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Home My WebLink AboutCT 01-08; NORTHPOINTE WEST; PRELIMINARY DRAINAGE STUDY NORTHPOINTE; 2002-02-12K&S ENGINEERING Planning Engineering Surveying PRELIMINARY DRAINAGE STUDY FOR NORTHPOINTE WEST IN CITY OF CARLSBAD JN 00-111 February 12, 2002 DATE ^ 7801 Mission Center Court. Suite 100 . San Dlego. California 92108 . (619)296-5566 . Fax (619) 296-5564 FILE COPY TABLE OF CONTENTS l.SITE DESCRIPTION 2. HYDROLOGY DESIGN MODELS 3. HYDROLOGIC CALCULATIONS APPENDIX A 4. TABLES AND CHARTS APPENDIX B 5. HYDROLOGY MAPS APPENDIX C 1. SITE DESCRIPTION A. EXISTING CONDITION THE EXISTING SITE CONSISTS OF LOTS 9 THRU 12 OF MAP NO. 13716. THESE LOTS WERE MASS-GRADED PER CITY OF CARLSBAD PROJECT NO. 98-07, GRADING PLAN NO. 365-5A. THE GRADED PADS CURRENTLY DRAIN IN AN INTERIM CONDITION TO AN EXISTING DESILTING BASIN LOCATED ON THE SOUTHERLY SIDE OF LOT NO. 12. THESE COMBINED STORM FLOWS ARE CONVEYED FROM THE DESILTING BASIN BY AN EXISTING 48" STORM DRAIN TO AN EXISTING CREEK THAT RUNS ALONG THE WESTERLY SUBDIVISION BOUNDARY. STORM FLOWS ALSO ENTER THIS BASIN VIA AN UNDERGROUND STORM DRAIN SYSTEM FROM THE EXISTING NORTHPOINTE DEVELOPMENT. APROXIMATELY 13.5 ACRES ARE TRIBUTARY TO THIS STORM DRAIN SYSTEM. THE EXISTING STORM DRAIN SYSTEM UTILIZES FOSSIL FILTERS AT ALL CATCH BASINS AND INLETS TO TREAT THE STORM RUNOFF BEFORE ENTERING THE EXISTING DESILT BASIN. ALSO, LOTS 9, 10 AND 11 CONTAIN INDIVIDUAL 24" STORM DRAIN PIPES CONSTRUCTED PER SAID GRADING PLAN NO. 365- A. THESE INDIVIDUAL STORM DRAINS. DO NOT ACCEPT FLOWS IN THE INTERIM CONDITION, BUT ARE INTENDED FOR THE USE BY THE PROPOSED DEVELOPMENT. B. PROPOSED CONDITION THE PROPOSED SITE (NORTHPOINTE WEST) CONSISTS OF INDUSTRIAL BUILDINGS AND THEIR CORRESPONDING PARKING AREAS. THE PROPOSED DRAINAGE CONSISTS OF A COMBINATION OF SURFACE FLOW AND A SYSTEM OF INLETS AND UNDERGROUND PIPES THAT WILL TIE INTO THE FOUR EXISTING STORM DRAIN PIPES MENTIONED ON THE "EXISTING CONDITION" AND CONVEY THE PROPOSED FLOWS TO THE EXISTING CREEK. ALL CATCH BASINS AND INLETS PROPOSED WITH THIS PROJECT WILL HAVE FOSSIL FILTERS INSTALLED. ALSO, A SEPARATE REPORT ENTITLED "CONCEPT WATER QUALITY PLAN" HAS BEEN PREPARED FOR THE PROJECT. THIS REPORT ADDRESSES THE SAN DIEGO REGIONAL WATER QUALITY BOARD ORDER 2001.01. BRIEFLY, THE REPORT DEMONSTRATES THAT THERE WILL BE NO DOWNSTREAM IMPACTS DUE TO DEVELOPMENT OF THE SITE WITH RESPECT TO WATER QUALITY AND EROSION. A MAINTENANCE PROGRAM FOR THE BMP'S HAS ALSO BEEN ADDRESSED IN THE REPORT. 2. HYDROLOGY DESIGN MODELS A. DESIGN METHODS THE RATIONAL METHOD IS USED IN THIS HYDROLOGY STUDY; THE RATIONAL FORMULA IS AS FOLLOWS: Q = CIA, WHERE : Q= PEAK DISCHARGE IN CUBIC FEET/SECOND * C = RUNOFF COEFFICIENT (DIMENSIONLESS) I = RAINFALL INTENSITY IN INCHES/HOUR (PER APPENDIX XI-A) A = TRIBUTARY DRAINAGE AREA IN ACRES *1 ACRE INCHES/HOUR = 1.008 CUBIC FEET/SEC THE NATURAL WATERSHED METHOD IS ALSO USED IN THIS HYDROLOGY STUDY; THE NATURAL WATERSHED FLOW FORMULA IS AS FOLLOWS: Tc=1.8 (1.1-C) (L)-'/[SdOO) ]-^^^ L = OVERLAND TRAVEL DISTANCE IN FEET S = SLOPE IN FT./FT. Tc= TIME IN MINUTES B. DESIGN CRITERIA - FREQUENCY, 100 YEAR STORM. - LAND USE PER SPECIFIC PLAN AND TENTATIVE MAP. - RAIN FALL INTENSITY PER COUNTY OF SAN DIEGO 1993 HYDROLOGY DESIGN MANUAL. C. REFERENCES - COUNTY OF SAN DIEGO 1993, HYDROLOGY MANUAL. - COUNTY OF SAN DIEGO 1992 REGIONAL STANDARD DRAWING. - HAND BOOK OF HYDRAULICS BY BRATER & KING, SIXTH EDITION. APPENDIX A (3. HYDROLOGIC CALCULATIONS) 6.2 EXISTING HYDROLOGY San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software,(c)1991-2000 Version Rational method hydrology program based on San Diego County Flood Control Division 1985 hydrology manual Rational Hydrology Study Date: 03/06/01 ****-k-k-k-k-k Hydrology Study Control Information ************ K&S Engineering, San Diego, California - S/N 868 Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used English (in) rainfall data used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.200 Adjusted 6 hour precipitation (inches) = 2.600 P6/P24 = 61.9% San Diego hydrology manual 'C values used Runoff coefficients by rational method -^-1--I--I--^-I--H-I--I-+-H-H-H-I--I--f-f-H-I--I--I--I--f-h-H H--I--f-H-I--H-I--f-f-H-H +-I--I--I--H-I-+ -l-l--I--1-1- Process from Point/Station 1.000 to Point/Station 2.000 **** INITIAL AREA EVALUATION **** User specified 'C value of 0.450 given for subarea Initial subarea flow distance = 365.000(Ft.) Highest elevation = 276.000(Ft.) Lowest elevation = 270.000(Ft.) Elevation difference = 6.000(Ft.) Time of concentration calculated by the urban areas overland flow method (App X-C) = 18.94 min. TC = [1.8*(l.l-C)*distance(Ft.)