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Home My WebLink AboutCT 15-08; HYDROLOGY STUDY; 2015-10-29IR EPORT ORIGINALLY APPROVE!) 10129115 I FOR REFERENCE ONLY HYDROLOGY STUDY Carlsbad Ranch PA 5- Marbrisa Phase III Hotel 3 and Timeshare Villas GRAND PACIFIC RESORT CARLSBAD, CALIFORNIA SDP 03-02(A), CT 15-08, CDP 03-04(A), CUP 03-01 (A), PUD 15-16 PREPARED FOR. GRAND PACIFIC CARLSBAD, L.P. 5900 PASTEUR COURT, SUITE 200 CARLSBAD, CA 92008 (760)431-8500 PREPARATION DATE: 4-28-2015 REVISION 1: 7-06-2015 REVISION 2:8-26-2015 REVISION 3:10-29-2015 PREPARED BY: 4A q ENGINEERING EXCELJob No. 14-100 440 STATE PLACE ESCONDIDO, CA 92029 PH: 760-745-8118 /SSIO; D. hfI#I% C Ex IL UNDER THE SUPERVISION OF: RECEIVED No. 45629 .\ Exp. 12-31-20 / AUG 27 2020 LAND DEVELOPMENT ENGINEERING ROBERT D. DENTINO RCE 45629 CONSTRUCTION CHANGE /\ Table of Contents Project Overview .3 Purpose..................................................................................................................................................3 Location.................................................................................................................................................3 ExistingConditions .............................................................................................................................3 ProposedFacilities...............................................................................................................................4 Methodology.....................................................................................................................4 Hydrology..............................................................................................................................................4 Hydraulics..............................................................................................................................................4 Calculations......................................................................................................................5 Determine the Watershed that the Project Effects.........................................................................5 Determine the Runoff Coefficients for the Site..............................................................................5 Calculate Qioo using the Rational Method.........................................................................................6 DetentionCalculations........................................................................................................................7 Design of Proposed Storm Drain Facilities.....................................................................................7 Conclusion........................................................................................................................7 Declaration of Responsible Charge .................................................................................8 Attachments...........................................................................Error! Bookmark not defined. EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 1 0F8 Attachments Attachment A Vicinity Map Attachment B San Diego County Drainage Manual Graphs and Tables Soils Group Map Attachment C Pre-Development Hydrologic Maps (From Phases 1 & 2) Post-Development Hydrologic Map Attachment D Civil-D Pre-Development Hydrology Calculations (From Phases 1 & 2) Attachment E Civil-D Post-Development Hydrology Calculations Attachment F Storm Drain Calculations EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 2 OF 8 Project Overview Purpose This report is in support of the Tentative Map and Preliminary Grading Plan for phase 3 of the Carlsbad Ranch, Planning Area 5 project also referred to as Marbrisa Phase III. The purpose of this report is to describe the procedures used in the hydrologic and hydraulic models, estimate peak discharge magnitudes and to size the proposed storm drain pipes in order to preserve the water quality and channel stability of the downstream watershed. Location The proposed development is located in the City of Carlsbad, County of San Diego, CA. The majority of the project is located at the south eastern corner of the intersection of Cannon Road and Grand Pacific Drive, while a small portion of the project is located at the South West of the aforementioned intersection. Existing Conditions The site is approximately 21.160 acres. The site was graded during phase I of the project (Drawing #428-9A). During Phase II, Drawing #428-9G, of the project villas 60-64 were permitted. This project proposes to re-grade Phase III for construction of villas 75-79 as well as change the size of these buildings approved under SDP 03-02 and to construct a revised plan for the hotel. Villas 60-64 will be built on the existing graded pads per drawing #428-96 Therefore this analysis includes these areas. Villa 67 has also been included in this site plan submittal. However the storm drains and treatment for this area were designed and installed per drawing no. 428-9G. The runoff for the current site is discharged into 2 separate outfalls: Outfall-A - The southern portion of the project drains to a de-silting pond. After the flow is collected in the pond it is then discharged via a storm drain pipe into a bio-filtration swale that leads to the southernmost corner of the project where it is then discharged to a 42" public storm drain. Outfall-B - Currently the portion of the project to the Northeast of Grand Pacific Drive drains to 2 different de-silting ponds. From these ponds the runoff is discharged to a public storm drain in Cannon Rd. (See the pre- development drainage map for this portion of the project in Attachment C) The pre developed condition for this portion of the project was taken from the post-developed condition for the mass grading condition for this project (Drawing # 428-9A) and the precise grading plans for the areas around Villas 60-64 (Drawing # 428-9G). EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 3 OF 8 Proposed Facilities The proposed site plan includes a combination of parking areas, time share villas, swimming pools, landscaping, and hotel buildings with associated structures. Infrastructure improvements are proposed to include new storm-drains as well as water and sewer main extensions and new dry utilities runs/extensions to service the lots. In the post-development conditions the runoff for the site will still be discharged through 2 separate outfalls: Outfall-A - The area contributing to this outfall is currently in a mass graded condition. The proposed project proposes to introduce 5.03 Acres of impermeable surface (driveways, buildings, etc.). For the post-developed condition the runoff will be routed through 4 of 6 new bio-retention ponds, from where it will then be discharged to the existing bio-swale to the South of project. From the existing bio-swale the runoff leaves the site via an existing 42" storm drain that then connects to an existing 60" RCP at Lego Drive. Outfall-B - For the post-developed condition the contributory area will become only slightly smaller as a pad footprint will infringe upon this area and divert the runoff to different outfalls. This basin will have an increase in impermeable area with the addition of three timeshare buildings, I parking lot and new proposed flatwork. Flow from this outfall will be routed through 2 new bio-retention ponds before it will be discharged to the existing tie-in to the public Storm Drain Line in Cannon Road. Methodology Hydrology The Rational Method as outlined in the San Diego County Hydrology Manual 2003 Edition was followed in this study. The CIV.ELCADD/C1VILDESIGN software version 7.9 was used to calculate the Stormwater peak flows. San Diego 2013 rational method module was selected so that the changes from 2013 manual has taken into account such changes as time concentration and urban area runoff coefficient. Also in 2013, the program updated the slope input for initial basin's with steep slope greater than 30%. The hydrology analysis was done only for 100 year storm event. The 2 and 10 year storm events were covered in the Hydromodification Analysis using Continuous Hydrologic Simulation. The hydrologic model, USEPA Storm Water Management Model (SWMM), was used to perform the simulation of continuous water movements through various patterns of land uses in the watershed. The SWMM analysis is included in Attachment G of this report. Hydraulics The Hydra flow storm Sewers version 8.0 software was used in the hydraulic calculations to size the proposed storm drain pipes. Said software uses the energy-based Standard step method when computing the hydraulic profile. This methodology is an iterative procedure that applies Bernoulli's energy equation between the downstream and upstream ends of each line in the system. It uses Manning's equation to determine head losses due to pipe friction. EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 4 OF 8 F(gure 1 Carlsbad Hjidrohgic The Hjdraflow Hjdrographs version 8.0 software was used in the hydraulic calculations involving the sizing of the storage ponds onsite. This software uses the hydrograph information that is calculated using the rational method hydrograph generating program by Rick Engineering Company to determine the Peak flows from the onsite ponds and Underground pipe storage. The inputs to the hydrograph generating program were generated from the Civil D Post-Development calculations. Calculations Determine the Watershed that the Project Effects As shown in the figure below the project lies within the Carlsbad Hydrologic Unit. For details see the storm water management plan for the project. Determine the Runoff Coefficients for the Site Based on Natural Resources Conservation Service Soil Survey Map this project is categorized as soil type B loamy coarse sand. The USDA NRCS soil texture classification was used to determine the average soil capillary suction, saturated hydraulic conductivity rate and the soil initial moisture deficit. The full printout from the USDA NRCS soils report is attached to this report. Cp - the permeability coefficient determined by the soil type. The Cp for type B soil is .25. Pre-Development - The pre-developed condition for this phase of the project was taken from the Post-Developed condition of phase I and phase 2 of the project. Post-Developed Condition - The average C-Value for the Post-Developed condition was calculated using the following equation C = .9 * (% Impervious) + Cp * (% Pervious) where: The average C-value was calculated separately for the areas surrounding the hotel and villas 75-79, and the area surrounding villas 60-64. EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 5 OF 8 Thus the average C value used to calculate the QIOO for the Post-Developed condition around the hotel and villas 75-79 was found to be C = .9 * (59) +.25 * (41) .63 And, the average C value used to calculate the QIOO for the Post-Developed condition around villas 60-64 was found to be C = .9 * (50) +.25 * (50) .58 Note - In the civil D-Program the calculation for the initial areas does not allow for the user-defined selection for the C-Factor. In order to select the correct C- factor the following options had to be chosen to essentially "trick" the program into choosing the correct c- value. For a C-value of .63 the MDR 14.5 with type D soil option was selected. For a C- Value of .58 the MDR 14.5 with type B soil was selected. These selections were determined from Table 3-1 of the san Diego County Hydrology Manual (Attachment B). See Attachment B for coefficient of runoff (C) calculations. Calculate Qioo using the Rational Method Hydrologic calculations were computed using CivilD based on 2 basins (labeled as Basin A, and B) for pre-development, and post-development. The layout of the drainage areas for both Pre and Post development are shown in Attachment C of this report. The Pool and Spa areas were not considered in the calculation because the runoff captured in these facilities will be treated by the pools filtration system. The CivilD printouts of these calculation can be found in Attachment D, & E as part of this report. The 100-year on-site developed peak storm flows (CFS) have been calculated and are summarized in the table below. These values were used to size the proposed storm drain pipes later in this report. PRE-DEVELOPMENT POST-DEVELOPMENT NODE/OUTFALL Qioo (CFS) TRIBUTARY AREA (AC) Tc (MIN) Qioo (CFS) TRIBUTARY AREA (AC) T (I,{lN) Node #103 Outfall A 62.85** 21.725** 9.83** 60.78 22.021 14.67 Node # 103 Outfall B 18.05* 4.360* 733* 12.61 4.220 8.84 * Taken from phase I (Drawing #428-9A). ** Taken from phase II (Drawing #428-9G). EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 6 OF 8 Detention Calculations Detention calculations were not needed because the QIOO flows for the post developed condition were calculated to be lower than the pre developed condition without detention calculations. Design of Proposed Storm Dram Facilities The proposed storm drain sizes have been shown in the Hydrologic Software and the calculations run as part of that program that the HGL within the pipes does not come within several feet of overtopping the inlet grate elevations. The maximum HGL above the top of underground storm drain pipe is less than a half foot. Therefore, no additional calculations have been done for the on- site system. Conclusion 100-year 6-hour storm event was analyzed to ensure the proposed project is capable to pass 100 year storm event without damage to facilities. Outlet velocities were controlled through pipe detention system to minimize downstream erosion. This project will not negatively impact the existing downstream storm drain facilities. In low storm cases, the runoff generated by the site will be allowed to percolate through bio-retention systems prior to entering public storm drainage system. This will add some additional lag times to the time of concentrations not accounted for by CivilD Hydrology program. Should these bio-retention mechanisms fail and not allow for percolation through the media, emergency spillways are provided to allow overtopping of the QIOO out of the bio-retention ponding system. QIOO SUMMARY 70 - 62.85 60.784 60 - - - 50 r.x.4 40 30 20 18.05 12.61 10 _________ 0 - PrcDedopment - - Post -Development - U Outfall A' • 62.85 60.784 UOutfall B I 18.05 12.61 U Outfall A U Outfall B EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 7 OF 8 Declaration of ResRonsible Charge I hereby declare that I am the engineer of work for this project. That I have exercised responsible charge over the design of the project as defined in section 6703 of the business and professions codes, and that the design is consistent with current design. I understand that the check of the project drawings and specifications by the City of Carlsbad is confined to a review only and does not relieve me, as engineer of work, of my responsibilities for project design. ENGINEER OF WORK Excel Engineering 440 State Place Escondido, CA 92029 Tel— (760)745-8118 Fax - (760)745-1890 Project Number: 13-070 e ;F 'Cjoe~' Z ~~) P/Z//eo '; ~; z 0 "~ 49 20 Robert D. DoKno, RCE 45629 Date Registration Expire: December 31, 2016 EXCEL ENGINEERING 440 STATE PLACE, ESCONDIDO CA 92029 PHONE: 760-745-8118 PAGE 8 OF 8 Attachment A Vicinity Map VICINITY MAP CITY OF OCEANSIDE HIGHWAY ?a NOT TO SCALE c R CITY OF VISTA 51 OAD ALOMAR \\\' \I-IIDDEN \\\7 VALLEY RD. CITY OF çoP0 SAN MARCOS ALG7 "-I PACIFIC Cos o AVE OCEAN 1 / CITY OF ENCINITAS Attachment B San Diego County Drainage Manual Graphs and Tables Soils Group Map Rainfall Isopluvials Cl, 0 En C°) - -. to 0 33030 lounty / I / Riverside County. -.0 ;d'Y-../,,/ : H.-. -. •0 • -. •.•-• .. -..-.;• --.-- 0 •• 0 ç - •• • .•.• •0 -. •-..6. I I o 0 0o A -...• N •- I - Iv 33'15'- #O 33 15 ----------------------------- l\ 'cc_•. - I, o -. \. •. .• ..-.., . - OCEANSIDE VIS .IT 4 r \ ......-,--. PROJECT LOCATION • • .... . • .• ....• . .• • .....-. .•. ES DIDO - I _- CARLSBAD •(•. - c _. ENcINITAs;• •-.•\fl•> V-'-- . / . ....... •.-000. 1 - 33°00 - - - -._ - . -; ------------ . u_ 33 *00' 0 SOLANA BEACH ?OVtAY \ S 1 (IOUNTY 0 DEL MAR •.• • ..• . . . .. •• ••......- .. . Is 65 ( L - - - - -. • • ' -e - NTE I AN DIE \%IIrc%c_1c %Ija '< - r . L J N • AMA 3245 ------------ - -- -. - -- - 3245 LE GRtV, • %- • .' 0 • ORION - •. ::.:: • .•S so IMPERIAL BEAC • : .• .7 32°30 - ------ -- ---;-------- ----------- ------- I 0 32°30' ) C,, '- 0 Cl) 100Year Rainfall Event - 24 Hours IsopIuvial (inches) DPW GIS SaAnAS 'X, Ha,, .jrt 1hC(I ('rLdr N THIS MAP IS PROVIDED WctHOUT RARRANTY OF ANY KIND, ErEHER EXPRESS w* OR IMPLIE6 INCLUDING, BUT NOT LIMITED TO. THE IMPLIED WARRANTIES 0° -RC HAMTABILITE AND FIThESS FOR A PARTICULAR PURPOSE CepcqN SscGS All RIgXII R.sopved TX.o p clurN r011 l.oflrlrr n'fclXOfl from PR SANDAG Regrocol E 101 onnspo., Svcloo, eRIch canorO be reproduced e.flnd Ore 0011100 p,orco*.o1 of SANDAlS 11cc product may contain infoonation *1011, hoc boor. 'eprcjccod W,tb plfn'orucorr 7*ril0rl by Thooma Bootbont LOops S 3 0 3MiIes County of San Diego Hydrology Manual 33°30 Ce) N- N- Oranqe 33030 ounty 95 b in D IT N ZD - --T Riverside County County of San Diego 330301 Hydrology Manual 33015 Rainfall Isopluvials 3315 ---------------- 100 Year Rainfall _Event — 6 Hours OCEANSIDE PROJECT LOCATION IsopIuvial (inches) O ENCINIT C) SOLANA BEACH -. ) Pow1v \ S COUNTY I - 4 DEL MAR I I I ( .5.. \.s • •• CD () b•• - Q 'I. (V ( - - NTEE ' I c;) 0 ...•.\ AN DIE I I °n 150 25 LC N — t - •Q rho (AMA I c7 --- ------/.-.-. - '-•-'-- 32°45 LE GROVE IMPERIAL BEACH 320301 -,- - 32030 33000 - 32°45 -- C1) Co 0 T DPW GIS Sanuia 1')LII (c,rd' N THIS MAP S PROV0E0 WITHOUT MAP.R.ANT OF ANY KIND, EITHER EXPRESS * OR IMPLIED. INCLUDING, BUT NOT LIVITED TO THE IMPUED WAPRANTES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE CopyngAl SonG IS All RRI'to Ryeen.d ma products ray dO4'I4S1 1h. 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II1IUpUU IllIllilul IIflhuIUS IUPP 11111 ItJlt5IIltlHIIIfl U UUEIII UIIIUPIIIIU ..IIuuIIIIuI III1uIIIIIIIIuuIuIIluIIuIIuItIIIIIiII U UUIIIUIIuIIlflhIIII u..u.u.u. •I•lluluul ImIIIIIfluuuIIIIIIuIflhIIIIIIIuIII..U...ltuIIulIIIFIIIIU:I uuuuuutuiuiiiiiu rniuiiiiiuuuuuuuu uliiuiIniiiIuu••••IIuIiuI iuuiiii;: u••uu•iuuauu .I.IIu,,u,unhllulll.•Im,IuIm tmiittmitiiiiiiu•u•iuiiuiiiiu IIIIIIImIi uu.....uuuuuu lililuin, imlilmi iiuum uuuum iuiuuiimiiiir•uuu.. .Dll. luluilulmill! 1ui•ii•ii 11111 IllIhlIlli IIIIIHIH III1IIIIIhIhIIIiIIhihiUhIUhIlUllII II1111IIIhIIlIhIII San Diego County Hydrology Manual Section: 3 Date: June 2003 Page: 6 of 26 Table 3-I RUNOFF COEFFICIENTS FOR URBAN AREAS Soil Type NRCS E]crnents County Elements % IMPEL A B C 0 UndistuThed Natural Terrain (Natural) Permanent Open Space 0* 0.20 0.25 0.30 0.35 Low Density Residential (LDR) Residential, 1.0 DUfA or less 10 0.27 0.32 0.36 0.411 Low Density Residential (LDR) Residential, 2.0 DUIAor less 20 0.34 0.38 0.42 0.46 Low Density Residential (LDR) Residential. 2.9 DUFA or less 25 0.38 0.41 0,45 0.49 Medium Density Residential (MDR) Residential. 4.3 DUFA or less 30 0.41 0.45 0.48 0.52 Mcdium Density Residential (MDR) Residential, 7.3 DU/A or less 40 0.48 0.51 0.54 0.57 Medium Density Residential (MDR) Residential, 10.9 011/A or kss 45 032 034 0.57 0.60 Medium Density Residential (MDR) Residential, 14.5 011/A or less 50 0.55 0.58 0.60 0.63 High Denshy Residential MDR) Residential, 24.0 DU7A or less 65 0.66 0.67 0.69 0.71 High Density Residential (HDR) ResIdential, 43.0 DU7A or less 80 0.76 0.77 0.78 0.79 commercial/Industrial K corn) Neighborhood Commercial 80 0.76 0.77 0.78 0.79 Commercial/Industrial (G. Con) Generni Commercial 85 0.80 0.80 0.81 0.82. Commercial/Industrial (D.P. Corn) Office Professional/Commercial 90 0.83 0.84 0.84 0.85 Commercial/Industrial (Limited L) Limited industrial 90 0.83 0.84 0.84 0.85 commercial/Industrial (General I.) General industrial 95 0.87 0.87 0117 0117 *The values associated with 0% inpervioiis my be used for direct calculation of the runoff coefficient as described in Section 3.1.2 (representing the pervious runoff coefficient, Cp. for the soil type). or f07 areas that will remain undisturbed in peetuity. Justification must be given that the area will remain natural forever (e.g., the area is located in Cleveland National Forest). 