOFF = 2
**TRAVELTIME COMPUTED USING MEAN FLOW(CFS) = 11.20
STREETFLOW MODEL RESULTS:
STREET FLOWDEPTH(FEET) = .38
HALFSTREET FLOODWIDTH(FEET) = 12.68
AVERAGE FLOW VELOCITY(FEET/SEC.) = 3.25
PRODUCT OF DEPTH&VELOCITY = 1.23
STREETFLOW TRAVELTIME(MIN) = 1.89 TC(MIN) = 18.19
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 3.093
SOIL CLASSIFICATION IS "D"
SINGLE FAMILY DEVELOPMENT RUNOFF COEFFICIENT = .5500
SUBAREA AREA(ACRES) = 2.60 SUBAREA RUNOFF(CFS) = 4.42
SUMMED AREA(ACRES) = 7.40 TOTAL RUNOFF(CFS) = 13.43
END OF SUBAREA STREETFLOW HYDRAULICS:
DEPTH(FEET) = .41 HALFSTREET FLOODWIDTH(FEET) = 14.34
FLOW VELOCITY(FEET/SEC.) = 3.09 DEPTH*VELOCITY = 1.28
************************************************** ******************************
FLOW PROCESS FROM NODE 13.00 TO NODE 14.00 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 6.8 INCHES
PIPEFLOW VELOCITY(FEET/SEC.) = 21.9
UPSTREAM NODE ELEVATION = 325.00
DOWNSTREAM NODE ELEVATION = 310.00
FLOWLENGTH(FEET) = 90.00 MANNING'S N = .012
ESTIMATED PIPE DIAMETER(INCH) = 18.00 NUMBER OF PIPES =
PIPEFLOW THRU SUBAREA(CFS) = 13.43
TRAVEL TIME(MIN.) = .07 TC(MIN.) = 18.25
*********************************•*•******************************,
FLOW PROCESS FROM NODE 14.00 TO NODE 22.00 IS CODE = 51
>»»COMPUTE TRAPEZOIDAL CHANNEL FLOW<««
>»»TRAVELTIME THRU SUBAREA<««
UPSTREAM NODE ELEVATION = 310.00
DOWNSTREAM NODE ELEVATION = 260.00
CHANNEL LENGTH THRU SUBAREA(FEET) = 155.00
CHANNEL SLOPE = .3226
CHANNEL BASE(FEET) = 15.00 "Z" FACTOR = 2.000
MANNING'S FACTOR = .030 MAXIMUM DEPTH(FEET) =20.00
CHANNEL FLOW THRU SUBAREA(CFS) = 13.43
FLOW VELOCITY(FEET/SEC) = 6.94 FLOW DEPTH(FEET) = .13
TRAVEL TIME(MIN.) = .37 TC(MIN.) = 18.63
******************************************************************************
FLOW PROCESS FROM NODE 14.00 TO NODE 22.00 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.) = 18.63
RAINFALL INTENSITY(INCH/HR) = 3.05
TOTAL STREAM AREA(ACRES) = 7.40
PEAK FLOW RATE(CFS) AT CONFLUENCE = 13.43
****************************************************************************
FLOW PROCESS FROM NODE 20.00 TO NODE 21.00 IS CODE = 21
>»»RATIONAL METHOD INITIAL SUBAREA ANALYSIS<««
SOIL CLASSIFICATION IS "D"
RURAL DEVELOPMENT RUNOFF COEFFICIENT = .4500
NATURAL WATERSHED NOMOGRAPH TIME OF CONCENTRATION
WITH 10-MINUTES ADDED = 12.41(MINUTES)
INITIAL SUBAREA FLOW-LENGTH = 600.00
UPSTREAM ELEVATION = 384.00
DOWNSTREAM ELEVATION = 310.00
ELEVATION DIFFERENCE = 74.00
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 3.958
SUBAREA RUNOFF(CFS) = 13.89
TOTAL AREA(ACRES) = 7.80 TOTAL RUNOFF(CFS) = 13.89
****************************************************************************
FLOW PROCESS FROM NODE 21.00 TO NODE 22.00 IS CODE = 51
>»»COMPUTE TRAPEZOIDAL CHANNEL FLOW<««
>»»TRAVELTIME THRU SUBAREA<««
UPSTREAM NODE ELEVATION = 310.00
DOWNSTREAM NODE ELEVATION = 260.00
CHANNEL LENGTH THRU SUBAREA(FEET) = 630.00
CHANNEL SLOPE = .0794
CHANNEL BASE(FEET) = 10.00 "Z" FACTOR = 1.500
MANNING'S FACTOR = .030 MAXIMUM DEPTH(FEET) = 20.00
CHANNEL FLOW THRU SUBAREA(CFS) = 13.89
FLOW VELOCITY(FEET/SEC) = 5.38 FLOW DEPTH(FEET) = .25
TRAVEL TIME(MIN.) = 1.95 TC(MIN.) = 14.36
****************************************************************************
FLOW PROCESS FROM NODE 21.00 TO NODE 22.00 IS CODE = 8
>»»ADDITION OF SUBAREA TO MAINLINE PEAK FLOW<««
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 3.602
SOIL CLASSIFICATION IS "D"
RURAL DEVELOPMENT RUNOFF COEFFICIENT = .4500
SUBAREA AREA(ACRES) = 7.30 SUBAREA RUNOFF(CFS) = 11.83
TOTAL AREA(ACRES) = 15.10 TOTAL RUNOFF(CFS) = 25.73
TC(MIN) = 14.36
************************************************************
FLOW PROCESS FROM NODE 21.00 TO NODE 22.00 IS CODE =
»>»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.) = 14.36
RAINFALL INTENSITY{INCH/HR) = 3.60
TOTAL STREAM AREA(ACRES) = 15.10
PEAK FLOW RATE(CFS) AT CONFLUENCE = 25.73
** CONFLUENCE DATA **
STREAM RUNOFF Tc INTENSITY AREA
NUMBER (CFS) (MIN.) (INCH/HOUR) (ACRE)
1 13.43 18.63 3.046 7.40
2 25.73 14.36 3.602 15.10
RAINFALL INTENSITY AND TIME OF CONCENTRATION RATIO
CONFLUENCE FORMULA US.ED FOR 2 STREAMS.