^.5)/(% slope^(l/3)] TC = [1.8*(1.1-0.4500)*( 365.000^.5)/( 1.644^(1/3)]= 18.94 Rainfall intensity (I) = 2.902(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.450 Subarea runoff = 3.055(CFS) Total initial stream area = 2.340(Ac.) +++++++^. ^.-H-I-++++-I-+-I--h++-h-I--I--H-f-I--I--f-I--I--f-f-I--1--I--I--H-f-f-f-f-I--f-I-+ -H-f-H- Process from Point/Station 2.000 to Point/Station 3.000 **** IMPROVED CHANNEL TRAVEL TIME **** Upstream point elevation = 270.000(Ft.) Downstream point elevation = 263.500(Ft.) Channel length thru subarea = 250.000(Ft.) Channel base width = 1.000(Ft.) Slope or 'Z' of left channel bank = 2.000 Slope or 'Z' of right channel bank = 2.000 Manning's 'N' = 0.020 Maximum depth of channel = 1.000(Ft.) Flow(q) thru subarea = 3.055(CFS) Depth of flow = 0.373(Ft.), Average velocity = 4.683(Ft/s) Channel flow top width = 2.4 94(Ft.) Flow Velocity = 4.68(Ft/s) Travel time = 0.89 min. Time of concentration = 19.83 min. Critical depth = 0.484(Ft.) -f-h-I--H-H-H-I--I--f-f-I--h-H-H-I--I--^-H-H-I--I--f-h-H-I--H-I--I-+-f-H-H-H-I--I-H--I--f-I--I--I-+ + + -I--I-I--I-1- Process from Point/Station 2.000 to Point/Station 3.000 **** SUBAREA FLOW ADDITION **** User specified 'C value of 0.450 given for subarea Time of concentration = 19.83 min. Rainfall intensity = 2.817(In/Hr) for a 100.0 year storm Runoff coefficient used for sub-area, Rational method,Q=KCIA, C = 0.450 Subarea runoff = 2.662(CFS) for 2.100(Ac.) Total runoff = 5.717(CFS) Total area = 4.44(Ac.) + +-I--I--I--I--I--(--H-H-I--I-+-I--I--H-H-I--I--f-f-H-f-H-I--f-I--H-H-I--h-I--H-I--H-H-H-I--I--f-I--f-h + -I-I-I--I-I- Process from Point/Station 3.000 to Point/Station 4.000 **** IMPROVED CHANNEL TRAVEL TIME **** Upstream point elevation = 263.500(Ft.) Downstream point elevation = 260.000(Ft.) Channel length thru subarea = 310.000(Ft.) Channel base width = 1.000(Ft.) Slope or 'Z' of left channel bank = 2.000 Slope or 'Z' of right channel bank = 2.000 Manning's 'N' = 0.020 Maximum depth of channel = 1.000(Ft.) Flow(q) thru subarea = 5.717(CFS) Depth of flow = 0.624(Ft.), Average velocity = 4.071(Ft/s) Channel flow top width = 3.4 98(Ft.) Flow Velocity = 4.07(Ft/s) Travel time = 1.27 min. Time of concentration = 21.10 min. Critical depth = 0.664(Ft.) -I-+-h-1--I--f +-f-I--f-f-h-H-I--H-f-H-H-I--f-f-h-h-f-I--H-I--I--I--f-f-h-I--I--f-h-I--f-H-I--I--t-+ -I--I--I-I--*- Process from Point/Station 3.000 to Point/Station 4.000 **** SUBAREA FLOW ADDITION **** User specified 'C value of 0.450 given for subarea Time of concentration = 21.10 min. Rainfall intensity = 2.706(In/Hr) for a 100.0 year storm Runoff coefficient used for sub-area. Rational method,Q=KCIA, C = 0.450 Subarea runoff = 3.276(CFS) for 2.690(Ac.) Total runoff = 8.994(CFS) Total area = 7.13(Ac.) -I--(--I-+ +-H-I-+-I--H-H-H-f-f-H-H-I--I--f-H-H-f-f-H-H-I--f-f-I--I--I--f ++-H-I-+-f + +-I-++ -I--I--I--I-I- Process from Point/Station 4.000 to Point/Station 5.000 **** IMPROVED CHANNEL TRAVEL TIME **** Upstream point elevation = 260.000(Ft.) Downstream point elevation = 251.000(Ft.) Channel length thru subarea = 320.000(Ft.) Channel base width = 45.000(Ft.) Slope or 'Z' of left channel bank = 2.000 Slope or 'Z' of right channel bank = 2.000 Manning's 'N' = 0.020 Maximum depth of channel = 10.000(Ft.) Flow(q) thru subarea = 8.994(CFS) Depth of flow = 0.084(Ft.), Average velocity = 2.378(Ft/s) Channel flow top width = 4 5.335(Ft.) Flow Velocity = 2.38(Ft/s) Travel time = 2.24 min. Time of concentration = 23.34 min. Critical depth = 0.107(Ft.) -I-^..(.-^-I--H-(-+-H-H-H-H + +-I--H-I--^-t--I--I--I--1--f-I--f-H-I--f-H-H-I--f-f-I--f-I--I--I--H+-I--I-+ -l-l--f-I-t- Process frora Point/Station 4.000 to Point/Station 5.000 **** SUBAREA FLOW ADDITION **** User specified 'C value of 0.450 given for subarea Time of concentration = 23.34 min. Rainfall intensity = 2.536(In/Hr) for a 100.0 year storm Runoff coefficient used for sub-area. Rational method,Q=KCIA, C 0.450 Subarea runoff = 3.195(CFS) for 2.800(Ac.) Total runoff = 12.188(CFS) Total area = 9.93{Ac.) -f-I--I--I--f-f-f-I--I--H-h-I--^-f-I--H-f-f-I--H-I--I--f-f-^-I--t--I--I--^-^-I--^-I--^-f-f-I--I--I- •f-i--i--i--i- Process from Point/Station 4.000 to Point/Station 5.