013/A dwelling units per acre NRCS = National Re sources Conservalion Service 3-6 2.50% slopa OOVI 0000000 00000000 2.0 100 1 AO I..o 'o + 30 — — — — — 75 Ci .50 • • .4 W w dl4 Z Ii. 0 I 2O Z U W - I ft 0 LI.I I- 3 0 — — — — — pool — — — 10 Q C) w > 0 0 EXAMPLE: Given: Watercourse Distance (D) 70 Feet Slope(s)=i.3% -C) VD Runoff Coefficient (C) = 041 T -___________ QverIandFIcw Time (T) 95 Minuie SOURCE: Airport Drainage Federal Avialion Adrninisraton 1965. FIGURE Rational Formula - Overland Time of Flow Nomograph [33 San Diego County Hydrology Manual Date: June 2003 Section: 3 Page: 12 of 26 Note that the initial Time of Concentration should be reflective of the general land-use at the upstream end of a drainage basin. A single lot with an area of two or less acres does not have a significant effect where the drainage basin area is 20 to 600 acres. Table 3-2 provides limits of the length (Maximum Length (LM)) of sheet flow to be used in hydrology studies, Initial T1 values based on average C values for the Land Use Element are also included. These values can be used in planning and design applications as described below. Exceptions may be approved by the "Regulating Agency" when submitted with a detailed study. Table 3-2 MAXIMUM OVERLAND FLOW LENGTH (L 1) & INITIAL TIME OF CONCENTRATION (Till Element* DU/ Acre 3% 1% % 3% 5% 1011/0 LM TI Lm Ti41 T, LmTI Lim Ti Lm Tj Natural 50 13.2 70 12.5 85 10.9 100 10.3 100 8.7 100 6.9 LDR 1 50 12.2 70 11.5 85 10.0 100 9.5 100 8.0 100 6.4 LDR 2 50 11.3 70 10.5 85 9.2 100 8.8 100 7.4 100 5.8 LDR 2.9 50 10.7 70 10.0 85 8.8 95 8.1 100 7.0 100 5.6 MDR 4.3 50 10.2 70 9.6 80 8.11 95 7.8 100 6.7 100 5.3 MDR 7.3 50 9.2 65 8.4 80 7.4 95 7.0 100 6.0 100 4.8 MDR 1 10.9 50 1 8.7 65 7.9 80 6.9 90 6.4 100 5.7 100 4.5 MDR 14.5 50 8.2 65 7.4 80 6.5 90 6.0 100 5.4 100 4.3 HIM 24 50 6.7 65 6J 75 5.1 90 4.9 95 4.3 100 33 HDR 143 50 5.3 65 4.7 75 4.0 85 3.8 95 3.4 100 2.7 N. Corn 50 1 5.3 60 4.5 75 4.0 85 3.8 95 3.4 100 2.7 Q. Corn 50 4.7 60 4.1 1 75 3.6 85 3.4 90 2.9 100 2.4 O.P./Corn 1 50 4.2 60 3.7 70 3.1 80 2.91 90 2.6 100 2.2 Limited I. 50 4.2 60 3.7 70 3.1 80 2.9 90 2.6 100 2.2 General I. 50 3.7 60 3.2 70 2.7 80 2.6 90 2.3 1 100 1.9 *See Table 3-1 for more detailed description 3-12 EQUATION AE (11.9L3 O3B5 It To L_s000 To =Time of cwiceflt,atiofl(howi) Watercourse Dtetance (mflos) 40O0 AE a Change In elevation along fr effective slope tine (See Figure 3.5)j1ot) 1-3000 To Hour Minutes F 2000 4 240 —1000 2 f l. 120 TOO 900 000 00 o - so 2E ___N "s I 40 Miles Felt 30 —'Do Ic 400° -20 10 3000 16 50 05 -14 40 200 12 1000 1600 10 30 1400 \ g 1200 a 20 1000 900 e00 a IN 600 10 500 1. 4 S I.2oo AF L Tc C?itornin Dvtson of H (1941) aid KIrpch (1940) Nomograph for DeterminatIon of Time Of ConCefllfollon (Tc) or Travel Time (TI) for Natural Watersheds F t G U R E 3..4 Watershed Divide y - L Design Point Watershed Divide Area "A Ii "B" Effective Slope Line Design Point (Watershed Outlet) Stream Profile L Area 'A" m Area "B" SOURCE: Cfflifomla 101vislom 1) ad KJrplth( FIGURE Computation of Effective Slope for Natural Watersheds 3..5 _9rk - — — — -- — — - __ Vi•••h' MA 1UFA rAl- • VA!T4I I VAU__ I VMUlI - W- m FA Fyi _ - __ "IIA_VAIIIMW1_ V__ 21W 4lAU•YAIl b~h' A MrAM,- .. • ___ ___ __ _ i•ENO V ri0 1 M m 0 mmffrbl - ____ __ mm - V. noMMM71, =j. 1'! rITTr FIGURE Gutter and Roadway Discharge - Velocity Chart 3-6 EQUATION: Vi4I R fl Il 03 015 30 001 04 0 10 0 09 006 0.520 00? 005 C-b 00 004 08 003 0.9 to 002 ir 0.03 6 CL 2 CL 10.09 001 9? 2 0009 l 1 .003 0.007 .4 000 0 0006 <; 8 0005 00 008 - 4 0.09 0003 0.10 0002 2 6 -1 8 0001 00009 10 10 02 00008 00007 09 - 00006 08 00000 07 03 0.0001 06 0 0003 20 10.4 GENERAL SOLTON I SOURCE USD01. Fl-tWA, HDS-3 (1961) FT GURE Manning's Equation Nomograph USDA United States Department of Agriculture NRCS Natural Resources Conservation Service A product of the National Cooperative Soil Survey, a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local participants Custom Soil Resource Report for San Diego County Area, California - -- ,,•, 1r ~A ii April 10, 2015 I I I Preface Soil surveys contain information that affects land use planning in survey areas. They highlight soil limitations that affect various land uses and provide information about the properties of the soils in the survey areas. Soil surveys are designed for many different users, including farmers, ranchers, foresters, agronomists, urban planners, community officials, engineers, developers, builders, and home buyers. Also, conservationists, teachers, students, and specialists in recreation, waste disposal, and pollution control can use the surveys to help them understand, protect, or enhance the environment. Various land use regulations of Federal, State, and local governments may impose special restrictions on land use or land treatment. Soil surveys identify soil properties that are used in making various land use or land treatment decisions. The information is intended to help the land users identify and reduce the effects of soil limitations on various land uses. The landowner or user is responsible for identifying and complying with existing laws and regulations. Although soil survey information can be used for general farm, local, and wider area planning, onsite investigation is needed to supplement this information in some cases. Examples include soil quality assessments (http://www.nrcs.usda.gov/wps/portal/ nrcs/main/soils/health/) and certain conservation and engineering applications. For more detailed information, contact your local USDA Service Center (http:II offices.sc.egov.usda.gov/locator/app?agency=nrcs) or your NRCS State Soil Scientist (http://www.nrcs.usda.gov/wps/portal/nrcs/detail/soils/contactus/? cid=nrcs142p2_053951). Great differences in soil properties can occur within short distances. Some soils are seasonally wet or subject to flooding. Some are too unstable to be used as a foundation for buildings or roads. Clayey or wet soils are poorly suited to use as septic tank absorption fields. A high water table makes a soil poorly suited to basements or underground installations. The National Cooperative Soil Survey is a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local agencies. The Natural Resources Conservation Service (NRCS) has leadership for the Federal part of the National Cooperative Soil Survey. Information about soils is updated periodically. Updated information is available through the NRCS Web Soil Survey, the site for official soil survey information. The U.S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin, age, disability, and where applicable, sex, marital status, familial status, parental status, religion, sexual orientation, genetic information, political beliefs, reprisal, or because all or a part of an individual's income is derived from any public assistance program. (Not all prohibited bases apply to all programs.) Persons with disabilities who require alternative means 2 I I I I I I I [I I I I I I I I I for communication of program information (Braille, large print, audiotape, etc.) should contact USDA's TARGET Center at (202) 720-2600 (voice and TDD). To file a complaint of discrimination, write to USDA, Director, Office of Civil Rights, 1400 Independence Avenue, S.W., Washington, D.C. 20250-9410 or call (800) 795-3272 (voice) or (202) 720-6382 (TDD). USDA is an equal opportunity provider and employer. Contents Preface....................................................................................................................2 How Soil Surveys Are Made..................................................................................5 SoilMap..................................................................................................................7 SoilMap................................................................................................................8 Legend..................................................................................................................9 MapUnit Legend................................................................................................10 MapUnit Descriptions........................................................................................10 San Diego County Area, California.................................................................12 CbB—Carlsbad gravelly loamy sand, 2 to 5 percent slopes.......................12 LeE—Las Flores loamy fine sand, 15 to 30 percent slopes........................13 MIC—Marina loamy coarse sand, 2 to 9 percent slopes.............................14 References............................................................................................................16 4 How Soil Surveys Are Made Soil surveys are made to provide information about the soils and miscellaneous areas in a specific area. They include a description of the soils and miscellaneous areas and their location on the landscape and tables that show soil properties and limitations affecting various uses. Soil scientists observed the steepness, length, and shape of the slopes; the general pattern of drainage; the kinds of crops and native plants; and the kinds of bedrock. They observed and described many soil profiles. A soil profile is the sequence of natural layers, or horizons, in a soil. The profile extends from the surface down into the unconsolidated material in which the soil formed or from the surface down to bedrock. The unconsolidated material is devoid of roots and other living organisms and has not been changed by other biological activity. Currently, soils are mapped according to the boundaries of major land resource areas (MLRAs). MLRAs are geographically associated land resource units that share common characteristics related to physiography, geology, climate, water resources, soils, biological resources, and land uses (USDA, 2006). Soil survey areas typically consist of parts of one or more MLRA. The soils and miscellaneous areas in a survey area occur in an orderly pattern that is related to the geology, landforms, relief, climate, and natural vegetation of the area. Each kind of soil and miscellaneous area is associated with a particular kind of landform or with a segment of the landform. By observing the soils and miscellaneous areas in the survey area and relating their position to specific segments of the landform, a soil scientist develops a concept, or model, of how they were formed. Thus, during mapping, this model enables the soil scientist to predict with a considerable degree of accuracy the kind of soil or miscellaneous area at a specific location on the landscape. Commonly, individual soils on the landscape merge into one another as their characteristics gradually change. To construct an accurate soil map, however, soil scientists must determine the boundaries between the soils. They can observe only a limited number of soil profiles. Nevertheless, these observations, supplemented by an understanding of the soil-vegetation-landscape relationship, are sufficient to verify predictions of the kinds of soil in an area and to determine the boundaries. Soil scientists recorded the characteristics of the soil profiles that they studied. They noted soil color, texture, size and shape of soil aggregates, kind and amount of rock fragments, distribution of plant roots, reaction, and other features that enable them to identify soils. After describing the soils in the survey area and determining their properties, the soil scientists assigned the soils to taxonomic classes (units). Taxonomic classes are concepts. Each taxonomic class has a set of soil characteristics with precisely defined limits. The classes are used as a basis for comparison to classify soils systematically. Soil taxonomy, the system of taxonomic classification used in the United States, is based mainly on the kind and character of soil properties and the arrangement of horizons within the profile. After the soil scientists classified and named the soils in the survey area, they compared the 5 Custom Soil Resource Report individual soils with similar soils in the same taxonomic class in other areas so that they could confirm data and assemble additional data based on experience and research. The objective of soil mapping is not to delineate pure map unit components; the objective is to separate the landscape into landforms or landform segments that have similar use and management requirements. Each map unit is defined by a unique combination of soil components and/or miscellaneous areas in predictable proportions. Some components may be highly contrasting to the other components of the map unit. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The delineation of such landforms and landform segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, onsite investigation is needed to define and locate the soils and miscellaneous areas. Soil scientists make many field observations in the process of producing a soil map. The frequency of observation is dependent upon several factors, including scale of mapping, intensity of mapping, design of map units, complexity of the landscape, and experience of the soil scientist. Observations are made to test and refine the soil- landscape model and predictions and to verify the classification of the soils at specific locations. Once the soil-landscape model is refined, a significantly smaller number of measurements of individual soil properties are made and recorded. These measurements may include field measurements, such as those for color, depth to bedrock, and texture, and laboratory measurements, such as those for content of sand, silt, clay, salt, and other components. Properties of each soil typically vary from one point to another across the landscape. Observations for map unit components are aggregated to develop ranges of characteristics for the components. The aggregated values are presented. Direct measurements do not exist for every property presented for every map unit component. Values for some properties are estimated from combinations of other properties. While a soil survey is in progress, samples of some of the soils in the area generally are collected for laboratory analyses and for engineering tests. Soil scientists interpret the data from these analyses and tests as well as the field-observed characteristics and the soil properties to determine the expected behavior of the soils under different uses. Interpretations for all of the soils are field tested through observation of the soils in different uses and under different levels of management. Some interpretations are modified to fit local conditions, and some new interpretations are developed to meet local needs. Data are assembled from other sources, such as research information, production records, and field experience of specialists. For example, data on crop yields under defined levels of management are assembled from farm records and from field or plot experiments on the same kinds of soil. Predictions about soil behavior are based not only on soil properties but also on such variables as climate and biological activity. Soil conditions are predictable over long periods of time, but they are not predictable from year to year. For example, soil scientists can predict with a fairly high degree of accuracy that a given soil will have a high water table within certain depths in most years, but they cannot predict that a high water table will always be at a specific level in the soil on a specific date. After soil scientists located and identified the significant natural bodies of soil in the survey area, they drew the boundaries of these bodies on aerial photographs and identified each as a specific map unit. Aerial photographs show trees, buildings, fields, roads, and rivers, all of which help in locating boundaries accurately. 6 I I P L I Soil Ma The soil map section includes the soil map for the defined area of interest, a list of soil map units on the map and extent of each map unit, and cartographic symbols displayed on the map. Also presented are various metadata about data used to produce the map, and a description of each soil map unit. I 1 I ri I I I I I I I I 1 7 Custom Soil Resource Report I 12 Soil Map bo 470650 470730 47081( 470806 171050 47fl 3388N Ix j4 338N it Ali - I _ AR, I '1: i I Olk I - . Q 7 k 4 " •. Al .. .. - --- - i 11 - -- - 33°746N 33746N LJtL) 470730 470810 470898 4709/0 471050 471130 MapS :1:3,260 ndonApor1ait(85"x11")sht Ms N 0 45 90 180 270 A Feet ,\\ 0 150 300 600 900 Map pnjedion: Web Mer Comer WGS84 Edge ths: 5M Zone uN WG584 8 I Area of Interest (AOl) Area of Interest (AOl) Soils Soil Map Unit Polygons Soil Map Unit Lines 111 Soil Map Unit Points Special Point Features w Blowout 10 Borrow Pit X Clay Spot Closed Depression Gravel Pit Gravelly Spot o Landfill A. Lava Flow Marsh or swamp Mine or Quarry 0 Miscellaneous Water 0 Perennial Water Rock Outcrop + Saline Spot :-: Sandy Spot Severely Eroded Spot • Sinkhole Slide or Slip Sodic Spot Custom Soil Resource Report MAP LEGEND MAP INFORMATION 1p Spoil Area The soil surveys that comprise your AOl were mapped at 1:24,000. 0 Stony Spot Warning: Soil Map may not be valid at this scale. Very Stony Spot Wet Spot Enlargement of maps beyond the scale of mapping can cause misunderstanding of the detail of mapping and accuracy of soil line A Other placement. The maps do not show the small areas of contrasting .. Special Line Features soils that could have been shown at a more detailed scale. Water Features Streams and Canals Please rely on the bar scale on each map sheet for map measurements. Transportation Rails Source of Map: Natural Resources Conservation Service Interstate Highways Web Soil Survey URL: http://websoilsurvey.nrcs.usda.gov Coordinate System: Web Mercator (EPSG:3857) US Routes Major Roads Maps from the Web Soil Survey are based on the Web Mercator projection, which preserves direction and shape but distorts Local Roads distance and area. A projection that preserves area, such as the Background Albers equal-area conic projection, should be used if more accurate Aerial Photography calculations of distance or area are required. This product is generated from the USDA-NRCS certified data as of the version date(s) listed below. Soil Survey Area: San Diego County Area, California Survey Area Data: Version 8, Sep 17, 2014 Soil map units are labeled (as space allows) for map scales 1:50,000 or larger. Date(s) aerial images were photographed: Data not available. The orthophoto or other base map on which the soil lines were compiled and digitized probably differs from the background imagery displayed on these maps. As a result, some minor shifting of map unit boundaries may be evident. Custom Soil Resource Report Map Unit Legend San Diego County Area, California (CA638) Map Unit Symbol Map Unit Name Acres in AOl Percent of AOl CbB Carlsbad gravelly loamy sand, 2 to 5 percent slopes 8.4 30.5% LeE Las Flores loamy fine sand, 15 to 30 percent slopes 0.4 1.5% MIC Marina loamy coarse sand, 2 to 9 percent slopes 18.8 68.0% Totals for Area of Interest 27.6 100.0% Map Unit Descriptions The map units delineated on the detailed soil maps in a soil survey represent the soils or miscellaneous areas in the survey area. The map unit descriptions, along with the maps, can be used to determine the composition and properties of a unit. A map unit delineation on a soil map represents an area dominated by one or more major kinds of soil or miscellaneous areas. A map unit is identified and named according to the taxonomic classification of the dominant soils. Within a taxonomic class there are precisely defined limits for the properties of the soils. On the landscape, however, the soils are natural phenomena, and they have the characteristic variability of all natural phenomena. Thus, the range of some observed properties may extend beyond the limits defined for a taxonomic class. Areas of soils of a single taxonomic class rarely, if ever, can be mapped without including areas of other taxonomic classes. Consequently, every map unit is made up of the soils or miscellaneous areas for which it is named and some minor components that belong to taxonomic classes other than those of the major soils. Most minor soils have properties similar to those of the dominant soil or soils in the map unit, and thus they do not affect use and management. These are called noncontrasting, or similar, components. They may or may not be mentioned in a particular map unit description. Other minor components, however, have properties and behavioral characteristics divergent enough to affect use or to require different management. These are called contrasting, or dissimilar, components. They generally are in small areas and could not be mapped separately because of the scale used. Some small areas of strongly contrasting soils or miscellaneous areas are identified by a special symbol on the maps. If included in the database for a given area, the contrasting minor components are identified in the map unit descriptions along with some characteristics of each. A few areas of minor components may not have been observed, and consequently they are not mentioned in the descriptions, especially where the pattern was so complex that it was impractical to make enough observations to identify all the soils and miscellaneous areas on the landscape. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The objective of mapping is not to delineate pure taxonomic classes but rather to separate the landscape into landforms or Iandform segments that have similar use and management requirements. The delineation of such segments 10 Custom Soil Resource Report on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, however, onsite investigation is needed to define and locate the soils and miscellaneous areas. An identifying symbol precedes the map unit name in the map unit descriptions. Each description includes general facts about the unit and gives important soil properties and qualities. Soils that have profiles that are almost alike make up a soil series. Except for differences in texture of the surface layer, all the soils of a series have major horizons that are similar in composition, thickness, and arrangement. Soils of one series can differ in texture of the surface layer, slope, stoniness, salinity, degree of erosion, and other characteristics that affect their use. On the basis of such differences, a soil series is divided into soil phases. Most of the areas shown on the detailed soil maps are phases of soil series. The name of a soil phase commonly indicates a feature that affects use or management. For example, Alpha silt loam, 0 to 2 percent slopes, is a phase of the Alpha series. Some map units are made up of two or more major soils or miscellaneous areas. These map units are complexes, associations, or undifferentiated groups. A complex consists of two or more soils or miscellaneous areas in such an intricate pattern or in such small areas that they cannot be shown separately on the maps. The pattern and proportion of the soils or miscellaneous areas are somewhat similar in all areas. Alpha-Beta complex, 0 to 6 percent slopes, is an example. An association is made up of two or more geographically associated soils or miscellaneous areas that are shown as one unit on the maps. Because of present or anticipated uses of the map units in the survey area, it was not considered practical or necessary to map the soils or miscellaneous areas separately. The pattern and relative proportion of the soils or miscellaneous areas are somewhat similar. Alpha- Beta association, 0 to 2 percent slopes, is an example. An undifferentiated group is made up of two or more soils or miscellaneous areas that could be mapped individually but are mapped as one unit because similar interpretations can be made for use and management. The pattern and proportion of the soils or miscellaneous areas in a mapped area are not uniform. An area can be made up of only one of the major soils or miscellaneous areas, or it can be made up of all of them. Alpha and Beta soils, 0 to 2 percent slopes, is an example. Some surveys include miscellaneous areas. Such areas have little or no soil material and support little or no vegetation. Rock outcrop is an example. 11 Custom Soil Resource Report San Diego County Area, California CbB—Carlsbad gravelly loamy sand, 2 to 5 percent slopes Map Unit Setting National map unit symbol: hb98 Elevation: 30 to 300 feet Mean annual precipitation: 10 to 16 inches Frost-free period: 330 to 350 days Farmland classification: Farmland of statewide importance Map Unit Composition Carlsbad and similar soils: 85 percent Minor components: 15 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Carlsbad Setting Landform: Hillslopes Landform position (two-dimensional): Backslope Landform position (three-dimensional): Side slope Down-slope shape: Convex Across-slope shape: Convex Parent material: Ferruginous sandstone Typical profile HI - 0 to 21 inches: gravelly loamy sand H2 - 21 to 36 inches: loamy sand H3 - 36 to 50 inches: indurated Properties and qualities Slope: 2 to 5 percent Depth to restrictive feature: 24 to 40 inches to duripan Natural drainage class: Moderately well drained Runoff class: Very low Capacity of the most limiting layer to transmit water (Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water storage in profile: Very low (about 2.4 inches) Interpretive groups Land capability classification (irrigated): 2e Land capability classification (nonimgated): 3e Hydrologic Soil Group: B Ecological site: Sandy (1975) (ROI9XD035CA) Minor Components Chesterton Percent of map unit: 5 percent Marina Percent of map unit: 5 percent 12 Custom Soil Resource Report Unnamed, ponded Percent of map unit: 4 percent Landform: Depressions Unnamed Percent of map unit: 1 percent Landform: Swales LeE—Las Flores loamy fine sand, 15 to 30 percent slopes Map Unit Setting National map unit symbol: hbdd Elevation: 700 feet Mean annual precipitation: 12 inches Mean annual air temperature: 61 degrees F Frost-free period: 300 to 340 days Farmland classification: Not prime farmland Map Unit Composition Las fibres and similar soils: 85 percent Minor components: 15 percent Estimates are based on observations, descriptions, and transacts of the mapunit. Description of Las Flores Setting Landform: Hilislopes Landform position (two-dimensional): Backsiope Landform position (three-dimensional): Side slope Down-slope shape: Convex Across-slope shape: Convex Parent material: Residuum weathered from siliceous calcareous sandstone Typical profile HI - 0 to 16 inches: loamy fine sand H2 - 16 to 28 inches: sandy clay, clay H2 - 16 to 28 inches: sandy clay, clay H3 -28 to 38 inches: loamy coarse sand H3 -28 to 38 inches: weathered bedrock H4 -38 to 48 inches: H5 -48 to 52 inches: Properties and qualities Slope: 15 to 30 percent Depth to restrictive feature: 40 to 60 inches to paralithic bedrock Natural drainage class: Moderately well drained Runoff class: Very high Capacity of the most limiting layer to transmit water (Ksat): Very low to moderately low (0.00 to 0.06 in/hr) Depth to water table: More than 80 inches 13 Custom Soil Resource Report Frequency of flooding: None Frequency of ponding: None Sodium adsorption ratio, maximum in profile: 30.0 Available water storage in profile: Low (about 4.2 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6e Hydrologic Soil Group: 0 Ecological site: Claypan (1975) (ROI9XD06I CA) Minor Components Huerhuero Percent of map unit: 5 percent Linne Percent of map unit: 5 percent Diablo Percent of map unit: 5 percent MIC—Marina loamy coarse sand, 2 to 9 percent slopes Map Unit Setting National map unit symbol: hbdz Mean annual air temperature: 57 to 61 degrees F Farmland classification: Prime farmland if irrigated Map Unit Composition Marina and similar soils: 85 percent Minor components: 15 percent Estimates are based on observations, descriptions, and transacts of the mapunit. Description of Marina Setting Landform: Ridges Down-slope shape: Linear Across-slope shape: Linear Parent material: Eolian sands derived from mixed sources Typical profile HI -0 to 10 inches: loamy coarse sand H2 - 10 to 57 inches: loamy sand, loamy coarse sand H2 - 10 to 57 inches: sand, coarse sand H3 - 57 to 60 inches: H3 - 57 to 60 inches: Properties and qualities Slope: 2 to 9 percent Depth to restrictive feature: More than 80 inches 14 Custom Soil Resource Report Natural drainage class: Somewhat excessively drained Runoff class: Medium Capacity of the most limiting layer to transmit water (Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Salinity, maximum in profile: Nonsaline (0.0 to 2.0 mmhos/cm) Available water storage in profile: Moderate (about 8.7 inches) Interpretive groups Land capability classification (irrigated): 3s Land capability classification (nonirrigated): 4e Hydrologic Soil Group: B Minor Components Carlsbad Percent of map unit: 5 percent Chesterton Percent of map unit: 5 percent Corralitos Percent of map unit: 5 percent 15 References American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing. 24th edition. American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes. ASTM Standard D2487-00. Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe. 1979. Classification of wetlands and deep-water habitats of the United States. U.S. Fish and Wildlife Service FWS/OBS-79/31. Federal Register. July 13, 1994. Changes in hydric soils of the United States. Federal Register. September 18, 2002. Hydric soils of the United States. Hurt, G.W., and L.M. Vasilas, editors. Version 6.0,2006. Field indicators of hydric soils in the United States. National Research Council. 1995. Wetlands: Characteristics and boundaries. Soil Survey Division Staff. 1993. Soil survey manual. Soil Conservation Service. U.S. Department of Agriculture Handbook 18. http://www.nrcs.usda.gov/wps/portal/nrcs/ detail/national/soils/?cid=nrcs142p2_054262 Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys. 2nd edition. Natural Resources Conservation Service, U.S. Department of Agriculture Handbook 436. http://www.nrcs.usda.gov/wps/portal/ nrcs/detail/national/soils/?cid=nrcs142p2_053577 Soil Survey Staff. 2010. Keys to soil taxonomy. 11th edition. U.S. Department of Agriculture, Natural Resources Conservation Service. http://www.nrcs.usda.gov/wps/ portal/nrcs/detail/national/soils/?cid=nrcs142p2_053580 Tiner, R.W., Jr. 1985. Wetlands of Delaware. U.S. Fish and Wildlife Service and Delaware Department of Natural Resources and Environmental Control, Wetlands Section. United States Army Corps of Engineers, Environmental Laboratory. 1987. Corps of Engineers wetlands delineation manual. Waterways Experiment Station Technical Report Y-87-1. United States Department of Agriculture, Natural Resources Conservation Service. National forestry manual. http://www.nrcs.usda.gov/wps/portal/nrcs/detail/soils/ home/?cid=nrcs142p2 053374 United States Department of Agriculture, Natural Resources Conservation Service. National range and pasture handbook. http://www.nrcs.usda.gov/wps/portal/nrcs/ detail/national/landuse/rangepasture/?cid=ste1prdb1043084 16 Custom Soil Resource Report United States Department of Agriculture, Natural Resources Conservation Service. National soil survey handbook, title 430-VI. http:llwww.nrcs.usda.gov/wps/portal/ nrcs/detail/soils/scientists/?cid=nrcs142p2_054242 United States Department of Agriculture, Natural Resources Conservation Service. 2006. Land resource regions and major land resource areas of the United States, the Caribbean, and the Pacific Basin. U.S. Department of Agriculture Handbook 296. http:/Iwww.nrcs.usda.gov/wps/portal/nrcs/detail/national/soils/? cid=nrcs142p2_053624 United States Department of Agriculture, Soil Conservation Service. 1961. Land capability classification. U.S. Department of Agriculture Handbook 210. http:ll www.nrcs.usda.gov/IntemetIFSE_DOCUMENTS/nrcs142p2_052290.pdf 17 Attachment C Pre-Development Hydrologic Maps (From Phases I and II) Post-Development Hydrologic Maps __J-1 — . — — — — — -I - — 1 — — / (3 / / PPOV![C/ /2O(J0/D4Y - I / - L MARBRISA -PHASE III , i _) 2 'RESORT SITE - PHASE , - - MARBRISA - PHSE v - -- LocTs0uN94 MARBRISA - PHASE II LEGEND -- N I/(oJ7/7 11A "N (5) -N I ' THIS MAP IS TAKEN FROM THE POST DEVELOPMENT DRAINAGE MAP FOR PHASE I / EXCEL THIS MAP IS NOT AN EXACT REPRESENTATION OF THE ACTUAL ENGINEER G SITE CONDITION. IT IS A REPRESENTATION Of THE CONDITION Of V THE SITE PLANS THAT ARE PSRrED TO THIS POINT. PHASE IN Of THE PROJECT IS DESIGNED TO PRODUCE LESS RUNOFF THAN PHASE I AND U OF THE PROJECT. / Pre-Development Hydrologic Tributary Areas Carlsbad Ranch, Planning Area 5 MarBrisa Phase Ill CARLSBAD. CALIFORNIA i7 Grand Pacific Resorts D.1. 18AP.2010 Numb. 14.100 -- 72 I ,il Al- FRC TAN I ' POST DEVELOPEME 13 1 LPIIAOEMAPFORPt / /SORMØR N\\N H •••• / 2—" "0UtFALL I r 'L 2 N H . LEGEND N - raw HYDROLOGY TRIBUTARY AREA INDICATES TRIBUTARY AREA BOUNDARY -:7 1A..TY Oil PERMUS AREA/-ANDSCAPE AREA 16' CONCRETE P—MENT ON SIDEWALK DRAINING TO OUVALL I (NODES I TO 40 & 100 TO 106) Aa OR 'LOW DIRECTION e dl _ —S-TORMDk4IN / Pre-Dev.lopment Hydrologic Trlbutar/ Areas 2- Carlsbad Ranch, Planning Area 5 MarBrisa Phase Ifi N CARL$IAO CALIPORNIA Grand Pacific Resorts D.I.-.*Mfl P.4,iiiIk W.., 1 _ - - - - - - - - - - - - - - - — - - - - - - - _ - _ -- I - - Post-Development Hydrologic Tributary Areas Phase III / Carlsbad Ranch Planning Area 5 MaiBrisa CARLSBAD, CALIFORNIA Grand Pacific Resorts " 20 APRIL 2015 14-100 •_C"t__,_.__._ - - (_7 -1?LE GEND - iwc- ol — — — — \ U 0 I - - •0 01 elm - N * / - - ,- -, M F, o 171 A17 \\ \ 0 ri ET00 - & \ on 8 68 178 I6'O /81' , /III Al QJ SUMMARY TABLE 440 STATE PXE ESCONDIDO, CA 92029 11 1/ 21:1 ENGINEERING TEL (760) 745-8118 FAX (760) 745-1890 Attachment D Civil D Pre-Development Hydrology Calculations (From Phases I & II) ++ ++ ++ ++ + +++++++++++++++++++++ +++++++++ + ++++++++++ + + + + + Process from Point/Station 51.000 to Point/Station 53.000 '''' PIPEFLOW TRAVEL TIME (User specified size) Upstream point/station elevation = 186.500 (Ft.) Downstream point/station elevation = 185.430 (Ft.) Pipe length = 37.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.656(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.656(CFS) Normal flow depth in pipe 2.67(In.) Flow top width inside pipe = 9.98(In.) Critical Depth = 4.05(In.) Pipe flow velocity = 5.05(Ft/s) Travel time through pipe = 0.12 mm. Time of concentration (TC) = 9.24 mm. +++++++++++++ ++ +++ +++++++++++++++ + +++++++++++ ++++++++ +++++++++++ + +++ + + Process from Point/Station 53.000 to Point/Station 53.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number Stream flow area = 0.224 (Ac.) Runoff from this stream = 0.656(CFS) Time of concentration = 9.24 mm. Rainfall intensity = 4.611(In/Hr) ++++++++++++++++.+++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 52.000 to Point/Station 53.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 202.000(Ft.) Highest elevation = 190.870(Ft.) Lowest elevation = 189.800(Ft.) Elevation difference = 1.070(Ft.) Slope = 0.530 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 50.00 (Ft) for the top area slope value of 0.53 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.39 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope'(1/3)] TC = [1.8*(1.1_0.6300)*( 50.000.5)/( 0.530"(1/3)]= 7.39 The initial area total distance of 202.00 (Ft.) entered leaves a remaining distance of 152.00 (Ft.) Using Figure 3-4, the travel time for this distance is 2.81 minutes for a distance of 152.00 (Ft.) and a slope of 0.53 % with an elevation difference of 0.81(Ft.) from the end of the top area Tt = (ll.9*length(Mi)3)/(elevation change(Ft.))1'.385 *60(min/hr) = 2.810 Minutes Tt=((ll.9*0.02883)/( 0.81)].385= 2.81 Total initial area Ti = 7.39 minutes from Figure 3-3 formula plus 2.81 minutes from the Figure 3-4 formula = 10.20 minutes Rainfall intensity (I) = 4.324(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 1.891(CFS) Total initial stream area = 0.694(Ac.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 2 of 18 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 53.000 to Point/Station 53.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.694 (Ac.) Runoff from this stream = 1.891(CFS) Time of concentration = 10.20 mm. Rainfall intensity = 4.324(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 0.656 9.24 4.611 2 1.891 10.20 4.324 Qmax(1) = 1.000 * 1.000 * 0.656) + 1.000 * 0.905 * 1.891) + = 2.368 Qmax(2) 0.938 * 1.000 * 0.656) + 1.000 * 1.000 * 1.891) + = 2.506 Total of 2 streams to confluence: Flow rates before confluence point: 0.656 1.891 Maximum flow rates at confluence using above data: 2.368 2.506 Area of streams before confluence: 0.224 0.694 Results of confluence: Total flow rate = 2.506(CFS) Time of concentration = 10.202 mm. Effective stream area after confluence = 0.918(Ac.) Process from Point/Station 53.000 to Point/Station 55.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.430 (Ft.) Downstream point/station elevation = 185.140 (Ft.) Pipe length = 32.70(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 2.506(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 2.506(CFS) Normal flow depth in pipe = 6.18(In.) Flow top width inside pipe = 17.09(In.) Critical Depth = 7.19(In.) Pipe flow velocity = 4.67(Ft/s) Travel time through pipe = 0.12 mm. Time of concentration (TC) = 10.32 mm. Process from Point/Station 55.000 to Point/Station 55.000 **** SUBAREA FLOW ADDITION User specified 'C' value of 0.630 given for subarea Time of concentration 10.32 mm. Rainfall intensity = 4.293(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.747 Subarea runoff = 0.701(CFS) for 0.268(Ac.) Total runoff = 3.208(CFS) Total area = 1.186(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 55.000 to Point/Station 58.000 PIPEFLOW TRAVEL TIME (User specified size) **** Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 3 of 18 Upstream point/station elevation = 185.140 (Ft.) Downstream point/station elevation = 183.920(Ft.) Pipe length = 187,.60(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.208(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 3.208(CFS) Normal flow depth in pipe = 7.68(In.) Flow top width inside pipe = 17.80(In.) Critical Depth = 8.18(In.) Pipe flow velocity = 4.46(Ft/s) Travel time through pipe = 0.70 mm. Time of concentration (TC) = 11.02 mm. ++ +++++++++++++ + + ++++++++++++ + + ++++++++++ + +++++++++ + + +++++++ + +++++ + Process from Point/Station 58.000 to Point/Station 58.000 **** CONFLUENCE OF MINOR STREAMS '''' Along Main Stream number: 1 in normal stream number Stream flow area = 1.186(Ac.) Runoff from this stream = 3.208(CFS) Time of concentration = 11.02 mm. Rainfall intensity = 4.115(In/Hr) ++ +++++++++ + + + + ++ +++++++ + ++++++++++++++++++++ + +++++++ ++ + + + Process from Point/Station 56.000 to Point/Station 57.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 168.000(Ft.) Highest elevation = 190.200(Ft.) Lowest elevation = 189.330(Ft.) Elevation difference = 0.870(Ft.) Slope = 0.518 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 50.00 (Ft) for the top area slope value of 0.52 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.45 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 50.000.5)/( 0.518'(1/3)]= 7.45 The initial area total distance of 168.00 (Ft.) entered leaves a remaining distance of 118.00 (Ft.) Using Figure 3-4, the travel time for this distance is 2.33 minutes for a distance of 118.00 (Ft.) and a slope of 0.52 % with an elevation difference of 0.61(Ft.) from the end of the top area Tt = (11.9*length(Mi)3)/(elevation change(Ft.))1".385 *60(min/hr) = 2.333 Minutes Tt=( (11.9*0.02233)/( 0.61)1 ^.385= 2.33 Total initial area Ti = 7.45 minutes from Figure 3-3 formula plus 2.33 minutes from the Figure 3-4 formula = 9.78 minutes Rainfall intensity (I) = 4.444(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.677(CFS) Total initial stream area = 0.242(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 57.000 to Point/Station 57.000 SUBAREA FLOW ADDITION **** User specified 'C' value of 0.630 given for subarea Time of concentration = 9.78 mm. Rainfall intensity = 4.444(In/Hr) for a 100.0 year storm Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 4 of 18 Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.307 Subarea runoff = 0.686(CFS) for 0.245(Ac.) Total runoff = 1.363(CFS) Total area = 0.487(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 57.000 to Point/Station 58.