** PEAK FLOW RATE TABLE **
STREAM RUNOFF Tc INTENSITY
NUMBER (CFS) (MIN.) (INCH/HOUR)
1 37.08 14.36 3.602
2 35.18 18.63 3.046
COMPUTED CONFLUENCE ESTIMATES ARE AS FOLLOWS:
PEAK FLOW RATE(CFS) = 37.08 Tc(MIN.) = 14.36
TOTAL AREA(ACRES) = 22.50
****************************************************************************
FLOW PROCESS FROM NODE 22.00 TO NODE 23.00 IS CODE = 51
>»»COMPUTE TRAPEZOIDAL CHANNEL FLOW<««
>»»TRAVELTIME THRU SUBAREA<««
UPSTREAM NODE ELEVATION = 260.00
DOWNSTREAM NODE ELEVATION = 244.00
CHANNEL LENGTH THRU SUBAREA(FEET) = 290.00
CHANNEL SLOPE = .0552
CHANNEL BASE(FEET) = 10.00 "Z" FACTOR = 1.500
MANNING'S FACTOR = .030 MAXIMUM DEPTH(FEET) = 10.00
CHANNEL FLOW THRU SUBAREA(CFS) = 37.08
FLOW VELOCITY(FEET/SEC) = 6.89 FLOW DEPTH(FEET) = .50
TRAVEL TIME(MIN.) = .70 TC(MIN.) = 15.06
FLOW PROCESS FROM NODE 22.00 TO NODE 23.00 IS CODE = 8
>»»ADDITION OF SUBAREA TO MAINLINE PEAK FLOW<««
100 YEAR RAINFALL INTENSITY(INCH/HOUR) = 3.493
SOIL CLASSIFICATION IS "D"
RURAL DEVELOPMENT RUNOFF COEFFICIENT = .4500
SUBAREA AREA(ACRES) = 6.40 SUBAREA RUNOFF(CFS) = 10.06
TOTAL AREA(ACRES) = 28.90 TOTAL RUNOFF(CFS) = 47.14
TC(MIN) = 15.06
END OF STUDY SUMMARY:
PEAK FLOW RATE(CFS) = 47.14 Tc(MIN.) = 15.06
TOTAL AREA(ACRES) = 28.90
END OF RATIONAL METHOD ANALYSIS
V
REFERENCE DATA
NOTE: Some reference data that has typically been included in support of
hydrologic calculations done by hand are incorporated into the Rational
Method Hydrology Computer Program Package (by AES).
These include:
* Intensity-Duration Design Chart
* Nomograph for Determination of Time of Concentration (Tc) for Natural
Watersheds
* Urban Areas Overland Time of Flow Curves
* Runoff Coefficients (Rational Method)
Since these references are incorporated into the AES software, they are
not needed to support this study and are therefore not included in this
support.
Soils maps are also not included, as Hydrologic Soil Group "D"
RA:msword\\\pcserver\ti ydrology\aes92\2239\1Miyd.doc
W.0.2239-1 09/25/98
100-YEAR 6-HOUR PRECIPITATION
CUfcli'Y OF SAN DIEGO
DEPARTMENT OF SANITATION
FLOOD CONTROL
ISOPLUVIALS
PRECIPITATION
OF 100-YEAR 6-HOUR
OF AN IKCII
33'
Pftpn
U.S. DEPARTMEN
NATIONAL OCfANIC AND AT?
SPECIAL STUDIES BRANCH. OFFICE OF II
30' _
m—;^.-:vX:\\f\ ;
27riVr-N\r^-L * •J V>N\\ V iN /|.'rf ^
it by
1 OF COMMERCE
SPI1EHIC ADMINISTRATION
)ROLOCY. NATIONAL WEATHER SERVICE