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 9.930(Ac.) Runoff from this stream = 12.188(CFS) Time of concentration = 23.34 min. Rainfall intensity = 2.536(In/Hr) -I--H-f-1--1--H-I--I--H-f-I--H-t--H-H-H-f-f-f-H-H-I--H-H-H-f-H-^-I--H-I--H-h-I--H-I--I--I--1--I-+ -I--I--H-f-I- Process from Point/Station 303.000 to Point/Station 6.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Rainfall intensity (I) = 4.843(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 8.56 min. Rain intensity = 4.84(In/Hr) Total area = 14.740(Ac.) Total runoff = 72.684(CFS) -I--1--I--f-f-I--1--I--I--I--H-I--I--I--I--I--I--I--I--I--I--I--I--I--I--H-f-I--h-I--H-H-I--I--I--I--I--I--f-f+ -I-H-H--I- Process from Point/Station 6.000 to Point/Station 5.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 254.670(Ft.) Downstream point/station elevation = 252.270(Ft.) Pipe length = 177.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 72.684(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 72.684(CFS) Normal flow depth in pipe = 27.61(In.) Flow top width inside pipe = 30.44(In.) Critical Depth = 32.32(In.) Pipe flow velocity = 12.4 9(Ft/s) Travel time through pipe = 0.24 min. Time of concentration (TC) = 8.80 min. ++-H-I--H-I--I--I--I--H-t--I--H-H-I--I--f-I--f-I--H-I--I--I--f-f-I--H-H-I--I--I--H-I--f-I--I-+-I--I--I-+ -l-l--l-l--I- Process from Point/Station 6.000 to Point/Station 5.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 14.740(Ac.) Runoff from this stream = 72.684(CFS) Time of concentration = 8.80 min. Rainfall intensity = 4.759(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 12.188 23.34 2.536 2 72.684 8.80 4.759 Qmax(1) Qmax(2) 1.000 * 1.000 * 12.188) -I- 0.533 * 1.000 * 72.684) -H = 50.920 1.000 * 0.377 * 12.188) -i- 1.000 * 1.000 * 72.684) -H = 77.277 Total of 2 streams to confluence: Flow rates before confluence point: 12.188 72.684 Maximum flow rates at confluence using above data: 50.920 77.277 Area of streams before confluence: 9.930 14.740 Results of confluence: Total flow rate = 77.277(CFS) Time of concentration = 8.7 96 min. Effective stream area after confluence = 24.670(Ac.) + + + + + + + + +-H-H-H + +-I--H-(--1--H +-I--I--I--H-H-I--h-H-H-I--I--I--H-I--I-4--I--I--I--I--I--I--f-f -I--f-f-f-I- Process from Point/Station 5.000 to Point/Station 7.000 -*r*** PIPEFLOW TRAVEL TIME (User specified size) **** h-f-f-f-f-f Upstream point/station elevation = 247.000(Ft.) Downstream point/station elevation = 246.800(Ft.) Pipe length = 20.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 77.277(CFS) Given pipe size = 36.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 2.852(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 0.268(Ft.) Minor friction loss = 2.784(Ft.) K-factor = 1.50 Pipe flow velocity = 10.93(Ft/s) Travel time through pipe = 0.03 min. Time of concentration (TC) = 8.83 min. -f +++-h-H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ -f-f-f-f-f Process from Point/Station 7.000 to Point/Station 8.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 246.470(Ft.) Downstream point/station elevation = 221.620(Ft.) Pipe length = 46.75(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 77.277(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 77.277(CFS) Normal flow depth in pipe = 9.70(In.) Flow top width inside pipe = 31.95(In.) Critical Depth = 32.93(In.) Pipe flow velocity = 50.31(Ft/s) Travel time through pipe = 0.02 min. Time of concentration (TC) = 8.84 min. -I-+-H+-H-H-H-f+-f-f-f-f-f-f-f-f-f-f-f+-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ -f-f-f-f-f Process from Point/Station 8.000 to Point/Station 9.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 220.620(Ft.) Downstream point/station elevation = 220.260(Ft.) Pipe length = 35.