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.770 (Ft.) Downstream point/station elevation = 183.920 (Ft.) Pipe length = 6.30(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow 1.363(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 1.363(CFS) Normal flow depth in pipe = 2.16(In.) Flow top width inside pipe = 9.22(In.) Critical Depth = 5.93(In.) Pipe flow velocity = 14.19(Ft/s) Travel time through pipe = 0.01 mm. Time of concentration (TC) = 9.79 mm. ++ + +++++++++++++++++++ + + + +++++ +++++++++++ + +++++++ + +++++++ + ++ + Process from Point/Station 58.000 to Point/Station 58.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.487 (Ac.) Runoff from this stream = 1.363(CFS) Time of concentration = 9.79 mm. Rainfall intensity = 4.441(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 3.208 11.02 4.115 2 1.363 9.79 4.441 Qmax(1) = 1.000 * 1.000 * 3.208) + 0.926 * 1.000 * 1.363) + = 4.471 Qmax(2) = 1.000 * 0.888 * 3.208) + 1.000 * 1.000 * 1.363) + = 4.213 Total of 2 streams to confluence: Flow rates before confluence point: 3.208 1.363 Maximum flow rates at confluence using above data: 4.471 4.213 Area of streams before confluence: 1.186 0.487 Results of confluence: Total flow rate = 4.471(CFS) Time of concentration = 11.020 mm. Effective stream area after confluence = 1.673(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 58.000 to Point/Station 61.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 183.920(Ft.) Downstream point/station elevation = 183.610(Ft.) Pipe length = 62.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 4.471(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 4.471(CFS) Normal flow depth in pipe = 10.07(In.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 5 of 18 Flow top width inside pipe = 17.87(In.) Critical Depth = 9.75(In.) Pipe flow velocity = 4.40(Ft/s) Travel time through pipe = 0.24 mm. Time of concentration (TC) = 11.26 mm. +++++++++++++++++++++++...++++++.+++++++.+++++++++++++++++...+++++++++ Process from Point/Station 61.000 to Point/Station 61.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 1.673(Ac.) Runoff from this stream = 4.471(CFS) Time of concentration = 11.26 mm. Rainfall intensity = 4.059(In/Hr) + ++++++ + ++++++++ + ++ ++++++++++++++++++++++++ + Process from Point/Station 59.000 to Point/Station 60.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 110.000 (Ft.) Highest elevation = 190.600(Ft.) Lowest elevation = 189.650(Ft.) Elevation difference = 0.950(Ft.) Slope = 0.864 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.86 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.16 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = (1.8*(1.1_0.6300)*( 65.000.5)/( 0.864(1/3)]= 7.16 The initial area total distance of 110.00 (Ft.) entered leaves a remaining distance of 45.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.91 minutes for a distance of 45.00 (Ft.) and a slope of 0.86 % with an elevation difference of 0.39(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))1".385 *60(min/hr) = 0.912 Minutes Tt=( (1l.9*0.00853)/( 0.39) 1.385= 0.91 Total initial area Ti = 7.16 minutes from Figure 3-3 formula plus 0.91 minutes from the Figure 3-4 formula = 8.07 minutes Rainfall intensity (I) = 5.029(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.783(CFS) Total initial stream area = 0.247 (Ac.) Process from Point/Station 60.000 to Point/Station 61.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.300 (Ft.) Downstream point/station elevation = 183.610(Ft.) Pipe length = 89.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.783(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.783(CFS) Normal flow depth in pipe = 2.88 (In.) Flow top width inside pipe = 10.25(In.) Critical Depth = 4.43(In.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 6 of 18 Pipe flow velocity = 5.40(Ft/s) Travel time through pipe = 0.27 mm. Time of concentration (TC) = 8.35 mm. Process from Point/Station 61.000 to Point/Station 61.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.247 (Ac.) Runoff from this stream 0.783(CFS) Time of concentration 8.35 mm. Rainfall intensity = 4.922(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 4.471 11.26 4.059 2 0.783 8.35 4.922 Qmax(1) = 1.000 * 1.000 * 4.471) + 0.825 * 1.000 * 0.783) + = 5.116 Qmax(2) = 1.000 * 0.742 * 4.471) + 1.000 * 1.000 * 0.783) + = 4.098 Total of 2 streams to confluence: Flow rates before confluence point: 4.471 0.783 Maximum flow rates at confluence using above data: 5.116 4.098 Area of streams before confluence: 1.673 0.247 Results of confluence: Total flow rate = 5.116(CFS) Time of concentration = 11.255 mm. Effective stream area after confluence = 1.920(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 61.000 to Point/Station 64.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 183.610 (Ft.) Downstream point/station elevation = 183.540(Ft.) Pipe length = 13.20(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.116(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 5.116(CFS) Normal flow depth in pipe = 10.77 (In.) Flow top width inside pipe = 17.65(In.) Critical Depth = 10.45(In.) Pipe flow velocity = 4.64(Ft/s) Travel time through pipe = 0.05 mm. Time of concentration (TC) = 11.30 mm. Process from Point/Station 64.000 to Point/Station 64.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 1.920(Ac.) Runoff from this stream = 5.116(CFS) Time of concentration = 11.30 mm. Rainfall intensity = 4.048(In/Hr) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 7 of 18 Process from Point/Station 62.000 to Point/Station 63.000 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 207.000(Ft.) Highest elevation = 198.700(Ft.) Lowest elevation = 190.420(Ft.) Elevation difference = 8.280(Ft.) Slope = 4.000 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 4.00 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.33 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 100.000'.5)/( 4.000(1/3)]= 5.33 The initial area total distance of 207.00 (Ft.) entered leaves a remaining distance of 107.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.98 minutes for a distance of 107.00 (Ft.) and a slope of 4.00 % with an elevation difference of 4.28(Ft.) from the end of the top area Tt = (11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 0.985 Minutes Tt=((11.9*0.02033)/( 4.28)].385= 0.98 Total initial area Ti = 5.33 minutes from Figure 3-3 formula plus 0.98 minutes from the Figure 3-4 formula = 6.31 minutes Rainfall intensity (I) = 5.893(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.791(CFS) Total initial stream area = 0.213(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 63.000 to Point/Station 64.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.420 (Ft.) Downstream point/station elevation = 183.540(Ft.) Pipe length = 15.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.791(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.791(CFS) Normal flow depth in pipe = 2.04 (In.) Flow top width inside pipe = 9.01 (In.) Critical Depth = 4.45(In.) Pipe flow velocity = 8.95(Ft/s) Travel time through pipe = 0.03 mm. Time of concentration (TC) = 6.34 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 64.000 to Point/Station 64.000 "' CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number Stream flow area = 0.213(Ac.) Runoff from this stream = 0.791(CFS) Time of concentration = 6.34 mm. Rainfall intensity = 5.876(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 8 of 18 1 5.116 11.30 4.048 2 0.791 6.34 5.876 Qmax(l) = 1.000 * 1.000 * 5.116) + 0.689 * 1.000 * 0.791) + = 5.661 Qmax(2) = 1.000 * 0.561 * 5.116) + 1.000 * 1.000 * 0.791) + 3.662 Total of 2 streams to confluence: Flow rates before confluence point: 5.116 0.791 Maximum flow rates at confluence using above data: 5.661 3.662 Area of streams before confluence: 1.920 0.213 Results of confluence: Total flow rate = 5.661(CFS) Time of concentration = 11.303 mm. Effective stream area after confluence = 2.133(Ac.) + ++++++++ + + +++++++ +++++++ + + + +++++ + +++++++++ ++++++++ + + Process from Point/Station 64.000 to Point/Station 66.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 183.540(Ft.) Downstream point/station elevation = 182.820(Ft.) Pipe length = 161.50(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.661(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 5.661(CFS) Normal flow depth in pipe = 12.26(In.) Flow top width inside pipe = 16.78(In.) Critical Depth = 11.01(m.) Pipe flow velocity = 4.42(Ft/s) Travel time through pipe = 0.61 mm. Time of concentration (TC) = 11.91 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 66.000 to Point/Station 66.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 2.133(Ac.) Runoff from this stream = 5.661(CFS) Time of concentration = 11.91 mm. Rainfall intensity = 3.913(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 7.000 to Point/Station 65.000 "'' 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 101.000(Ft.) Highest elevation = 190.600(Ft.) Lowest elevation = 189.800(Ft.) Elevation difference = 0.800(Ft.) Slope = 0.792 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.79 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 9 of 18 Initial Area Time of Concentration = 7.37 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)1 TC = [1.8*(1.1_0.6300)*( 65.000.5)/( 0.792(1/3)J= 7.37 The initial area total distance of 101.00 (Ft.) entered leaves a remaining distance of 36.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.79 minutes for a distance of 36.00 (Ft.) and a slope of 0.79 % with an elevation difference of 0.29(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 0.794 Minutes Tt=[(11.9*0.0068'3)/( 0.29)J.385= 0.79 Total initial area Ti = 7.37 minutes from Figure 3-3 formula plus 0.79 minutes from the Figure 3-4 formula = 8.17 minutes Rainfall intensity (I) = 4.992(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.887(CFS) Total initial stream area = 0.282(Ac.) ++++++.+.+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 65.000 to Point/Station 66.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.360 (Ft.) Downstream point/station elevation = 182.820(Ft.) Pipe length = 32.00(Ft.) Mannings N = 0.013 No. of pipes = 1 Required pipe flow = 0.887(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.887(CFS) Normal flow depth in pipe = 2.22 (In.) Flow top width inside pipe = 9.32 (In.) Critical Depth = 4.73(In.) Pipe flow velocity = 8.86(Ft/s) Travel time through pipe = 0.06 mm. Time of concentration (TC) = 8.23 mm. Process from Point/Station 66.000 to Point/Station 66.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.282(Ac.) Runoff from this stream = 0.887(CFS) Time of concentration = 8.23 mm. Rainfall intensity = 4.969(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 5.661 11.91 3.913 2 0.887 8.23 4.969 Qmax(l) = 1.000 * 1.000 * 5.661) + 0.788 * 1.000 * 0.887) + = 6.359 Qmax(2) = 1.000 * 0.691 * 5.661) + 1.000 * 1.000 * 0.887) + = 4.796 Total of 2 streams to confluence: Flow rates before confluence point: 5.661 0.887 Maximum flow rates at confluence using above data: 6.359 4.796 Area of streams before confluence: 2.133 0.282 Results of confluence: Total flow rate = 6.359(CFS) Time of concentration = 11.912 mm. Effective stream area after confluence = 2.415(Ac.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE H Page 10 of 18 Process from Point/Station 66.000 to Point/Station 68.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.820(Ft.) Downstream point/station elevation = 182.780 (Ft.) Pipe length = 8.50(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 6.359(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 6.359(CFS) Normal flow depth in pipe 13.13(In.) Flow top width inside pipe = 16.00(In.) Critical Depth = 11.70(In.) Pipe flow velocity = 4.60(Ft/s) Travel time through pipe = 0.03 mm. Time of concentration (TC) = 11.94 mm. +++++ + +++++ + +++++++ +++++++ ++++++++ + +++++++ +++ + + Process from Point/Station 68.000 to Point/Station 68.000 '' CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number Stream flow area = 2.415(Ac.) Runoff from this stream = 6.359(CFS) Time of concentration = 11.94 mm. Rainfall intensity = 3.907(In/Hr) Process from Point/Station 7.000 to Point/Station 67.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 120.000(Ft.) Highest elevation 190.600(Ft.) Lowest elevation = 189.640(Ft.) Elevation difference = 0.960(Ft.) Slope = 0.800 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.80 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.35 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)1 TC = (1.8*(1.1_0.6300)*( 65.000.5)/( 0.800(1/3)]= 7.35 The initial area total distance of 120.00 (Ft.) entered leaves a remaining distance of 55.00 (Ft.) Using Figure 3-4, the travel time for this distance is 1.10 minutes for a distance of 55.00 (Ft.) and a slope of 0.80 % with an elevation difference of 0.44(Ft.) from the end of the top area Tt = (11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(mjn/hr) = 1.096 Minutes Tt=[(11.9*0.01043)/( 0.44)]A.385= 1.10 Total initial area Ti = 7.35 minutes from Figure 3-3 formula plus 1.10 minutes from the Figure 3-4 formula = 8.44 minutes Rainfall intensity (I) = 4.886(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.532(CFS) Total initial stream area = 0.173(Ac.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE H Page 11 of 18 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 67.000 to Point/Station 68.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.640 (Ft.) Downstream point/station elevation = 182.780(Ft.) Pipe length = 8.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.532(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.532(CFS) Normal flow depth in pipe = 1.22 (In.) Flow top width inside pipe 7.25(In.) Critical Depth = 3.63(In.) Pipe flow velocity = 12.76(Ft/s) Travel time through pipe = 0.01 mm. Time of concentration (TC) = 8.45 mm. ++++++++-H-++ ++ + + + +++++++ ++ ++ ++++++++++ + +++++++++ + ++ + Process from Point/Station 68.000 to Point/Station 68.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.173(Ac.) Runoff from this stream = 0.532(CFS) Time of concentration = 8.45 mm. Rainfall intensity = 4.882(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 6.359 11.94 3.907 2 0.532 8.45 4.882 Qmax(1) = - 1.000 * 1.000 * 6.359) + 0.800 * 1.000 * 0.532) + = 6.785 Qmax(2) = 1.000 * 0.708 * 6.359) + 1.000 * 1.000 * 0.532) + = 5.034 Total of 2 streams to confluence: Flow rates before confluence point: 6.359 0.532 Maximum flow rates at confluence using above data: 6.785 5.034 Area of streams before confluence: 2.415 0.173 Results of confluence: Total flow rate = 6.785(CFS) Time of concentration = 11.943 mm. Effective stream area after confluence = 2.588(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 68.000 to Point/Station 71.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.780 (Ft.) Downstream point/station elevation = 181.950(Ft.) Pipe length = 165.50(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 6.785(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 6.785(CFS) Normal flow depth in pipe 13.50 (In.) Flow top width inside pipe = 15.59(In.) Critical Depth = 12.09(In.) Pipe flow velocity = 4.77(Ft/s) Travel time through pipe = 0.58 mm. Time of concentration (TC) = 12.52 mm. Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 12 of 18 Process from Point/Station 71.000 to Point/Station 71.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 2.588(Ac.) Runoff from this stream = 6.785(CFS) Time of concentration = 12.52 mm. Rainfall intensity = 3.789(In/Hr) Process from Point/Station 7.000 to Point/Station 70.000 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 133.600(Ft.) Highest elevation 190.600(Ft.) Lowest elevation = 189.500(Ft.) Elevation difference = 1.100(Ft.) Slope = 0.823 % Top of Initial Area Slope adjusted by User to 0.850 % Bottom of Initial Area Slope adjusted by User to 0.850 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.85 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.20 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)) TC = [1.8*(1.1_0.6300)*( 65.000.5)/( 0.850(1/3)1= 7.20 The initial area total distance of 133.60 (Ft.) entered leaves a remaining distance of 68.60 (Ft.) Using Figure 3-4, the travel time for this distance is 1.27 minutes for a distance of 68.60 (Ft.) and a slope of 0.85 % with an elevation difference of 0.58(Ft.) from the end of the top area Tt = [ll.9*length(Mi)3)/(elevation change(Ft.))J'.385 *60(min/hr) = 1.270 Minutes Tt=[(ll.9*0.0l303)/( 0.58)J.385= 1.27 Total initial area Ti = 7.20 minutes from Figure 3-3 formula plus 1.27 minutes from the Figure 3-4 formula = 8.47 minutes Rainfall intensity (I) = 4.876(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.596(CFS) Total initial stream area = 0.194 (Ac.) Process from Point/Station 70.000 to Point/Station 71.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.950(Ft.) Downstream point/station elevation = 185.570(Ft.) Pipe length = 38.30(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.596(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.596(CFS) Normal flow depth in pipe = 3.33(In.) Flow top width inside pipe = 10.74(In.) Critical Depth = 3.84(In.) Pipe flow velocity = 3.36(Ft/s) Travel time through pipe = 0.19 mm. Time of concentration (TC) = 8.66 mm. Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE H Page 13 of 18 ++ ++++ + + + +++++ + + ++++++ + +++++++ ++ + +++++++++++++++ + Process from Point/Station 71.000 to Point/Station 71.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.194 (Ac.) Runoff from this stream = 0.596(CFS) Time of concentration = 8.66 mm. Rainfall intensity = 4.807(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 6.785 12.52 3.789 2 0.596 8.66 4.807 Qmax(1) = 1.000 * 1.000 * 6.785) + 0.788 * 1.000 * 0.596) + = 7.255 Qmax(2) = 1.000 * 0.692 * 6.785) + 1.000 * 1.000 * 0.596) + 5.289 Total of 2 streams to confluence: Flow rates before confluence point: 6.785 0.596 Maximum flow rates at confluence using above data: 7.255 5.289 Area of streams before confluence: 2.588 0.194 Results of confluence: Total flow rate = 7.255(CFS) Time of concentration = 12.521 mm. Effective stream area after confluence = 2.782(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 71.000 to Point/Station 76.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 181.950 (Ft.) Downstream point/station elevation = 180.960 (Ft.) Pipe length = 99.20(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 7.255(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 7.255(CFS) Normal flow depth in pipe = 9.35(In.) Flow top width inside pipe = 23.41 (In.) Critical Depth = 11.48(In.) Pipe flow velocity = 6.41 (Ft/s) Travel time through pipe = 0.26 mm. Time of concentration (TC) = 12.78 mm. + +++++++++++++++++++++++++ +++++++ +++++++ + +++++++ + + + ++++++++++++++++ + + + Process from Point/Station 76.000 to Point/Station 76.000 **** CONFLUENCE OF MAIN STREAMS The following data inside Main Stream is listed: In Main Stream number: 1 Stream flow area = 2.782 (Ac.) Runoff from this stream = 7.255(CFS) Time of concentration = 12.78 mm. Rainfall intensity = 3.740(In/Hr) Program is now starting with Main Stream No. 2 Process from Point/Station 72.000 to Point/Station 73.000 **** INITIAL AREA EVALUATION Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 14 of 18 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 63.000 (Ft.) Highest elevation = 190.500(Ft.) Lowest elevation = 189.800(Ft.) Elevation difference = 0.700(Ft.) Slope = 1.111 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 1.11 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 6.59 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = (1.8*(1.1_0.6300)*( 65.000'.5)/( l.11l(l/3)]= 6.59 Rainfall intensity (I) = 5.735(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 1.142(CFS) Total initial stream area = 0.316(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 73.000 to Point/Station 75.000 '" PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 187.000(Ft.) Downstream point/station elevation = 183.200 (Ft.) Pipe length = 306.