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 77.277(CFS) Given pipe size = 48.00(In.) Calculated individual pipe flow = 77.277(CFS) Normal flow depth in pipe = 24.84(In.) Flow top width inside pipe = 47.97(In.) Critical Depth = 31.91(In.) Pipe flow velocity = 11.76(Ft/s) Travel time through pipe = 0.05 min. Time of concentration (TC) = 8.89 min. -I--(--I--^-I--I--I--I--H-I-+-H-H-I--H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f -f-f-f-f-f Process frora Point/Station 8.000 to Point/Station 9.000 **** SUBAREA FLOW ADDITION **** User specified 'C value of 0.4 50 given for subarea Time of concentration = 8.89 min. Rainfall intensity = 4.725(In/Hr) for a 100.0 year storm Runoff coefficient used for sub-area, Rational method,Q=KCIA, C = 0.450 Subarea runoff = 2.552(CFS) for 1.200(Ac.) Total runoff = 79.829(CFS) Total area = 25.87(Ac.) + + + + + + + + + + ++-(--!- + -(-++-)-+ -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-ft -f-f-f-f-f Process from Point/Station 9.000 to Point/Station 10.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 220.260(Ft.) Downstream point/station elevation = 220.200(Ft.) Pipe length = 35.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 79.829(CFS) Given pipe size = 48.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 0.988(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 0.108(Ft.) Minor friction loss = 0.940(Ft.) K-factor = 1.50 Pipe flow velocity = 6.35(Ft/s) Travel time through pipe = 0.09 min. Time of concentration (TC) = 8.98 min. End of computations, total study area = 25.870 (Ac.) PROPOSED HYDROLOGY San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software,(c)1991-2001 Version 6.2 Rational method hydrology prograra based on San Diego County Flood Control Division 1985 hydrology manual Rational Hydrology Study Date: 11/27/01 Hydrology Study Control Inforraation K&S Engineering, San Diego, California - S/N 868 Rational hydrology study storra event year is 100.0 English (in-lb) input data Units used English (in) rainfall data used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.200 Adjusted 6 hour precipitation (inches) = 2.600 P6/P24 = 61.9% San Diego hydrology manual 'C values used Runoff coefficients by rational method -(--h-h-H-H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f Process from Point/Station 1.000 to Point/Station 2.000 **** INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Initial subarea flow distance = 400.000(Ft.) Highest elevation = 275.560(Ft.) Lowest elevation = 270.170(Ft.) Elevation difference = 5.390(Ft.) Time of concentration calculated by the urban areas overland flow method (App X-C) = 4.89 min. TC = [1.8*{l.l-C)*distance(Ft.)'^.5)/(% slope'^ (1/3) ] TC = [1.8*(l.l-0.9500)*( 400.000^^.5)/( 1. 347'^ (1/3) ] = 4.89 Setting time of concentration to 5 minutes Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storra Effective runoff coefficient used for area (Q=KCIA) is C = 0.950 Subarea runoff = 7.159(CFS) Total initial stream area = 1.100(Ac.) + + + + + + + + + + + + + + + -!--!--(--I--^-H-I--^ + -H-H + -|--H-H-H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f + Process from Point/Station 1.000 to Point/Station 2.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Streara flow area = 1.100(Ac.) Runoff from this stream = 7.159(CFS) Time of concentration = 5.00 min. Rainfall intensity = 6.850(In/Hr) +++++++++++-I--H-I-^.-H-H-I-.^-I--H-I--t--1--I-++-h+-I-+-1--I--I--f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 20.000 to Point/Station 21.000 **** INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Deciraal fraction soil group B = 0.000 Deciraal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Initial subarea flow distance = 160.000(Ft.) Highest elevation = 273.040(Ft.) Lowest elevation = 269.570(Ft.) Elevation difference = 3.470(Ft.) Time of concentration calculated by the urban areas overland flow method (App X-C) = 2.64 min. TC = [1.8*(l.l-C)*distance(Ft.)'^.5)/(% slope^(l/3)] TC = [1.8*(l.l-0.9500)*( 160.000^^.5) / ( 2 .169^^ (1/3) ] = 2.64 Setting time of concentration to 5 minutes Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storra Effective runoff coefficient used for area {Q=KCIA) is C = 0.950 Subarea runoff = 8.330(CFS) Total initial stream area = 1.280(Ac.) + + + + + H-+-H-H-I--H +-I--1--H-H + + + +-H-H-t--H-H-h-H-I--1--H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f Process from Point/Station 21.000 to Point/Station 2.