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.142(CFS) Given pipe size = 8.00(In.) Calculated individual pipe flow = 1.142(CFS) Normal flow depth in pipe = 5.65(In.) Flow top width inside pipe = 7.28(In.) Critical Depth = 6.08(In.) Pipe flow velocity = 4.33(Ft/s) Travel time through pipe = 1.18 mm. Time of concentration (TC) = 7.76 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 73.000 to Point/Station 75.000 **** SUBAREA FLOW ADDITION **** User specified 'C' value of 0.630 given for subarea Time of concentration = 7.76 mm. Rainfall intensity = 5.158(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.437 Subarea runoff = 1.113(CFS) for 0.378(Ac.) Total runoff = 2.255(CFS) Total area = 0.694(Ac.) Process from Point/Station 75.000 to Point/Station 75.000 **** SUBAREA FLOW ADDITION User specified 'C' value of 0.630 given for subarea Time of concentration = 7.76 mm. Rainfall intensity = 5.158(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.704 Subarea runoff = 1.374(CFS) for 0.423(Ac.) Total runoff = 3.629(CFS) Total area = 1.117(Ac.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 15 of 18 Process from Point/Station 75.000 to Point/Station 76.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 183.200 (Ft.) Downstream point/station elevation = 181.380 (Ft.) Pipe length = 186.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.629(CFS) Given pipe size = 12.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 0.607(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 1.930(Ft.) Minor friction loss = 0.497(Ft.) K-factor = 1.50 Pipe flow velocity = 4.62 (Ft/s) Travel time through pipe = 0.67 mm. Time of concentration (TC) = 8.43 mm. ++ + ++++++++++ + + + +++++++++ + ++ ++++++++ + +++++++++ + Process from Point/Station 76.000 to Point/Station 76.000 **** CONFLUENCE OF MAIN STREAMS The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 1.117(Ac.) Runoff from this stream = 3.629(CFS) Time of concentration = 8.43 mm. Rainfall intensity = 4.889(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 7.255 12.78 3.740 2 3.629 8.43 4.889 Qmax(1) = 1.000 * 1.000 * 7.255) + 0.765 * 1.000 * 3.629) + = 10.032 Qmax(2) = 1.000 * 0.660 * 7.255) + 1.000 * 1.000 * 3.629) + = 8.418 Total of 2 main streams to confluence: Flow rates before confluence point: 7.255 3.629 Maximum flow rates at confluence using above data: 10.032 8.418 Area of streams before confluence: 2.782 1.117 Results of confluence: Total flow rate = 10.032(CFS) Time of concentration = 12.779 mm. Effective stream area after confluence = 3.899(Ac.) Process from Point/Station 76.000 to Point/Station 106.000 '"' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 181.380 (Ft.) Downstream point/station elevation = 180.640(Ft.) Pipe length = 45.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 10.032(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow 10.032(CFS) Normal flow depth in pipe = 9.74 (In.) Flow top width inside pipe = 23.57 (In.) Critical Depth = 13.59(In.) Pipe flow velocity = 8.39(Ft/s) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 16 of 18 Travel time through pipe = 0.09 mm. Time of concentration (TC) = 12.87 mm. Process from Point/Station 106.000 to Point/Station 106.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 3.899(Ac.) Runoff from this stream = 10.032(CFS) Time of concentration = 12.87 mm. Rainfall intensity = 3.723(In/Hr) +++++++++.+ + + +++++++ + + +++++++++ + +++++++++++++ +++++++++++ +++++++ + + + + Process from Point/Station 106.000 to Point/Station 106.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 4.865(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 8.50 mm. Rain intensity = 4.86(In/Hr) Total area = 17.600(Ac.) Total runoff = 56.220(CFS) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 106.000 to Point/Station 106.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 17.600(Ac.) Runoff from this stream = 56.220(CFS) Time of concentration = 8.50 mm. Rainfall intensity = 4.865(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 10.032 12.87 3.723 2 56.220 8.50 4.865 Qmax(1) = 1.000 * 1.000 * 10.032) + 0.765 * 1.000 * 56.220) + = 53.057 Qmax(2) = 1.000 * 0.661 * 10.032) + 1.000 * 1.000 * 56.220) + = 62.846 Total of 2 streams to confluence: Flow rates before confluence point: 10.032 56.220 Maximum flow rates at confluence using above data: 53.057 62.846 Area of streams before confluence: 3.899 17.600 Results of confluence: Total flow rate = 62.846(CFS) Time of concentration = 8.500 mm. Effective stream area after confluence = 21.499(Ac.) Process from Point/Station 106.000 to Point/Station 107.000 **** IRREGULAR CHANNEL FLOW TRAVEL TIME **** Estimated mean flow rate at midpoint of channel = 62.887(CFS) Depth of flow = 1.717(Ft.), Average velocity = 4.004(Ft/s) ******* Irregular Channel Data *********** ----------------------------------------------------------------- Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 17of18 Information entered for subchannel number 1 Point number 'X' coordinate ty, coordinate 1 0.00 3.70 2 10.30 0.00 3 15.30 0.00 4 27.40 5.90 Manning's 'N' friction factor = 0.035 --------------------------------------------------- Sub-Channel flow = 62.887(CFS) flow top width = 13.299 (Ft.) velocity= 4.004(Ft/s) area = 15.706(Sq.Ft) Froude number = 0.649 Upstream point elevation = 175.700 (Ft.) Downstream point elevation 173.260 (Ft.) Flow length 320.000(Ft.) Travel time = 1.33 mm. Time of concentration = 9.83 mm. Depth of flow = 1.717(Ft.) Average velocity = 4.004(Ft/s) Total irregular channel flow = 62.887(CFS) Irregular channel normal depth above invert elev. = 1.717 (Ft.) Average velocity of channel(s) = 4.004(Ft/s) Adding area flow to channel User specified 'C' value of 0.630 given for subarea The area added to the existing stream causes a a lower flow rate of Q = 60.617(CFS) therefore the upstream flow rate of Q = 62.846(CFS) is being used Rainfall intensity = 4.429(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 13.687 Subarea runoff = 0.000(CFS) for 0.226(Ac.) Total runoff = 62.846(CFS) Total area = 21.725(Ac.) Depth of flow = 1.716(Ft.), Average velocity = 4.003(Ft/s) End of computations, total study area = 21.725 (Ac.) Outfall A Continued TAKEN FROM HYDROLOGY STUDY PHASE II Page 18 of 18 San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software, (C) 1991-2004 Version 7.4 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 10/03/11 ----------------------------------------------------------------- CT 03-02 CARLSBAD RANCH PLANNING AREA 5 - MARBRISA SITE PHASE III 100 YEAR STORM, Pre-DEVELOPMENT OUTFALL A - NODES 1 TO 40, NODES 100 TO 106 ---------------------------------------------------------- ********* Hydrology Study Control Information Program License Serial Number 4012 -------------------------------------------------------- Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) 4.500 P6/P24 = 57.8% San Diego hydrology manual C' values used 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 139.000(Ft.) Highest elevation = 199.000(Ft.) Lowest elevation = 194.500(Ft.) Elevation difference = 4.500(Ft.) Slope = 3.237 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 3.24 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.43 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = (1.8*(1.1_0.6300)*( 90.000.5)/( 3.237(1/3)1= 5.43 The initial area total distance of 139.00 (Ft.) entered leaves a remaining distance of 49.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.59 minutes for a distance of 49.00 (Ft.) and a slope of 3.24 % with an elevation difference of 1.59(Ft.) from the end of the top area Tt = (1l.9*length(Mi)3)/(elevation change(Ft.))]'.385 *60(min/hr) = 0.586 Minutes Tt=[(1l.9*0.00933)/( 1.59)].385= 0.59 Total initial area Ti 5.43 minutes from Figure 3-3 formula plus 0.59 minutes from the Figure 3-4 formula = 6.01 minutes Rainfall intensity (I) = 6.083(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.383(CFS) Total initial stream area = 0.100(Ac.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE 11 Page 1 of 21 ++++++.++++4-+++++++++++++++++++++++++++++++++++++++++..+.+++++++++++++ Process from Point/Station 2.000 to Point/Station 101.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 190.500 (Ft.) Downstream point/station elevation = 181.130 (Ft.) Pipe length = 10.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow 0.383(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.383(CFS) Normal flow depth in pipe = 0.89(In.) Flow top width inside pipe = 6.29(In.) Critical Depth = 3.07 (In.) Pipe flow velocity = 14.55(Ft/s) Travel time through pipe = 0.01 mm. Time of concentration (TC) = 6.02 mm. Process from Point/Station 101.000 to Point/Station 101.000 **** CONFLUENCE OF MINOR STREAMS '''' Along Main Stream number: 1 in normal stream number Stream flow area = 0.100 (Ac.) Runoff from this stream = 0.383(CFS) Time of concentration = 6.02 mm. Rainfall intensity = 6.076(In/Hr) + + + +++++ + ++++++++++ ++ + + ++++++++++++ + +++++ + Process from Point/Station 100.000 to Point/Station 100.000 **** USER DEFINED FLOW INFORMATION AT A POINT User specified 'C' value of 0.770 given for subarea Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 5.00 mm. Rain intensity = 6.85(In/Hr) Total area = 10.160(Ac.) Total runoff = 45.050(CFS) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 100.000 to Point/Station 101.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.660(Ft.) Downstream point/station elevation = 181.130(Ft.) Pipe length = 35.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 45.050(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 45.050(CFS) Normal flow depth in pipe = 14.07(In.) Flow top width inside pipe = 35.13(In.) Critical Depth = 26.24(In.) Pipe flow velocity = 17.60(Ft/s) Travel time through pipe = 0.03 mm. Time of concentration (TC) = 5.03 mm. ++++++++++++++++++++++++++++++++ ++ ++++ + ++++++++++ + + + ++++++++++ + ++++++ + Process from Point/Station 101.000 to Point/Station 101.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 10.160(Ac.) Runoff from this stream 45.050(CFS) Time of concentration = 5.03 mm. Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 2 of 21 Rainfall intensity = 6.821(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 0.383 6.02 6.076 2 45.050 5.03 6.821 Qmax(1) = 1.000 * 1.000 * 0.383) + 0.891 * 1.000 * 45.050) + = 40.508 Qmax(2) = 1.000 * 0.836 * 0.383) + 1.000 * 1.000 * 45.050) + = 45.370 Total of 2 streams to confluence: Flow rates before confluence point: 0.383 45.050 Maximum flow rates at confluence using above data: 40.508 45.370 Area of streams before confluence: 0.100 10.160 Results of confluence: Total flow rate = 45.370(CFS) Time of concentration = 5.033 mm. Effective stream area after confluence = 10.260(Ac.) Process from Point/Station 101.000 to Point/Station 102.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 181.130 (Ft.) Downstream point/station elevation = 180.300 (Ft.) Pipe length = 165.34(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 45.370(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 45.370(CFS) Normal flow depth in pipe = 28.31(In.) Flow top width inside pipe = 29.51(In.) Critical Depth = 26.32 (In.) Pipe flow velocity = 7.61(Ft/s) Travel time through pipe = 0.36 mm. Time of concentration (TC) 5.40 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 102.000 to Point/Station 102.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 10.260(Ac.) Runoff from this stream = 45.370(CFS) Time of concentration = 5.40 mm. Rainfall intensity = 6.522(In/Hr) ++++ + ++++ ++++ + ++++ + +++++++ + ++++++ + ++++ +++++++ ++++++ + Process from Point/Station 3.000 to Point/Station 4.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 204.000(Ft.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 3 of 21 Highest elevation = 196.000(Ft.) Lowest elevation = 190.100(Ft.) Elevation difference = 5.900(Ft.) Slope = 2.892 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 2.89 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.63 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 90.000.5)/( 2.892'(1/3)1= 5.63 The initial area total distance of 204.00 (Ft.) entered leaves a remaining distance of 114.00 (Ft.) Using Figure 3-4, the travel time for this distance is 1.17 minutes for a distance of 114.00 (Ft.) and a slope of 2.89 % with an elevation difference of 3.30(Ft.) from the end of the top area Tt = [11.9*length(Mi)"3)/(elevation change(Ft.))]".385 *60(min/hr) = 1.172 Minutes Tt=[(11.9*0.02163)/( 3.30)]A.385= 1.17 Total initial area Ti = 5.63 minutes from Figure 3-3 formula plus 1.17 minutes from the Figure 3-4 formula = 6.81 minutes Rainfall intensity (I) = 5.615(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.520(CFS) Total initial stream area = 0.147(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 4.000 to Point/Station 102.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 190.100 (Ft.) Downstream point/station elevation = 180.300(Ft.) Pipe length = 6.70(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.520(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.520(CFS) Normal flow depth in pipe = 0.92 (In.) Flow top width inside pipe = 6.40(In.) Critical Depth = 3.59(In.) Pipe flow velocity = 18.64(Ft/s) Travel time through pipe = 0.01 mm. Time of concentration (TC) = 6.81 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 102.000 to Point/Station 102.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.147(Ac.) Runoff from this stream = 0.520(CFS) Time of concentration = 6.81 mm. Rainfall intensity = 5.612(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 45.370 5.40 6.522 2 0.520 6.81 5.612 Qmax(l) = 1.000 * 1.000 * 45.370) + 1.000 * 0.792 * 0.520) + = 45.782 Qmax(2) = 0.860 * 1.000 * 45.370) + 1.000 * 1.000 * 0.520) + = 39.558 Total of 2 streams to confluence: Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 4 of 21 Flow rates before confluence point: 45.370 0.520 Maximum flow rates at confluence using above data: 45.782 39.558 Area of streams before confluence: 10.260 0.147 Results of confluence: Total flow rate = 45.782(CFS) Time of concentration = 5.395 mm. Effective stream area after confluence = 10.407(Ac.) +++..+++++ + ++++ + + +++++++ + ++++++ ++++++++ +++++++++++++ +++++++ + Process from Point/Station 102.000 to Point/Station 103.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 180.300 (Ft.) Downstream point/station elevation = 179.860 (Ft.) Pipe length = 88.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 45.782(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 45.782(CFS) Normal flow depth in pipe = 28.59(In.) Flow top width inside pipe = 29.10(m.) Critical Depth = 26.47(In.) Pipe flow velocity = 7.60(Ft/s) Travel time through pipe = 0.19 mm. Time of concentration (TC) = 5.59 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 103.000 to Point/Station 103.000 CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 1 Stream flow area = 10.407 (Ac.) Runoff from this stream = 45.782(CFS) Time of concentration = 5.59 mm. Rainfall intensity = 6.376(In/Hr) Program is now starting with Main Stream No. 2 Process from Point/Station 11.000 to Point/Station 12.000 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 327.000(Ft.) Highest elevation = 198.200(Ft.) Lowest elevation = 189.400(Ft.) Elevation difference = 8.800(Ft.) Slope = 2.691 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 2.69 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.77 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope'(1/3)] TC = [1.8*(1.1_0.6300)*( 90.000.5)/( 2.691(1/3)]= 5.77 The initial area total distance of 327.00 (Ft.) entered leaves a remaining distance of 237.00 (Ft.) Using Figure 3-4, the travel time for this distance is 2.12 minutes for a distance of 237.00 (Ft.) and a slope of 2.69 % Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 5 of 21 with an elevation difference of 6.38(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 2.117 Minutes Tt=[(11.9*0.0449"3)/( 6.38)].385= 2.12 Total initial area Ti = 5.77 minutes from Figure 3-3 formula plus 2.12 minutes from the Figure 3-4 formula = 7.89 minutes Rainfall intensity (I) = 5.106(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.708(CFS) Total initial stream area = 0.220(Ac.) +++ + ++++++ + + +++++++++++++ + + +++++++ +++++++++++++ + +++++ + Process from Point/Station 12.000 to Point/Station 103.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.400 (Ft.) Downstream point/station elevation = 184.900(Ft.) Pipe length = 47.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.708(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.708(CFS) Normal flow depth in pipe = 3.57(In.) Flow top width inside pipe = 10.97 (In.) Critical Depth = 4.21(In.) Pipe flow velocity = 3.61(Ft/s) Travel time through pipe = 0.22 mm. Time of concentration (TC) = 8.10 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 103.000 to Point/Station 103.000 **** CONFLUENCE OF MAIN STREAMS The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 0.220(Ac.) Runoff from this stream = 0.708(CFS) Time of concentration = 8.10 mm. Rainfall intensity = 5.017(In/Hr) Program is now starting with Main Stream No. 3 +++++++++++++++++ ++++++ + +++++++++++++ ++ ++ + +++++++ ++++++++++++ ++++++++ + Process from Point/Station 20.000 to Point/Station 21.000 '''' 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 60.000(Ft.) Highest elevation = 200.000(Ft.) Lowest elevation = 196.000(Ft.) Elevation difference = 4.000(Ft.) Slope = 6.667 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 6.67 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 4.49 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)) TC = [1.8*(1.1_0.6300)*( 100.000.5)/( 6.667(1/3)J= 4.49 Rainfall intensity (I) = 7.337(In/Hr) for a 100.0 year storm Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 6 of 21 Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.092(CFS) Total initial stream area = 0.020 (Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 21.000 to Point/Station 22.000 IRREGULAR CHANNEL FLOW TRAVEL TIME **** Estimated mean flow rate at midpoint of channel = 1.228(CFS) Depth of flow 0.146(Ft.), Average velocity = 1.771(Ft/s) ******* Irregular Channel Data *********** ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.50 2 0.00 0.00 3 13.00 0.20 Manning's 'N' friction factor = 0.015 ----------------------------------------------------------------- Sub-Channel flow = 1.228(CFS) flow top width = 9.495 (Ft.) velocity= 1.771(Ft/s) area = 0.693(Sq.Ft) Froude number = 1.155 Upstream point elevation = 196.000 (Ft.) Downstream point elevation = 190.870(Ft.) Flow length = 480.000(Ft.) Travel time = 4.52 mm. Time of concentration = 9.01 mm. Depth of flow = 0.146(Ft.) Average velocity = 1.771(Ft/s) Total irregular channel flow = 1.228(CFS) Irregular channel normal depth above invert elev. 0.146(Ft.) Average velocity of channel(s) = 1.771(Ft/s) 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Rainfall intensity = 4.685(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.484 Subarea runoff = 2.174(CFS) for 0.748(Ac.) Total runoff = 2.267(CFS) Total area = 0.768(Ac.) Depth of flow = 0.184(Ft.), Average velocity = 2.064(Ft/s) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 22.000 to Point/Station 23.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.000 (Ft.) Downstream point/station elevation 185.600(Ft.) Pipe length = 39.10(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 2.267(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 2.267(CFS) Normal flow depth in pipe = 6.90 (In.) Flow top width inside pipe 11.86(In.) Critical Depth = 7.73(In.) Pipe flow velocity = 4.85(Ft/s) Travel time through pipe = 0.13 mm. Time of concentration (TC) = 9.15 mm. Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 7 of 21 Process from Point/Station 23.000 to Point/Station 23.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 3 in normal stream number 1 Stream flow area = 0.768(Ac.) Runoff from this stream = 2.267(CFS) Time of concentration = 9.15 mm. Rainfall intensity = 4.640(In/Hr) Process from Point/Station 11.000 to Point/Station 30.000 **** 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 80.000(Ft.) Highest elevation = 198.200(Ft.) Lowest elevation = 195.000(Ft.) Elevation difference = 3.200(Ft.) Slope = 4.000 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 4.00 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.33 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 100.000.5)/( 4.000(1/3)1= 5.33 Rainfall intensity (I) = 6.574(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.112(CFS) Total initial stream area = 0.027(Ac.) ++..+++++++++++++.+++++++++++++++++++++++++++++++++.+++.++++++++++++++ Process from Point/Station 30.000 to Point/Station 23.000 '''' IRREGULAR CHANNEL FLOW TRAVEL TIME **** Estimated mean flow rate at midpoint of channel = 0.509(CFS) Depth of flow = 0.092(Ft.), Average velocity = 1.234(Ft/s) ******* Irregular Channel Data ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.50 2 0.00 0.00 3 29.50 0.30 Manning's 'N' friction factor = 0.015 ----------------------------------------------------------- Sub-Channel flow = 0.509(CFS) flow top width = 9.007(Ft.) velocity= 1.234(Ft/s) area = 0.413(Sq.Ft) Froude number = 1.016 Upstream point elevation = 195.000 (Ft.) Downstream point elevation = 190.530 (Ft.) Flow length = 466.000(Ft.) Travel time = 6.30 mm. Time of concentration = 11.63 mm. Depth of flow = 0.092(Ft.) Average velocity = 1.234(Ft/s) Total irregular channel flow = 0.509(CFS) Irregular channel normal depth above invert elev. = 0.092(Ft.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 8 of 21 Average velocity of channel(s) = 1.234(Ft/s) 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Rainfall intensity = 3.975(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.209 Subarea runoff = 0.717(CFS) for 0.304(Ac.) Total runoff = 0.829(CFS) Total area = 0.331(Ac.) Depth of flow = 0.110(Ft.), Average velocity = 1.394(Ft/s) Process from Point/Station 23.000 to Point/Station 23.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 3 in normal stream number 2 Stream flow area = 0.331(Ac.) Runoff from this stream = 0.829(CFS) Time of concentration = 11.63 mm. Rainfall intensity = 3.975(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 2.267 9.15 4.640 2 0.829 11.63 3.975 Qmax(1) = 1.000 * 1.000 * 2.267) + 1.000 * 0.787 * 0.829) + = 2.919 Qmax(2) = 0.857 * 1.000 * 2.267) + 1.000 * 1.000 * 0.829) + = 2.771 Total of 2 streams to confluence: Flow rates before confluence point: 2.267 0.829 Maximum flow rates at confluence using above data: 2.919 2.771 Area of streams before confluence: 0.768 0.331 Results of confluence: Total flow rate = 2.919(CFS) Time of concentration = 9.146 mm. Effective stream area after confluence = 1.099 (Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 23.000 to Point/Station 31.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.600(Ft.) Downstream point/station elevation = 182.730(Ft.) Pipe length = 110.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 2.919(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 2.919(CFS) Normal flow depth in pipe = 6.05(In.) Flow top width inside pipe = 12.00(In.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 9 of 21 Critical Depth = 8.78(In.) Pipe flow velocity = 7.35(Ft/s) Travel time through pipe = 0.25 mm. Time of concentration (TC) = 9.40 mm. +++++++.++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 31.000 to Point/Station 31.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.730(Ft.) Downstream point/station elevation = 181.550 (Ft.) Pipe length = 236.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 2.919(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 2.919(CFS) Normal flow depth in pipe = 6.94(In.) Flow top width inside pipe = 21.77 (In.) Critical Depth = 7.14 (In.) Pipe flow velocity = 3.87(Ft/s) Travel time through pipe = 1.02 mm. Time of concentration (TC) = 10.41 mm. +++++++++...++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 32.000 to Point/Station 32.000 **** 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Time of concentration = 10.41 mm. Rainfall intensity = 4.268(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C 0.630 CA = 3.028 Subarea runoff = 10.005(CFS) for 3.707(Ac.) Total runoff = 12.924(CFS) Total area = 4.806(Ac.) Process from Point/Station 32.000 to Point/Station 33.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 181.550 (Ft.) Downstream point/station elevation = 181.110(Ft.) Pipe length = 88.50(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 12.924(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 12.924(CFS) Normal flow depth in pipe = 16.38(In.) Flow top width inside pipe = 22.34 (In.) Critical Depth = 15.51(In.) Pipe flow velocity = 5.65(Ft/s) Travel time through pipe = 0.26 mm. Time of concentration (TC) = 10.67 mm. Process from Point/Station 33.000 to Point/Station 33.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 3 in normal stream number 1 Stream flow area = 4.806 (Ac.) Runoff from this stream = 12.924(CFS) Time of concentration = 10.67 mm. Rainfall intensity = 4.201(In/Hr) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 10of21 Process from Point/Station 7.000 to Point/Station 15.000 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 128.000(Ft.) Highest elevation = 190.600(Ft.) Lowest elevation = 189.550(Ft.) Elevation difference = 1.050(Ft.) Slope = 0.820 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.82 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.29 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 65.000.5)/( 0.820(1/3)J= 7.29 The initial area total distance of 128.00 (Ft.) entered leaves a remaining distance of 63.00 (Ft.) Using Figure 3-4, the travel time for this distance is 1.21 minutes for a distance of 63.00 (Ft.) and a slope of 0.82 % with an elevation difference of 0.52(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 1.206 Minutes Tt=[ (l1.9*0.01193)/( 0.52)]A.385= 1.21 Total initial area Ti = 7.29 minutes from Figure 3-3 formula plus 1.21 minutes from the Figure 3-4 formula = 8.49 minutes Rainfall intensity (I) = 4.867(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.411(CFS) Total initial stream area = 0.134 (Ac.) Process from Point/Station 15.000 to Point/Station 33.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.550(Ft.) Downstream point/Station elevation = 185.020(Ft.) Pipe length = 53.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.411(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.411(CFS) Normal flow depth in pipe = 2.75(In.) Flow top width inside pipe = 10.09(In.) Critical Depth = 3.18(In.) Pipe flow velocity = 3.02(Ft/s) Travel time through pipe = 0.29 mm. Time of concentration (TC) = 8.78 mm. Process from Point/Station 33.000 to Point/Station 33.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 3 in normal stream number 2 Stream flow area = 0.134 (Ac.) Runoff from this stream = 0.411(CFS) Time of concentration = 8.78 mm. Rainfall intensity = 4.762(In/Hr) Summary of stream data: Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 11 of 21 Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 12.924 10.67 4.201 2 0.411 8.78 4.762 Qmax(l) = 1.000 * 1.000 * 12.924) + 0.882 * 1.000 * 0.411) + = 13.286 Qmax(2) = 1.000 * 0.823 * 12.924) + 1.000 * 1.000 * 0.411) + = 11.050 Total of 2 streams to confluence: Flow rates before confluence point: 12.924 0.411 Maximum flow rates at confluence using above data: 13.286 11.050 Area of streams before confluence: 4.806 0.134 Results of confluence: Total flow rate = 13.286(CFS) Time of concentration = 10.672 mm. Effective stream area after confluence = 4.940(Ac.) Process from Point/Station 33.000 to Point/Station 35.000 PIPEFLOW TRAVEL TIME (User specified size) '' Upstream point/station elevation = 181.110(Ft.) Downstream point/station elevation = 180.300(Ft.) Pipe length = 162.20(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 13.286(CFS) Given pipe size = 30.00(m.) Calculated individual pipe flow = 13.286(CFS) Normal flow depth in pipe = 14.26(In.) Flow top width inside pipe = 29.96(In.) Critical Depth = 14.70(m.) Pipe flow velocity = 5.78 (Ft/s) Travel time through pipe = 0.47 mm. Time of concentration (TC) = 11.14 mm. Process from Point/Station 35.000 to Point/Station 35.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 3 in normal stream number 1 Stream flow area = 4.940(Ac.) Runoff from this stream = 13.286(CFS) Time of concentration = 11.14 mm. Rainfall intensity = 4.086(In/Hr) Process from Point/Station 34.000 to Point/Station 13.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 119.000(Ft.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 12 of 21 Highest elevation = 190.640(Ft.) Lowest elevation = 189.200(Ft.) Elevation difference = 1.440(Ft.) Slope = 1.210 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 1.21 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 6.40 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 65.000^.5)/( 1.210(1/3)1= 6.40 The initial area total distance of 119.00 (Ft.) entered leaves a remaining distance of 54.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.92 minutes for a distance of 54.00 (Ft.) and a slope of 1.21 % with an elevation difference of 0.65(Ft.) from the end of the top area Tt = (l1.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 0.922 Minutes Tt=( (ll.9*0.01023)/( 0.65)1 ^.385= 0.92 Total initial area Ti = 6.40 minutes from Figure 3-3 formula plus 0.92 minutes from the Figure 3-4 formula = 7.32 minutes Rainfall intensity (I) = 5.356(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.337(CFS) Total initial stream area = 0.100(Ac.) Process from Point/Station 13.000 to Point/Station 35.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.200 (Ft.) Downstream point/station elevation = 180.300 (Ft.) Pipe length = 48.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.337(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.337(CFS) Normal flow depth in pipe = 1.42 (In.) Flow top width inside pipe = 7.74 (In.) Critical Depth = 2.87(In.) Pipe flow velocity = 6.46(Ft/s) Travel time through pipe = 0.12 mm. Time of concentration (TC) = 7.45 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 35.000 to Point/Station 35.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 3 in normal stream number 2 Stream flow area = 0.100(Ac.) Runoff from this stream 0.337(CFS) Time of concentration = 7.45 mm. Rainfall intensity = 5.298(In/Hr) Process from Point/Station 5.000 to Point/Station 6.000 '''' 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 221.000(Ft.) Highest elevation 191.000(Ft.) Lowest elevation = 189.200(Ft.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE H Page 13 of 21 Elevation difference = 1.800(Ft.) Slope = 0.814 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.81 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.30 minutes TC = (]..8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)) TC = [1.8*(1.1_0.6300)*( 65.000".5)/( 0.814(1/3)]= 7.30 The initial area total distance of 221.00 (Ft.) entered leaves a remaining distance of 156.00 (Ft.) Using Figure 3-4, the travel time for this distance is 2.43 minutes for a distance of 156.00 (Ft.) and a slope of 0.81 % with an elevation difference of 1.27(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 2.431 Minutes Tt=[ (11.9*0.02953)/( 1.27)]A.385= 2.43 Total initial area Ti = 7.30 minutes from Figure 3-3 formula plus 2.43 minutes from the Figure 3-4 formula = 9.74 minutes Rainfall intensity (I) = 4.457(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.702(CFS) Total initial stream area = 0.250(Ac.) Process from Point/Station 6.000 to Point/Station 35.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.200 (Ft.) Downstream point/station elevation = 180.300(Ft.) Pipe length = 5.60(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.702(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.702(CFS) Normal flow depth in pipe = 1.21(In.) Flow top width inside pipe = 7.22 (In.) Critical Depth = 4.19(In.) Pipe flow velocity = 17.07(Ft/s) Travel time through pipe = 0.01 mm. Time of concentration (TC) = 9.74 mm. ++++H-+ +++++++ +++ + +++++++ + +++++++ ++ + + +++++++++++++ + + + Process from Point/Station 35.000 to Point/Station 35.000 **** CONFLUENCE OF MINOR STREAMS '''' Along Main Stream number: 3 in normal stream number 3 Stream flow area = 0.250(Ac.) Runoff from this stream 0.702(CFS) Time of concentration = 9.74 mm. Rainfall intensity = 4.455(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 13.286 11.14 4.086 2 0.337 7.45 5.298 3 0.702 9.74 4.455 Qmax(l) = 1.000 * 1.000 * 13.286) + 0.771 * 1.000 * 0.337) + 0.917 * 1.000 * 0.702) + = 14.190 Qmax(2) = 1.000 * 0.668 * 13.286) + 1.000 * 1.000 * 0.337) + 1.000 * 0.764 * 0.702) + = 9.756 Qmax(3) 1.000 * 0.874 * 13.286) + Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 14 of 21 0.841 * 1.000 * 0.337) + 1.000 * 1.000 * 0.702) + = 12.604 Total of 3 streams to confluence: Flow rates before confluence point: 13.286 0.337 0.702 Maximum flow rates at confluence using above data: 14.190 9.756 12.604 Area of streams before confluence: 4.940 0.100 0.250 Results of confluence: Total flow rate = 14.190(CFS) Time of concentration = 11.140 mm. Effective stream area after confluence = 5.290(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 35.000 to Point/Station 103.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 180.300 (Ft.) Downstream point/station elevation = 179.860 (Ft.) Pipe length = 88.50 (Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 14.190(CFS) Given pipe size = 30.00(In.) Calculated individual pipe flow = 14.190(CFS) Normal flow depth in pipe = 14.84 (In.) Flow top width inside pipe 30.00 (In.) Critical Depth = 15.21 (In.) Pipe flow velocity = 5.86(Ft/s) Travel time through pipe = 0.25 mm. Time of concentration (TC) = 11.39 mm. Process from Point/Station 103.000 to Point/Station 103.000 CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 3 Stream flow area = 5.290(Ac.) Runoff from this stream = 14.190(CFS) Time of concentration = 11.39 mm. Rainfall intensity = 4.028(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 45.782 5.59 6.376 2 0.708 8.10 5.017 3 14.190 11.39 4.028 Qmax(1) = 1.000 * 1.000 * 45.782) + 1.000 * 0.690 * 0.708) + 1.000 * 0.491 * 14.190) + = 53.231 Qmax(2) 0.787 * 1.000 * 45.782) + 1.000 * 1.000 * 0.708) + 1.000 * 0.711 * 14.190) + = 46.826 Qmax(3) = 0.632 * 1.000 * 45.782) + 0.803 * 1.000 * 0.708) + 1.000 * 1.000 * 14.190) + = 43.678 Total of 3 main streams to confluence: Flow rates before confluence point: 45.782 0.708 14.190 Maximum flow rates at confluence using above data: 53.231 46.826 43.678 Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 15 of 21 Area of streams before confluence: 10.407 0.220 5.290 Results of confluence: Total flow rate = 53.231(CFS) Time of concentration = 5.588 mm. Effective stream area after confluence = 15.917 (Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 103.000 to Point/Station 104.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 179.860 (Ft.) Downstream point/station elevation = 179.460(Ft.) Pipe length = 80.20(Ft.) Mannings N = 0.013 No. of pipes = 1 Required pipe flow = 53.231(CFS) Given pipe size = 48.00(In.) Calculated individual pipe flow = 53.231(CFS) Normal flow depth in pipe = 24.70(In.) Flow top width inside pipe = 47.98(In.) Critical Depth = 26.29(In.) Pipe flow velocity = 8.17 (Ft/s) Travel time through pipe = 0.16 mm. Time of concentration (TC) = 5.75 mm. ++++++++++.+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 104.000 to Point/Station 104.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number Stream flow area = 15.917(Ac.) Runoff from this stream = 53.231(CFS) Time of concentration = 5.75 mm. Rainfall intensity = 6.259(In/Hr) ++++++++++++++.+++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 36.000 to Point/Station 37.000 **** 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 120.000(Ft.) Highest elevation = 194.000(Ft.) Lowest elevation = 192.800(Ft.) Elevation difference = 1.200(Ft.) Slope = 1.000 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 1.00 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 6.82 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 65.000.5)/( 1.000'(1/3)]= 6.82 The initial area total distance of 120.00 (Ft.) entered leaves a remaining distance of 55.00 (Ft.) Using Figure 3-4, the travel time for this distance is 1.01 minutes for a distance of 55.00 (Ft.) and a slope of 1.00 % with an elevation difference of 0.55(Ft.) from the end of the top area Tt = [11.9*length(Mi)"3)/(elevation change(Ft.))1".385 *60(min/hr) = 1.006 Minutes Tt=[ (11.9*0.0l043)/( 0.55) ].385= 1.01 Outfall A TAKEN FROM HYDROLOGY STUDY PHASE H Page 16of21 Total initial area Ti = 6.82 minutes from Figure 3-3 formula plus 1.01 minutes from the Figure 3-4 formula = 7.83 minutes Rainfall intensity (I) = 5.131(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.420(CFS) Total initial stream area = 0.130(Ac.) Process from Point/Station 37.000 to Point/Station 38.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 192.800(Ft.) Downstream point/station elevation = 187.400 (Ft.) Pipe length = 158.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.420(CFS) Given pipe size = 8.00(In.) Calculated individual pipe flow = 0.420(CFS) Normal flow depth in pipe = 2.35(In.) Flow top width inside pipe = 7.29(In.) Critical Depth = 3.63(In.) Pipe flow velocity = 4.91(Ft/s) Travel time through pipe = 0.54 mm. Time of concentration (TC) = 8.36 mm. Process from Point/Station 37.000 to Point/Station 38.000 SUBAREA FLOW ADDITION **** User specified ICI value of 0.630 given for subarea Time of concentration = 8.36 mm. Rainfall intensity = 4.916(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.208 Subarea runoff = 0.602(CFS) for 0.200(Ac.) Total runoff = 1.022(CFS) Total area = 0.330(Ac.) ++++++++++.++++++++++.++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 38.000 to Point/Station 104.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 187.400(Ft.) Downstream point/station elevation = 104.000(Ft.) Pipe length = 192.50(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.022(CFS) Given pipe size = 8.00(In.) Calculated individual pipe flow = 1.022(CFS) Normal flow depth in pipe = 1.94 (In.) Flow top width inside pipe = 6.85(In.) Critical Depth = 5.76(In.) Pipe flow velocity = 15.67(Ft/s) Travel time through pipe = 0.20 mm. Time of concentration (TC) = 8.57 mm. Process from Point/Station 38.000 to Point/Station 104.000 SUBAREA FLOW ADDITION '''' User specified 'C' value of 0.630 given for subarea Time of concentration = 8.57 mm. Rainfall intensity = 4.840(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C =.0.630 CA = 0.476 Subarea runoff = 1.280(CFS) for 0.425(Ac.) Total runoff = 2.302(CFS) Total area = 0.755(Ac.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 17 of 21 Process from Point/Station 104.000 to Point/Station 104.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.755 (Ac.) Runoff from this stream = 2.302(CFS) Time of concentration = 8.57 mm. Rainfall intensity = 4.840(In/Hr) ++ + ++++++++ + +++++++++ + + +++++++++++ + + + +++++++++++++++++++ +++++++ + Process from Point/Station 39.000 to Point/Station 40.000 **** 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 95.000(Ft.) Highest elevation 190.000(Ft.) Lowest elevation = 189.000(Ft.) Elevation difference = 1.000(Ft.) Slope = 1.053 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 1.05 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration 6.70 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 65.000.5)/( 1.053(1/3)1= 6.70 The initial area total distance of 95.00 (Ft.) entered leaves a remaining distance of 30.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.62 minutes for a distance of 30.00 (Ft.) and a slope of 1.05 % with an elevation difference of 0.32(Ft.) from the end of the top area Tt = [l1.9*length(Mi)3)/(elevation change(Ft.))].385 *60(min/hr) = 0.619 Minutes Tt=[ (11.9*0.00573)/( 0.32)1-.385= 0.62 Total initial area Ti = 6.70 minutes from Figure 3-3 formula plus 0.62 minutes from the Figure 3-4 formula = 7.32 minutes Rainfall intensity (I) = 5.356(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.648(CFS) Total initial stream area = 0.192(Ac.) Process from Point/Station 40.000 to Point/Station 41.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.050 (Ft.) Downstream point/station elevation = 184.970(Ft.) Pipe length = 108.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.648(CFS) Given pipe size = 8.00(In.) Calculated individual pipe flow = 0.648(CFS) Normal flow depth in pipe = 4.17 (In.) Flow top width inside pipe 7.99(In.) Critical Depth = 4.55(In.) Pipe flow velocity = 3.52(Ft/s) Travel time through pipe = 0.51 mm. Time of concentration (TC) = 7.83 mm. + +++++++++ + + ++++++++ + + ++++++++++++++-I-+++++++++ + + ++++++.+ ++++++.+ + +++ + + Process from Point/Station 40.000 to Point/Station 41.000 Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 18 of 21 SUBAREA FLOW ADDITION **** User specified 'C' value of 0.630 given for subarea Time of concentration = 7.83 mm. Rainfall intensity = 5.128(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.231 Subarea runoff = 0.535(CFS) for 0.174(Ac.) Total runoff = 1.182(CFS) Total area = 0.366(Ac.) ++++++++++...+ + ++++++ + + + ++++++ + +++++++ +++++ ++++++++++ ++++++++ + Process from Point/Station 41.000 to Point/Station 104.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 184.970(Ft.) Downstream point/station elevation = 183.040(Ft.) Pipe length = 195.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.182(CFS) Given pipe size = 8.00(In.) Calculated individual pipe flow = 1.182(CFS) Normal flow depth in pipe = 6.44 (In.) Flow top width inside pipe = 6.34(In.) Critical Depth = 6.18(In.) Pipe flow velocity = 3.93(Ft/s) Travel time through pipe = 0.83 mm. Time of concentration (TC) = 8.66 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 41.000 to Point/Station 104.000 SUBAREA FLOW ADDITION **** User specified 'C' value of 0.630 given for subarea Time of concentration = 8.66 mm. Rainfall intensity = 4.806(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.451 Subarea runoff = 0.986(CFS) for 0.350(Ac.) Total runoff = 2.168(CFS) Total area = 0.716(Ac.) ++++++ +++++++ ++++++++++ + +++++ +++++++++++ + ++++ ++++++++++ ++++++++ ++++++ + Process from Point/Station 104.000 to Point/Station 104.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 3 Stream flow area = 0.716(Ac.) Runoff from this stream = 2.168(CFS) Time of concentration = 8.66 mm. Rainfall intensity = 4.806(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 53.231 5.75 6.259 2 2.302 8.57 4.840 3 2.168 8.66 4.806 Qmax(l) = 1.000 * 1.000 * 53.231) + 1.000 * 0.671 * 2.302) + 1.000 * 0.664 * 2.168) + = 56.216 Qmax(2) = 0.773 * 1.000 * 53.231) + 1.000 * 1.000 * 2.302) + 1.000 * 0.989 * 2.168) + = 45.611 Qmax(3) = 0.768 * 1.000 * 53.231) + Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 19 of 21 0.993 * 1.000 * 2.302) + 1.000 * 1.000 * 2.168) + = 45.331 Total of 3 streams to confluence: Flow rates before confluence point: 53.231 2.302 2.168 Maximum flow rates at confluence using above data: 56.216 45.611 45.331 Area of streams before confluence: 15.917 0.755 0.716 Results of confluence: Total flow rate = 56.216(CFS) Time of concentration = 5.752 mm. Effective stream area after confluence = 17.388(Ac.) +++++++++ ++++++++++++ +++++++++++++ + +++++++++ +++++++++ + +++++++++ + +++++ + Process from Point/Station 104.000 to Point/Station 105.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 179.430(Ft.) Downstream point/station elevation = 179.240(Ft.) Pipe length = 37.40(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 56.216(CFS) Given pipe size = 48.00(In.) Calculated individual pipe flow = 56.216(CFS) Normal flow depth in pipe = 25.38 (In.) Flow top width inside pipe = 47.92 (In.) Critical Depth = 27.04(In.) Pipe flow velocity = 8.34(Ft/s) Travel time through pipe = 0.07 mm. Time of concentration (TC) = 5.83 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 105.000 to Point/Station 106.000 IRREGULAR CHANNEL FLOW TRAVEL TIME Depth of flow = 1.215(Ft.), Average velocity = 3.036(Ft/s) Irregular Channel Data ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 1.64 2 6.00 0.00 3 11.00 0.00 4 24.98 1.04 5 44.34 10.26 Manning's 'N' friction factor 0.035 ----------------------------------------------------------------- Sub-Channel flow = 56.217(CFS) flow top width = 23.790 (Ft.) velocity= 3.036(Ft/s) area = 18.514(Sq.Ft) Froude number = 0.607 Upstream point elevation = 179.240(Ft.) Downstream point elevation = 175.700(Ft.) Flow length = 488.800(Ft.) Travel time = 2.68 mm. Time of concentration = 8.51 mm. Depth of flow = 1.215(Ft.) Average velocity = 3.036(Ft/s) Total irregular channel flow = 56.216(CFS) Irregular channel normal depth above invert elev. 1.215(Ft.) Average velocity of channel(s) = 3.036(Ft/s) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 105.000 to Point/Station 106.000 SUBAREA FLOW ADDITION **** Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 20 of 21 User specified 'C' value of 0.630 given for subarea The area added to the existing stream causes a a lower flow rate of Q = 53.897(CFS) therefore the upstream flow rate of Q = 56.216(CFS) is being used Time of concentration = 8.51 mm. Rainfall intensity = 4.861(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 11.087 Subarea runoff = 0.000(CFS) for 0.210(Ac.) Total runoff = 56.216(CFS) Total area = 17.598(Ac.) End of computations, total study area = 17.598 (Ac.) Outfall A TAKEN FROM HYDROLOGY STUDY PHASE II Page 21 of 21 San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software, (c)1991-2012 Version 7.9 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 10/29/15 CT 03-02, CARLSBAD RANCH, PLANNING AREA NO. 5 - RESORT SITE PHASE 1 100 YEAR STORM POST-DEVELOPMENT NODES 100 TO 110 ------------------------------------------------------------------------ ********* Hydrology Study Control Information ********** ------------------------------------------------------------------------ Program License Serial Number 6312 ------------------------------------------------------------------------ Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.500 P6/P24 = 57.8% San Diego hydrology manual 'C' values used + + + + + + + + + + . + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + ++ ++ + + + + + + + + + + + + + + + + + + + Process from Point/Station 100.000 to Point/Station 101.000 INITIAL AREA EVALUATION Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 539.000(Ft.) Highest elevation = 208.900(Ft.) Lowest elevation = 188.300(Ft.) Elevation difference = 20.600(Ft.) Slope = 3.822 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 85.00 (Ft) for the top area slope value of 3.82 %, in a development type of Neighborhod Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.50 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope'(1/3)J TC= [1.8*(1.1_0.7700)*( 85.00V.5)/( 3.822(1/3)1= 3.50 The initial area total distance of 539.00 (Ft.) entered leaves a remaining distance of 454.00 (Ft.) Using Figure 3-4, the travel time for this distance is 3.05 minutes for a distance of 454.00 (Ft.) and a slope of 3.82 % with an elevation difference of 17.35(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))].385 *60(min/hr) = 3.050 Minutes Tt=[ (11.9*0.08603)/( 17.35)]".385= 3.05 Total initial area Ti = 3.50 minutes from Figure 3-3 formula plus 3.05 minutes from the Figure 3-4 formula = 6.55 minutes Rainfall intensity (I) = 5.754(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Subarea runoff = 2.570(CFS) Total initial stream area = 0.580(Ac.) ++++++++++.+++++++++++++++.+.++++++++++++++++++++++++++.....++++++++++ Process from Point/Station 101.000 to Point/Station 102.000 PIPEFLOW TRAVEL TIME (User specified size) **** 100 YR PRE-DEVELOPMENT CAIC (NODES 100 THROUGH 110) TAKEN FROM HYDROLOGY STUDY PHASE I Page 1 of 6 Upstream point/station elevation = 184.300(Ft.) Downstream point/station elevation = 163.540(Ft.) Pipe length = 77.37(Ft.) Slope = 0.2683 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 2.570(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 2.570(CFS) Normal flow depth in pipe = 2.66(In.) Flow top width inside pipe = 12.78(In.) Critical Depth = 7.28(In.) Pipe flow velocity = 15.77(Ft/s) Travel time through pipe = 0.08 mm. Time of concentration (TC) = 6.63 mm. ++ + + + + + + + + + + ++++++++++++++++++++++++++++++++++++++++++ + + ++++++++ Process from Point/Station 104.000 to Point/Station 102.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.708(In/Hr) for a 100.0 year storm Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Time of concentration 6.63 mm. Rainfall intensity = 5.708(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.770 CA = 1.01 Subarea runoff = 3.232(CFS) for 0. 740 (Ac Total runoff = 5.801(CFS) Total area = 1.320(Ac.) +++++++++++++ ++++++ +++++++++++++++++ ++ + + +++++++++ +++++++ + + +++++ Process from Point/Station 102.000 to Point/Station 102.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 1 Stream flow area = 1.320(Ac.) Runoff from this stream = 5.801(CFS) Time of concentration 6.63 mm. Rainfall intensity = 5.708(In/Hr) Program is now starting with Main Stream No. 2 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 105.000 to Point/Station 106.000 **** INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 234.000(Ft.) Highest elevation = 192.000(Ft.) Lowest elevation = 184.000(Ft.) Elevation difference = 8.000(Ft.) Slope = 3.419 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 85.00 (Ft) for the top area slope value of 3.42 %, in a development type of Neighborhod Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.64 minutes 100 YR PRE.DEVELOPMENT CALC (NODES 100 THROUGH 110) TAKEN FROM HYDROLOGY STUDY PHASE I Page 2 of 6 TC = (1.8*(1.1_C)*distance(Ft.)".5)/(% slope(1/3)] TC= (1.8*(1.1_0.7700)*( 85.000.5)/( 3.419(1/3)]= 3.64 The initial area total distance of 234.00 (Ft.) entered leaves a remaining distance of 149.00 (Ft.) Using Figure 3-4, the travel time for this distance is 1.35 minutes for a distance of 149.00 (Ft.) and a slope of 3.42 % with an elevation difference of 5.09(Ft.) from the end of the top area Tt = [ll.9*length(Mi)3)/(elevation change(Ft.))]'.385 *60(min/hr) = 1.350 Minutes Tt=( (11.9*0.02823)/( 5.09)1^.385= 1.35 Total initial area Ti = 3.64 minutes from Figure 3-3 formula plus 1.35 minutes from the Figure 3-4 formula = 4.99 minutes Calculated TC of 4.985 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Subarea runoff = 1.582(CFS) Total initial stream area = 0.300(Ac.) + +++++ + + + + + ++++++++++ +++++++++ +++++++++++++ +++++++++ +++++++++++++++ +++ Process from Point/Station 106.000 to Point/Station 107.000 **** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION **** Top of street segment elevation = 184.000(Ft.) End of street segment elevation = 173.900(Ft.) Length of street segment = 165.000(Ft.) Height of curb above gutter flowline = 6.0(In.) Width of half street (curb to crown) = 30.000(Ft.) Distance from crown to crossfall grade break = 28.000(Ft.) Slope from gutter to grade break (v/hz) = 0.020 Slope from grade break to crown (v/hz) = 0.020 Street flow is on [1] side(s) of the street Distance from curb to property line = 10.000(Ft.) Slope from curb to property line (v/hz) = 0.020 Gutter width = 1.500(Ft.) Gutter hike from flowline = 1.500(In.) Manning's N in gutter = 0.0150 Manning's N from gutter to grade break = 0.0150 Manning's N from grade break to crown = 0.0150 Estimated mean flow rate at midpoint of street = 2.801(CFS) Depth of flow = 0.242(Ft.), Average velocity = 4.571(Ft/s) Streetflow hydraulics at midpoint of street travel: Halfstreet flow width = 7.358(Ft.) Flow velocity = 4.57(Ft/s) Travel time = 0.60 mm. TC = 5.59 •min. Adding area flow to street Rainfall intensity (I) = 6.377(In/Hr) for a 100.0 year storm Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (COMMERCIAL area type (General Commercial Impervious value, Ai = 0.850 Sub-Area C Value = 0.800 Rainfall intensity = 6.377(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.788 CA = 0.615 Subarea runoff = 2.339(CFS) for 0.480(Ac.) Total runoff = 3.922(CFS) Total area = 0.780(Ac.) Street flow at end of street = 3.922(CFS) Half street flow at end of street = 3.922(CFS) Depth of flow = 0.265(Ft.), Average velocity = 4.940(Ft/s) Flow width (from curb towards crown)= 8.500(Ft.) Process from Point/Station 107.000 to Point/Station 107.000 **** CONFLUENCE OF MINOR STREAMS **** 100 YR PRE-DEVELOPMENT CALC (NODES 100 THROUGH 110) TAKEN FROM HYDROLOGY STUDY PHASE I Page 3 of 6 Along Main Stream number: 2 in normal stream number Stream flow area = 0.780(Ac.) Runoff from this stream = 3.922(CFS) Time of concentration = 5.59 mm. Rainfall intensity = 6.377(In/Hr) ++++++++++++++++++++++++.+++++++++++++++++++++++++++++++++++++..++++++ Process from Point/Station 108.000 to Point/Station 109.000 *** INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 572.000(Ft.) Highest elevation = 200.000(Ft.) Lowest elevation = 179.500(Ft.) Elevation difference = 20.500(Ft.) Slope = 3.584 % Top of Initial Area Slope adjusted by User to 3.671 % Bottom of Initial Area Slope adjusted by User to 3.671 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 85.00 (Ft) for the top area slope value of 3.67 %, in a development type of Neighborhod Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.55 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% s1ope(1/3)] TC = L1.8*(1.1_0.7700)*( 85.000.5)/( 3.671'(1/3)1= 3.55 The initial area total distance of 572.00 (Ft.) entered leaves a remaining distance of 487.00 (Ft.) Using Figure 3-4, the travel time for this distance is 3.27 minutes for a distance of 487.00 (Ft.) and a slope of 3.67 % with an elevation difference of 17.88(Ft.) from the end of the top area Tt = L11.9*length(Mi)3)/(elevation change(Ft.))]'.385 *60(min/hr) = 3.270 Minutes Tt=[(11.9*0.09223)/( 17.88)].385= 3.27 Total initial area Ti = 3.55 minutes from Figure 3-3 formula plus 3.27 minutes from the Figure 3-4 formula = 6.82 minutes Rainfall intensity (I) = 5.607(In/Hr) for a 100.0 year Storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Subarea runoff = 5.354(CFS) Total initial stream area = 1.240(Ac.) + +++ + + + + + +++++++++++++++++ +++++++ +++++++++++++++++++ + ++++++ ++++++++ Process from Point/Station 109.000 to Point/Station 107.000 PIPEFLOW TRAVEL TIME (User Specified size) Upstream point/station elevation = 177.400(Ft.) Downstream point/Station elevation = 168.330(Ft.) Pipe length = 195.48(Ft.) Slope = 0.0464 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.354(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 5.354(CFS) Normal flow depth in pipe = 7.38(In.) Flow top width inside pipe = 11.68(In.) Critical Depth = 11.20(In.) Pipe flow velocity = 10.57(Ft/s) Travel time through pipe = 0.31 mm. Time of concentration (TC) = 7.13 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 107.000 to Point/Station 107.000 100 YR PRE-DEVELOPMENT CAtC (NODES 100 THROUGH 110) TAKEN FROM HYDROLOGY STUDY PHASE I Page 4 of 6 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 2 in normal stream number 2 Stream flow area = 1.240(Ac.) Runoff from this stream = 5.354(CFS) Time of concentration = 7.13 mm. Rainfall intensity = 5.450(In/Hr) Summary of stream data: Rainfall Intensity (In/Hr) 6.377 5.450 3.922) + 5.354) + = 8.118 0.855 * 1.000 * 3.922) + 1.000 * 1.000 * 5.354) + = 8.705 Total of 2 streams to confluence: Flow rates before confluence point: 3.922 5.354 Maximum flow rates at confluence using above data: 8.118 8.705 Area of streams before confluence: 0.780 1.240 Results of confluence: Total flow rate = 8.705(CFS) Time of concentration = 7.128 mm. Effective stream area after confluence = 2.020 (Ac.) ++++++++++++ ++++ +++++ + +++++++ + + ++++++++ +++++++++ +++++++++ +++++++ Process from Point/Station 107.000 to Point/Station 102.000 '' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 168.000(Ft.) Downstream point/Station elevation = 163.540 (Ft.) Pipe length = 94.72(Ft.) Slope = 0.0471 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 8.705(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 8.705(CFS) Normal flow depth in pipe = 7.71(In.) Flow top width inside pipe = 17.81(In.) Critical Depth = 13.71(In.) Pipe flow velocity = 12.03(Ft/s) Travel time through pipe = 0.13 mm. Time of concentration (TC) = 7.26 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 102.000 to Point/Station 102.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 2.020(Ac.) Runoff from this stream = 8.705(CFS) Time of concentration 7.26 mm. Rainfall intensity = 5.386(In/Hr) Summary of Stream data: Stream Flow rate TC No. (CFS) (mm) 1 5.801 6.63 Rainfall Intensity (In/Hr) 5.708 100 YR PRE-DEVELOPMENT CALC (NODES 100 THROUGH 110) TAKEN FROM HYDROLOGY STUDY PHASE I Page 5 of 6 Stream Flow rate TC No. (CFS) (mm) 1 3.922 5.59 2 5.354 7.13 Qmax(l) = 1.000 * 1.000 * 1.000 * 0.784 * Qmax(2) = 2 8.705 7.26 5.386 Qmax(1) = 1.000 * 1.000 * 5.801) + 1.000 * 0.914 * 8.705) + = 13.757 Qmax(2) = 0.944 * 1.000 * 5.801) + 1.000 * 1.000 * 8.705) + = 14.180 Total of 2 main streams to confluence: Flow rates before confluence point: 5.801 8.705 Maximum flow rates at confluence using above data: 13.757 14.180 Area of streams before confluence: 1.320 2.020 Results of confluence: Total flow rate = 14.180(CFS) Time of concentration = 7.260 mm. Effective stream area after confluence = 3.340 (Ac.) Process from Point/Station 102.000 to Point/Station 103.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 163.210 (Ft.) Downstream point/station elevation = 162.500(Ft.) Pipe length = 37.46(Ft.) Slope = 0.0190 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 14.180(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 14.180(CFS) Normal flow depth in pipe 14.44(In.) Flow top width inside pipe = 14.34(In.) Critical Depth = 16.64(In.) Pipe flow velocity = 9.33(Ft/s) Travel time through pipe = 0.07 mm. Time of concentration (TC) = 7.33 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 110.000 to Point/Station 103.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.354(In/Hr) for a 100.0 year storm Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Time of concentration = 7.33 mm. Rainfall intensity = 5.354(In/Mr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.773 CA = 3.372 Subarea runoff = 3.872(CFS) for 1.020(Ac.) Total runoff = 18.052(CFS) Total area = 4.360(Ac.) End of computations, total study area = 4.360 (Ac.) 100 YR PRE-DEVELOPMENT CALC (NODES 100 THROUGH 110) TAKEN FROM HYDROLOGY STUDY PHASE I Page 6 of 6 Attachment E Civil D Post-Development Hydrology Calculations San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software, (c)1991-2004 Version 7.4 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 05/02/05 ********* Hydrology Study Control Information ********** ------------------------------------------------------------------------ Program License Serial Number 4012 ------------------------------------------------------------------------ Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.500 P6/P24 = 57.8% San Diego hydrology manual C values used Process from Point/Station 227.000 to Point/Station 228.000 INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 204.000(Ft.) Highest elevation = 242.500(Ft.) Lowest elevation 226.000(Ft.) Elevation difference = 16.500(Ft.) Slope = 8.088 % Top of Initial Area Slope adjusted by User to 30.000 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 30.00 %, in a development type of Neighborhod Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 1.91 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC= [1.8*(1.1_0.7700)*( 100.000.5)/( 30.000(1/3)1= 1.91 The initial area total distance of 204.00 (Ft.) entered leaves a remaining distance of 104.