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 266.070(Ft.) Downstreara point/station elevation = 258.300(Ft.) Pipe length = 114.50(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 8.330(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 8.330(CFS) Normal flow depth in pipe = 8.88 (In.) Flow top width inside pipe = 10.52(In.) Critical depth could not be calculated. Pipe flow velocity = 13.37(Ft/s) Travel time through pipe = 0.14 min. Time of concentration (TC) = 5.14 min. -f-f-f-f-f-f-f-f+-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-I--I--I--t--1-+-I-+-I- Process from Point/Station 21.000 to Point/Station 2.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Streara flow area = 1.280(Ac.) Runoff from this stream = 8.330(CFS) Time of concentration = .5.14 rain. Rainfall intensity = 6.727(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 7.159 5.00 6.850 2 8.330 5.14 6.727 Qmax(1 Qmax(2) = 1.000 * 1.000 * 7.159) -f 1.000 * 0.972 * 8.330) -f = 15.257 0.982 * 1.000 * 7.159) -f 1.000 * 1.000 * 8.330) -f = 15.360 Total of 2 strearas to confluence: Flow rates before confluence point: 7.159 8.330 Maxiraum flow rates at confluence using above data: 15.257 15.360 Area of streams before confluence: 1.100 1.280 Results of confluence: Total flow rate = 15.360(CFS) Time of concentration = 5.143 min. Effective stream area after confluence = 2.380(Ac.) -1--I-+-I--1--f-f++-f-f-f-f-f+-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 2.000 to Point/Station 3.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstreara point/station elevation = 258.550(Ft.) Downstream point/station elevation = 241.200(Ft.) Pipe length = 60.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 15.360(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 15.360(CFS) Norraal flow depth in pipe = 5.76(In.) Flow top width inside pipe = 20.50(In.) Critical Depth = 16.95(In.) Pipe flow velocity = 26.50(Ft/s) Travel tirae through pipe = 0.04 min. Tirae of concentration (TC) = 5.18 rain. +++++++++++-I--I--I--I--I--I--I-+-I--H-I--H-I--I-+-H-H-1-+-f-f-f-f-f-f-f-f-f-f-f-f-f Process from Point/Station 1.000 to Point/Station 4.000 * * * •* INITIAL AREA EVALUATION Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Deciraal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Initial subarea flow distance = 500.000(Ft.) Highest elevation = 275.560(Ft.) Lowest elevation = 267.500(Ft.) Elevation difference = 8.060(Ft.) Time of concentration calculated by the urban areas overland flow method (App X-C) = 5.15 min. TC = [1.8*(l.l-C)*distance(Ft.)''.5)/(% slope^(l/3)] TC = [1.8*(l.l-0.9500)*( 500.000".5)/( 1. 612^^ (1/3) ] = 5.15 Rainfall intensity (I) = 6.722(In/Hr) for a 100.0 year storra Effective runoff coefficient used for area (Q=KCIA) is C = 0.950 Subarea runoff = 13.091(CFS) Total initial stream area = 2.050(Ac.) -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-I--f-I--I-++++ Process frora Point/Station 4.000 to Point/Station 5.000 **** IMPROVED CHANNEL TRAVEL TIME **** Upstreara point elevation = 267.500(Ft.) Downstream point elevation = 265.220(Ft.) Channel length thru subarea = 200.000(Ft.) Channel base width = 0.000(Ft.) Slope or 'Z' of left channel bank = 67.000 Slope or 'Z' of right channel bank = 67.000 Estimated mean flow rate at midpoint of channel = 16.156(CFS) Manning's 'N' = 0.015 Maximum depth of channel = 1.000(Ft.) Flow(q) thru subarea = 16.156(CFS) Depth of flow = 0.288(Ft.), Average velocity = 2.906(Ft/s) Channel flow top width = 38.599(Ft.) Flow Velocity = 2.91(Ft/s) Travel time = 1.15 min. Tirae of concentration = 6.30 rain. Critical depth = 0.324(Ft.) Adding area flow to channel Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Rainfall intensity = 5.904(In/Hr) for a 100.0 year storra Runoff coefficient used for sub-area. Rational method,Q=KCIA, C = 0.950 Subarea runoff = 5.384(CFS) for 0.960(Ac.) Total runoff = 18.475(CFS) Total area = 3.01(Ac.) -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 5.000 to Point/Station 6.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 262.050(Ft.) Downstream point/station elevation = 251.500(Ft.) Pipe length = 4 6.20(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 18.475(CFS) Given pipe size = 15.00(In.) Calculated individual pipe flow = 18.475(CFS) Normal flow depth in pipe = 8.36(In.) Flow top width inside pipe = 14.90(In.) Critical depth could not be calculated. Pipe flow velocity = 26.28(Ft/s) Travel time through pipe = 0.03 min. Time of concentration (TC) = 6.33 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 6.000 to Point/Station 7.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstreara point/station elevation = 251.170(Ft.) Downstreara point/station elevation = 234.200(Ft.) Pipe length = 55.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 18.475(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 18.475(CFS) Normal flow depth in pipe = 6.22(In.) Flow top width inside pipe = 21.03(In.) Critical Depth = 18.58(In.) Pipe flow velocity = 28.60(Ft/s) Travel time through pipe = 0.03 min. Time of concentration (TC) = 6.36 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-I-+++++-I--I--1^ Process from Point/Station 8.000 to Point/Station 9.000 **** INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Initial subarea flow distance = 500.000(Ft.) Highest elevation = 269.500(Ft.) Lowest elevation = 261.670(Ft.) Elevation difference = 7.830(Ft.) Time of concentration calculated by the urban areas overland flow raethod (App X-C) = 5.20 min. TC = [1.8*(l.l-C)*distance(Ft.)^.5)/(% slope'^ (1/3) ] TC = [1.8*(l.l-0.9500)*( 500.000".5)/( 1.566^^(1/3)]= 5.20 Rainfall intensity (I) = 6.680(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.950 Subarea runoff = 19.927(CFS) Total initial stream area = 3.140(Ac.) -f-f-f-f-f-f-f-f-f-f-f +-f-f-H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f + Process from Point/Station 9.000 to Point/Station 10.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 258.500(Ft.) Downstream point/station elevation = 248.000(Ft.) Pipe length = 78.30(Ft.) Manning's N = 0.015 No. of pipes = 1 Required pipe flow = 19.927(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 19.927(CFS) Norraal flow depth in pipe = 10.03(In.) Flow top width inside pipe = 17.88(In.) Critical depth could not be calculated. Pipe flow velocity = 19.71(Ft/s) Travel time through pipe = 0.07 min. Time of concentration (TC) = 5.27 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 10.000 to Point/Station 11.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstreara point/station elevation = 246.950(Ft.) Downstream point/station elevation = 230.800(Ft.) Pipe length = 90.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 19.927(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 19.927(CFS) Normal flow depth in pipe = 7.43 (In.) Flow top width inside pipe = 22.19(In.) Critical Depth = 19.24(In.) Pipe flow velocity = 24.08(Ft/s) Travel time through pipe = 0.06 min. Time of concentration (TC) = 5.33 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+-f-f-f-f-f-f-f-f-f Process from Point/Station 12.000 to Point/Station 13.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** Decimal fraction soil group A = 0.000 Deciraal fraction soil group B = 0.000 Deciraal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Rainfall intensity (I) = 4.844(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 8.56 rain. Rain intensity = 4.84(In/Hr) Total area = 14.740(Ac.) Total runoff = 72.684(CFS) -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f Process from Point/Station 13.000 to Point/Station 14.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstreara point/station elevation = 254.670(Ft.) Downstream point/station elevation = 253.840(Ft.) Pipe length = 85.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 72.684(CFS) Given pipe size = 36.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 2.642(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 1.009(Ft.) Minor friction loss = 2.463(Ft.) K-factor = 1.50 Pipe flow velocity = 10.28(Ft/s) Travel time through pipe = 0.14 min. Time of concentration (TC) = 8.69 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process frora Point/Station 13.000 to Point/Station 14.000 **** SUBAREA FLOW ADDITION **** Deciraal fraction soil group A = 0.000 Deciraal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Time of concentration = 8.69 min. Rainfall intensity = 4.795(In/Hr) for a 100.0 year storm Runoff coefficient used for sub-area. Rational method,Q=KCIA, C = 0.950 Subarea runoff = 1.822(CFS) for 0.400(Ac.) Total runoff = 74.506(CFS) Total area = 15.14(Ac.) -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 14.000 to Point/Station 15.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 253.840(Ft.) Downstream point/station elevation = 251.890(Ft.) Pipe length = 110.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 74.506(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 74.506(CFS) Normal flow depth in pipe = 25.24(In.) Flow top width inside pipe = 32.96(In.) Critical Depth = 32.54(In.) Pipe flow velocity = 14.07(Ft/s) Travel time through pipe = 0.13 min. Tirae of concentration (TC) = 8.82 min. + + + + + ++ +-1--I--I--(.-I--(--(- +-H-f.-h-H-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f Process from Point/Station 14.000 to Point/Station 15.000 SUBAREA FLOW ADDITION **** Deciraal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type _ ] Time of concentration = 8.82 min. Rainfall intensity = 4.749(In/Hr) for a 100.0 year storra Runoff coefficient used for sub-area. Rational raethod,Q=KCIA, C = 0.950 Subarea runoff = 1.714(CFS) for 0.380(Ac.) Total runoff = 76.220(CFS) Total area = 15.52(Ac.) +++++++-H-I--H+-H-I-+-H-I--I--f.-h-h-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f Process from Point/Station 15.000 to Point/Station 16.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 251.890(Ft.) Downstream point/station elevation = 246.800(Ft.) Pipe length = 24.80(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 76.220(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 7 6.220(CFS) Norraal flow depth in pipe = 12.33(In.) Flow top width inside pipe = 34.17(In.) Critical Depth = 32.77(In.) Pipe flow velocity = 35.63(Ft/s) Travel time through pipe = 0.01 min. Time of concentration (TC) = 8.84 min. ++++++-i--H++-H+-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+-i--i--l--l-+ Process from Point/Station 16.000 to Point/Station 17.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 246.470(Ft.) Downstream point/station elevation = 221.620(Ft.) Pipe length = 4 6.75(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 76.220(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 76.220(CFS) Norraal flow depth in pipe = 9.63(In.) Flow top width inside pipe = 31.87(In.) Critical Depth = 32.77(In.) Pipe flow velocity = 50.10(Ft/s) Travel time through pipe = 0.02 min. Time of concentration (TC) = 8.85 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 17.000 to Point/Station 18.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstreara point/station elevation = 220.620(Ft.) Downstream point/station elevation = 220.260(Ft.) Pipe length = 35.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 76.220(CFS) Given pipe size = 48.00(In.) Calculated individual pipe flow = 76.220(CFS) Normal flow depth in pipe = 24.66(In.) Flow top width inside pipe = 47.98(In.) Critical Depth = 31.69(In.) Pipe flow velocity = 11.72(Ft/s) Travel tirae through pipe = 0.05 min. Time of concentration (TC) = 8.90 min. -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 17.000 to Point/Station 18.000 **** SUBAREA FLOW ADDITION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 1.000 [INDUSTRIAL area type ] Time of concentration = 8.90 min. Rainfall intensity = 4.722 (In/Hr) for a 100.0 year storm Runoff coefficient used for sub-area. Rational method,Q=KCIA, C = 0.950 Subarea runoff = 6.640{CFS) for 1.480(Ac.) Total runoff = 82.860(CFS) Total area = 17.00(Ac.) -f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f-f+ Process from Point/Station 18.000 to Point/Station 19.000 **** PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 220.260(Ft.) Downstream point/station elevation = 219.970(Ft.) Pipe length = 35.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 82.8 60(CFS) Given pipe size = 48.00(In.) Calculated individual pipe flow = 82.860(CFS) Normal flow depth in pipe = 27.75(In.) Flow top width inside pipe = 47.41(In.) Critical Depth = 33.11(In.) Pipe flow velocity = 11.02(Ft/s) Travel time through pipe = 0.05 min. Time of concentration (TC) = 8.95 min. End of computations, total study area = 25.530 (Ac.) APPENDIX B (4. TABLES AND CHARTS) U/eS/?7^ 7?7?S7?S 0l^£yeL7?A//7> T/MS OF FLOW CU/e\7SS £xo/np/£ •• G/yen le/rg//} 0/" T'/otv ' JOO S/ofi^ ' 70'A, Coef/'/c/e/}/ 0/ eu/7o//. C'.SO ^eac/ • Ot'£/'/<fne/ /'/otv/Zme '/^ A///7C//<TS i I SAN DIEGO COUNTY DEPARTMENT OF SPECIAL DISTRICT SERVICES DESIGN MANUAL URBAN AREAS OVERLAND TIME OF FLOW CURVES DATE APPENDIX X-C CHART 3 EXHI3LT 2 (7/9) Cur» wiorrtvo) i TO Au-i7* f^cs C'J:/3OI.V3 CIVICS ? ca CiSCHiPCE FS." SCUARE fCCr CP I I ...... ...,,.,.=..,3 HYDRA'JL'.C CAPACITY OF GRATE pr.riiW INLET IN SUMP INTENSITY-DUMTION DtSIGN CHART la nnlli'lliliil i.i-i-»i4iiiliiinii;ii.ii.iimf=; • i . i'i j.i-j.i u.i-H»nirimi j Equation: I = 7.44 D ''^^^ I = Intensity (In./Hr.) » 6 Hr. Precipitation (In.) ' • :' • CTt I o c -? -J ro o rt O =1 3 n =r ro (/» 15 20 Minntfis Directions for Application: 1) From precipitation naps determine 6 hr. and 24 hr. amounts for the selected frequency. These maps are printed in the County Hydrology Manual (10, 50 and 100 yr. maps included in the Design and Procedure hjanual). 2) Adjust 6 hr. precipitation (if necessary) so that it is within the range of 45% 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 the plotted lines. 5) This line is the intensity-duration curve for the location being analyzed. Application Form: 0) Selected Frequency ^r. 1) P. = Jn., ?2Br — 2) Adjusted *Pg= in. %* 3) t^ = 4) I = . min. in/hr. *Not Applicable to Desert Region Revised 1/8.S APPFNDTX XT-A V '.*nf Of SAM OIECO OEPARINCffr OF SANITATION S FLOOO CONTROL ^5* 33* 30' 15' 100-YEAf^^4-IIOljR PRECIPITATION '•20^ISOPLUVIALS OF 100 -YEAR 24-HOUR PRECIPITATIOH IM EMTHS OF AN IMCH "15' U.S. DEPARtllENtr HATtOKAL OCKAMC AHO irsctAL STuoiKs »«A.MOi. orncc or ii 30* OF COMMERCE AT^OSPIICNIC AOMRISTIIATtON PMOkOCY. NATIONAI. »I:ATIIKII SCRVICC nr.' I|5« 30* 117' l,r,i 30« 116' W .nr OF SAN OIEGO i,..ARTNENr OF SANITATIOM ft FLOOO CONTROL 100-YEAft PRECIPITATI0?5 ISOPLUVIALS OF lOO-YEAR G-HOUR PRECIPITATIOM IM EMTHS 0? AM liiCIl ri»F« U.S. DEPARTMEN HAiiOMAL ecCAMC AMD AT9]osnieinc A^i^i^^f ^J3^!^ grtewu. ttwoiM ««As»eH. ornc« or II 30». r OF COMMERCE imOLOOV. NATIONAL VIATHKR SCKVICC 118 ^5' 30' «4 s TABLE 2 RUNOFF COEFFICIENTS (RATIONAL METHOD) DEVELOPED AREAS (URBAN) Land Use Coefficient. C SoiI Group (1) Residential: A B c D Si ngle Family .^0 MS .50 •55 Multi-Units .^5 .50 .60 .70 Mobile homes M .50 .55 .65 -\ Rural (lots greater than 1/2 acre) .30 .35 % M Commercial(2) 80% Impervious .70 .75 .80 .85 Industrial (2) 90% Impervious .80 .85 .90 .95 NOTES: ^'^Soil Group ma.r>s are available at the offices of the Departinent of Public Works. (2)whe re actual conditions deviate significantly from the tabulated impervious- ness values of 80% or 90%, 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 soiI. group. Actual imperviousness • 50% Tabulated imperviousness - 80% Revised C - 50 X 0.85 - 0.53 80 .4- r-^* • ^^7^:\^m^W7^: IV-A-9 APPENDIX IX-B- . ^. V .Rev.^; S/81 > "A Average Values of Roughness Coefficient (Manning's n) Typa of Waterway 1. Closed Conduits (1) Steel (not lined) Cast Iron Aluminum Corrugated Metal Corrugated Metal Corrugated Metal Corrugated Metal Concrete RCP Clay (sewer) Asbestos Cement-^ Pv<i- Drain Tile (terra cotta) Cast-in-place Pipe Reinforced Concrete Box (not lined) (2) (smooth asphalt quarterlining) (2) (smooth asphalt half lining) (smooth asphalt full lining) Roughness CoafficiBnt (n) 0.015 0.015 .021 0.024 0.021 0.018 0.012 0.012 0.013 0.011 0.015 0.015 0.014 2. Open Channels (1) a. Unlined Clay Loam Sand 0.023 0.020 b. Revetted Gravel Rock Pipe" and Wire Sacked Concrete c. Lined Con^crete (poured) Airv Blown Mortar (3) Asphaltic Concrete or Bituminous Plant Mix d. Vegetated (5) Grass lined, maintained Gra^s and Weeds Grass lined with concrete low flow channel 3. Pavement and Gutters (1) ! Concrete Bituminous (plant-mixed) ^m'i^^;.:7. 0.030 0.040 0.025 0.025 0.014 0.016 0.018 .035 .045 .032 0.013 0.016 tmest F. Brater ind Horace Williams King HANDBOOK OF HYDRAULICS For the Solulion of Hydraulic En gineering Problems Tabic 7-14. Values,of A" for Circular Cliannels in the Formula tt D - depth of water d « dianu trr of channel b 1 d j .00 1 .01 .0 .00007 .1 .00907 .0118 •> .0400 .0448 .3 .0907 .0900 .4 .1501 .1033 .5 .232 .239 .6 .311 .319 .7 .388 .395 .8 .4^ .458 .9 .494 .496 1.6 .463 .02 .00031 .0142 .0402 .1027 .1705 247 .327 .402 463 497 .03 .00074 .0107 ,0537 ,108U 177U 255 335 409 408 498 .04 ,00138 0195 0585 1153 1854 203 343 416 .473 498 .05 00222 .0225 .0034 .1218 .1929 .271 .350 .422 .477 498 .00 .0032S .0257 .0080 .1284 ,2005 279 358 429 481 496 "- .07 .00455 .0291 .0738 .1352 .2082 .287 .300 .435 .485 .494 .08 .00004 .0327 .0793 .1420 .2100 .295 .373 .441 .488 .489 .09 APPENDIX C (5. HYDROLOGY MAP)