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.73 minutes for a distance of 104.00 (Ft.) and a slope of 8.09 % with an elevation difference of 8.41(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 0.735 Minutes Tt=[ (ll.9*0.01973)/( 8.41))'.385= 0.73 Total initial area Ti = 1.91 minutes from Figure 3-3 formula plus 0.73 minutes from the Figure 3-4 formula = 2.65 minutes Rainfall intensity (I) = 10.326(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Subarea runoff = 1.590(CFS) Total initial stream area = 0.200(Ac.) Process from Point/Station 228.000 to Point/Station 229.000 IMPROVED CHANNEL TRAVEL TIME Upstream point elevation = 226.000(Ft.) Downstream point elevation = 193.100(Ft.) Channel length thru subarea = 623.000(Ft.) Channel base width = 2.000(Ft.) Slope or ,Z' of left channel bank = 3.000 Outfall B TAKEN FROM HYDROLOGY PHASE II Page 1 of 13 Slope or Z' of right channel bank = 3.000 Estimated mean flow rate at midpoint of channel = 15.857(CFS) Mannings N = 0.035 Maximum depth of channel = 3.000(Ft.) Flow(q) thru subarea = 15.857(CFS) Depth of flow = 0.689(Ft.), Average velocity = 5.653(Ft/s) Channel flow top width = 6.137(Ft.) Flow Velocity = 5.65(Ft/s) Travel time = 1.84 mm. Time of concentration = 4.48 mm. Critical depth = 0.844(Ft.) Adding area flow to channel Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Al = 0.800 Sub-Area C Value = 0.770 Rainfall intensity = 7.350(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.770 CA = 4.089 Subarea runoff = 28.460(CFS) for 5.110(Ac.) Total runoff = 30.050(CFS) Total area = 5.310(Ac.) Depth of flow = 0.935(Ft.), Average velocity = 6.689(Ft/s) Critical depth = 1.156(Ft.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 229.000 to Point/Station 229.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 1 Stream flow area = 5.310(Ac.) Runoff from this stream = 30.050(CFS) Time of concentration = 4.48 min. Rainfall intensity = 7.350(In/Hr) Process from Point/Station 231.000 to Point/Station 229.000 **** INITIAL AREA EVALUATION Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (General Commercial Impervious value, Ai = 0.850 Sub-Area C Value = 0.800 Initial subarea total flow distance = 829.000(Ft.) Highest elevation = 230.600(Ft.) Lowest elevation = 193.300(Ft.) Elevation difference = 37.300(Ft.) Slope = 4.499 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 4.50 %, in a development type of General Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.10 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)J TC= [1.8*(1.1_0.8000)*( 90.000.5)/( 4.499(1/3)1= 3.10 The initial area total distance of 829.00 (Ft.) entered leaves a remaining distance of 739.00 (Ft.) Using Figure 3-4, the travel time for this distance is 4.17 minutes for a distance of 739.00 (Ft.) and a slope of 4.50 % with an elevation difference of 33.25(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))J'.385 *60(min/hr) = 4.169 Minutes Tt=[ (11.9*0.14003)/( 33.25)1 ^.385= 4.17 Total initial area Ti = 3.10 minutes from Figure 3-3 formula plus Outfall B TAKEN FROM HYDROLOGY PHASE II Page 2 of 13 4.17 minutes from the Figure 3-4 formula = 7.27 minutes Rainfall intensity (I) = 5.380(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (QKCIA) is C = 0.800 Subarea runoff = 3.486(CFS) Total initial stream area = 0.810 (Ac.) Process from Point/Station 229.000 to Point/Station 229.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.810(Ac.) Runoff from this stream = 3.486(CFS) Time of concentration = 7.27 mm. Rainfall intensity = 5.380(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 30.050 4.48 7.350 2 3.486 7.27 5.380 Qmax(l) = 1.000 * 1.000 * 30.050) + 1.000 * 0.617 * 3.486) + = 32.200 Qmax(2) = 0.732 * 1.000 * 30.050) + 1.000 * 1.000 * 3.486) + = 25.484 Total of 2 streams to confluence: Flow rates before confluence point: 30.050 3.486 Maximum flow rates at confluence using above data: 32.200 25.484 Area of streams before confluence: 5.310 0.810 Results of confluence: Total flow rate = 32.200(CFS) Time of concentration = 4.483 mm. Effective stream area after confluence 6.120(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 229.000 to Point/Station 230.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.320 (Ft.) Downstream point/station elevation = 185.010 (Ft.) Pipe length = 15.85(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 32.200(CFS) Given pipe size = 24.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 2.458(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss 0.321(Ft.) Minor friction loss 2.447(Ft.) K-factor = 1.50 Pipe flow velocity = 10.25(Ft/s) Travel time through pipe = 0.03 mm. Time of concentration (TC) = 4.51 mm. + + + + + + + + + + + + + + + + + + + + + + + + + + ++ + + + + + + + ++ + + + ++ + + ++++ + + + + + ++ + + + + + + + ++ + + + + + + Process from Point/Station 230.000 to Point/Station 230.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 6.120(Ac.) Runoff from this stream = 32.200(CFS) Time of concentration = 4.51 mm. Rainfall intensity = 7.322(In/Hr) Outfall B TAKEN FROM HYDROLOGY PHASE II Page 3 of 13 ++++++++++++++++++++++.++++++++++++++++++++++.+++++++++++++++++++.++++ Process from Point/Station 231.000 to Point/Station 232.000 INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (General Commercial Impervious value, Ai = 0.850 Sub-Area C Value = 0.800 Initial subarea total flow distance = 840.000(Ft.) Highest elevation = 230.600(Ft.) Lowest elevation = 193.300(Ft.) Elevation difference = 37.300(Ft.) Slope = 4.440 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 4.44 %, in a development type of General Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.12 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope"(1/3)J TC = (1.8*(1.1_0.8000)*( 90.000".5)/( 4.440"(1/3)J= 3.12 The initial area total distance of 840.00 (Ft.) entered leaves a remaining distance of 750.00 (Ft.) Using Figure 3-4, the travel time for this distance is 4.24 minutes for a distance of 750.00 (Ft.) and a slope of 4.44 % with an elevation difference of 33.30(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 4.238 Minutes Tt=( (11.9*0.14203)/( 33.30)]^.385= 4.24 Total initial area Ti = 3.12 minutes from Figure 3-3 formula plus 4.24 minutes from the Figure 3-4 formula = 7.35 minutes Rainfall intensity (I) = 5.341(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.800 Subarea runoff = 3.504(CFS) Total initial stream area = 0.820(Ac.) Process from Point/Station 232.000 to Point/Station 230.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.520(Ft.) Downstream point/station elevation = 185.010 (Ft.) Pipe length = 51.15(Ft.) Mannings N = 0.013 No. of pipes = 1 Required pipe flow = 3.504(CFS) Given pipe size 18.00(In.) Calculated individual pipe flow = 3.504(CFS) Normal flow depth in pipe = 7.17(In.) Flow top width inside pipe = 17.62(In.) Critical Depth = 8.56(In.) Pipe flow velocity = 5.34(Ft/s) Travel time through pipe = 0.16 mm. Time of concentration (TC) = 7.51 mm. +++++++++++++++++++++++++++.++++++++++++++++++++.++++++++++++++++++++. Process from Point/Station 230.000 to Point/Station 230.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number Stream flow area = 0.820(Ac.) Runoff from this stream = 3.504(CFS) Time of concentration = 7.51 mm. Rainfall intensity = 5.267(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) Outfall B TAKEN FROM HYDROLOGY PHASE II Page 4 of 13 1 32.200 4.51 7.322 2 3.504 7.51 5.267 Qmax(1) = 1.000 * 1.000 * 32.200) + 1.000 * 0.600 * 3.504) + = 34.302 Qmax(2) = 0.719 * 1.000 * 32.200) + 1.000 * 1.000 * 3.504) + = 26.666 Total of 2 streams to confluence: Flow rates before confluence point: 32.200 3.504 Maximum flow rates at confluence using above data: 34.302 26.666 Area of streams before confluence: 6.120 0.820 Results of confluence: Total flow rate = 34.302(CFS) Time of concentration = 4.509 mm. Effective stream area after confluence = 6.940(Ac.) Process from Point/Station 230.000 to Point/Station 233.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 184.670(Ft.) Downstream point/station elevation = 182.990 (Ft.) Pipe length = 115.65(Ft.) Mannings N = 0.013 No. of pipes = 1 Required pipe flow = 34.302(CFS) Given pipe size = 24.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 3.755(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 2.658(Ft.) Minor friction loss = 2.777(Ft.) K-factor = 1.50 Pipe flow velocity = 10.92 (Ft/s) Travel time through pipe = 0.18 mm. Time of concentration (TC) = 4.69 mm. ++++++ ++++++++++ + ++++++ + + +++++++++ +++++++++++++++ +++++++++++++++ + + ++++ Process from Point/Station 233.000 to Point/Station 233.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 6.940(Ac.) Runoff from this stream = 34.302(CFS) Time of concentration = 4.69 mm. Rainfall intensity = 7.143(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 234.000 to Point/Station 235.000 INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 146.000(Ft.) Highest elevation = 242.000(Ft.) Lowest elevation = 230.500(Ft.) Elevation difference = 11.500.(Ft.) Slope = 7.877 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 7.88 %, in a development type of Neighborhod Commercial Outfall B TAKEN FROM HYDROLOGY PHASE II Page of 13 In Accordance With Figure 3-3 Initial Area Time of Concentration = 2.99 minutes TC = [1.8*(1.1_C)*distance(Ft. ).5)/(% slope(1/3)] TC= [1.8*(1.1_0.7700)*( 100.000.5)/( 7.877(1/3)]= 2.99 The initial area total distance of 146.00 (Ft.) entered leaves a remaining distance of 46.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.40 minutes for a distance of 46.00 (Ft.) and a slope of 7.88 % with an elevation difference of 3.62(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) = 0.396 Minutes Tt=[ (11.9*0.0O873)/( 3.62)]A.385= 0.40 Total initial area Ti = 2.99 minutes from Figure 3-3 formula plus 0.40 minutes from the Figure 3-4 formula = 3.38 minutes Rainfall intensity (I) = 8.816(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Subarea runoff = 0.475(CFS) Total initial stream area = 0.070(Ac.) + + + + + +++++++ ++++++++++++++ +++++++++++++ Process from Point/Station 235.000 to Point/Station 236.000 IMPROVED CHANNEL TRAVEL TIME Upstream point elevation = 230.500(Ft.) Downstream point elevation = 197.700(Ft.) Channel length thru subarea = 727.000(Ft.) Channel base width = 2.000(Ft.) Slope or 'Z' of left channel bank = 4.000 Slope or 'Z' of right channel bank 4.000 Estimated mean flow rate at midpoint of channel 7.591(CFS) Manning's 'N' = 0.035 Maximum depth of channel = 3.000 (Ft.) Flow(q) thru subarea = 7.591(CFS) Depth of flow = 0.472(Ft.), Average velocity = 4.142 (Ft/s) Channel flow top width = 5.773(Ft.) Flow Velocity = 4.14(Ft/s) Travel time = 2.93 mm. Time of concentration = 6.31 mm. Critical depth = 0.539(Ft.) Adding area flow to channel Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Rainfall intensity = 5.897(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.770 CA = 2.479 Subarea runoff = 14.147(CFS) for 3.150(Ac.) Total runoff = 14.622(CFS) Total area = 3.220(Ac.) Depth of flow = 0.646(Ft.), Average velocity = 4.932(Ft/s) Critical depth = 0.750(Ft.) ++++++ + + + + + + + + + + + + + + + + 1- + + + + + + + ++ + + + + + + + + + + + + + + + + + + + + + + + ++ + + + + + + + ++ + + + + Process from Point/Station 236.000 to Point/Station 233.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 190.000(Ft.) Downstream point/station elevation = 182.990 (Ft.) Pipe length = 72.54(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 14.622(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 14.622(CFS) Normal flow depth in pipe = 8.44(In.) Flow top width inside pipe = 17.96(In.) Critical Depth = 16.76(In.) Pipe flow velocity = 17.97(Ft/s) Travel time through pipe = 0.07 mm. Outfall B TAKEN FROM HYDROLOGY PHASE II Page 6 of 13 Time of concentration (TC) = 6.37 mm. Process from Point/Station 233.000 to Point/Station 233.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 3.220(Ac.) Runoff from this stream = 14.622(CFS) Time of concentration = 6.37 mm. Rainfall intensity = 5.857(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 34.302 4.69 7.143 2 14.622 6.37 5.857 Qmax(1) = 1.000 * 1.000 * 34.302) + 1.000 * 0.735 * 14.622) + = 45.050 Qmax(2) 0.820 * 1.000 * 34.302) + 1.000 * 1.000 * 14.622) + = 42.748 Total of 2 streams to confluence: Flow rates before confluence point: 34.302 14.622 Maximum flow rates at confluence using above data: 45.050 42.748 Area of streams before confluence: 6.940 3.220 Results of confluence: Total flow rate = 45.050(CFS) Time of concentration = 4.686 mm. Effective stream area after confluence = 10.160 (Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 233.000 to Point/Station 237.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.660(Ft.) Downstream point/station elevation = 179.000 (Ft.) Pipe length = 440.77(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 45.050(CFS) Given pipe size = 30.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 3.617(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 5.315(Ft.) Minor friction loss = 1.962(Ft.) K-factor 1.50 Pipe flow velocity = 9.18 (Ft/s) Travel time through pipe = 0.80 mm. Time of concentration (TC) = 5.49 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 237.000 to Point/Station 238.000 IMPROVED CHANNEL TRAVEL TIME **** Upstream point elevation = 179.000(Ft.) Downstream point elevation = 175.100 (Ft.) Channel length thru subarea = 639.000(Ft.) Channel base width = 2.000(Ft.) Slope or 'Z' of left channel bank = 2.000 Slope or 'Z' of right channel bank = 2.000 Estimated mean flow rate at midpoint of channel = 45.896(CFS) Manning's 'N' = 0.015 Maximum depth of channel = 3.000(Ft.) Flow(q) thru subarea = 45.896(CFS) Outfall B TAKEN FROM HYDROLOGY PHASE II Page 7 of 13 Depth of flow = 1.408(Ft.), Average velocity = 6.766(Ft/s) Channel flow top width = 7.633(Ft.) Flow Velocity = 6.77(Ft/s) Travel time = 1.57 mm. Time of concentration = 7.06 mm. Critical depth = 1.578(Ft.) Adding area flow to channel Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Rainfall intensity = 5.484(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.774 CA = 8.511 Subarea runoff = 1.621(CFS) for 0.830(Ac.) Total runoff = 46.672(CFS) Total area = 10.990(Ac.) Depth of flow = 1.419(Ft.), Average velocity = 6.796(Ft/s) Critical depth = 1.594(Ft.) + + ++++++++++++++++++ +++++++++ +++++++++ +++ +++++++++++++ ++ + Process from Point/Station 238.000 to Point/Station 238.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 10.990(Ac.) Runoff from this stream 46.672(CFS) Time of concentration = 7.06 mm. Rainfall intensity = 5.484(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 239.000 to Point/Station 240.000 INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 175.000(Ft.) Highest elevation = 230.000(Ft.) Lowest elevation = 194.500(Ft.) Elevation difference = 35.500(Ft.) Slope = 20.286 % Top of Initial Area Slope adjusted by User to 30.000 % Bottom of Initial Area Slope adjusted by User to 2.000 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 30.00 %, in a development type of Neighborhod Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 1.91 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)J TC= (1.8*(1.1_0.7700)*( 100.000.5)/( 30.000(1/3)]= 1.91 The initial area total distance of 175.00 (Ft.) entered leaves a remaining distance of 75.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.98 minutes for a distance of 75.00 (Ft.) and a slope of 2.00 % with an elevation difference of 1.50(Ft.) from the end of the top area Tt = (11.9*length(Mi)A3)/(elevation change(Ft.))].385 *60(min/hr) 0.978 Minutes Tt=((11.9*0.01423)/( 1.50)J.385= 0.98 Total initial area Ti = 1.91 minutes from Figure 3-3 formula plus 0.98 minutes from the Figure 3-4 formula = 2.89 minutes Rainfall intensity (I) = 9.756(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Outfall B TAKEN FROM HYDROLOGY PHASE II Page 8 of 13 Subarea runoff = 2.254(CFS) Total initial stream area = 0.300 (Ac.) Process from Point/Station 240.000 to Point/Station 241.000 '*** IMPROVED CHANNEL TRAVEL TIME **** Upstream point elevation = 194.500(Ft.) Downstream point elevation = 181.700(Ft.) Channel length thru subarea = 620.000(Ft.) Channel base width = 2.000(Ft.) Slope or 'Z' of left channel bank = 4.000 Slope or 'Z' of right channel bank = 4.000 Estimated mean flow rate at midpoint of channel = 27.433(CFS) Manning's •N' = 0.035 Maximum depth of channel = 3.000(Ft.) Flow(q) thru subarea = 27.433(CFS) Depth of flow = 1.031(Ft.), Average velocity = 4.345(Ft/s) Channel flow top width = 10.247(Ft.) Flow Velocity = 4.35(Ft/s) Travel time = 2.38 mm. Time of concentration = 5.27 mm. Critical depth = 1.016(Ft.) Adding area flow to channel Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Rainfall intensity = 6.623(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.770 CA = 7.931 Subarea runoff = 50.277(CFS) for 10.000(Ac.) Total runoff = 52.530(CFS) Total area = 10.300(Ac.) Depth of flow = 1.370(Ft.), Average velocity = 5.127(Ft/s) Critical depth = 1.375(Ft.) + +++++++++++++++ +++++++ +++++++ + + + +++++++ ++++++++++ Process from Point/Station 241.000 to Point/Station 238.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 177.000(Ft.) Downstream point/station elevation = 175.100(Ft.) Pipe length = 76.35(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 52.530(CFS) Given pipe size 30.00(In.) Calculated individual pipe flow = 52.530(CFS) Normal flow depth in pipe = 20.53(In.) Flow top width inside pipe = 27.89(In.) Critical Depth = 27.96(In.) Pipe flow velocity = 14.69(Ft/s) Travel time through pipe = 0.09 mm. Time of concentration (TC) = 5.35 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 238.000 to Point/Station 238.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 10.300(Ac.) Runoff from this stream = 52.530(CFS) Time of concentration = 5.35 mm. Rainfall intensity = 6.554(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) Outfall B TAKEN FROM HYDROLOGY PHASE II Page 9 of 13 1 46.672 7.06 5.484 2 52.530 5.35 6.554 Qmax(l) = L.odo * 1.000 * 46.672) + 0.837 * 1.000 * 52.530) + = 90.622 Qmax(2) = 1.000 * 0.758 * 46.672) + 1.000 * 1.000 * 52.530) + = 87.928 Total of 2 streams to confluence: Flow rates before confluence point: 46.672 52.530 Maximum flow rates at confluence using above data: 90.622 87.928 Area of streams before confluence: 10.990 10.300 Results of confluence: Total flow rate = 90.622(CFS) Time of concentration = 7.060 mm. Effective stream area after confluence = 21.290 (Ac.) +++++++.++++++++++++.+++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 238.000 to Point/Station 242.000 IMPROVED CHANNEL TRAVEL TIME Upstream point elevation = 175.100(Ft.) Downstream point elevation = 175.000(Ft.) Channel length thru subarea = 316.000(Ft.) Channel base width = 6.000(Ft.) Slope or 'Z' of left channel bank = 2.000 Slope or 'Z' of right channel bank = 2.000 Estimated mean flow rate at midpoint of channel = 90.651(CFS) Manning's 'N' = 0.025 Maximum depth of channel = 4.000 (Ft.) Flow(q) thru subarea = 90.651(CFS) Depth of flow = 3.740(Ft.), Average velocity = 1.798(Ft/s) Channel flow top width = 20.958(Ft.) Flow Velocity = 1.80(Ft/s) Travel time = 2.93 mm. Time of concentration = 9.99 mm. Critical depth = 1.594(Ft.) Adding area flow to channel Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 The area added to the existing stream causes a a lower flow rate of Q = 73.567(CFS) therefore the upstream flow rate of 0 = 90.622(CFS) is being used Rainfall intensity = 4.384(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.772 CA = 16.781 Subarea runoff = 0.000(CFS) for 0.440(Ac.) Total runoff = 90.622(CFS) Total area = 21.730(Ac.) Depth of flow = 3.739(Ft.), Average velocity = 1.798(Ft/s) Critical depth = 1.594(Ft.) Process from Point/Station 1242.000 to Point/Station 222.000 PIPEFLOW TRAVEL TIME (User specified size) Upstream point/station elevation = 168.610(Ft.) Downstream point/station elevation = 167.920 (Ft.) Pipe length = 33.95(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 90.622(CFS) Outfall B TAKEN FROM HYDROLOGY PHASE II Page 10 of 13 Given pipe size = 36.00(In.) Calculated individual pipe flow = 90.622(CFS) Normal flow depth in pipe = 28.08(In.) Flow top width inside pipe = 29.83(In.) Critical Depth = 34.20(In.) Pipe flow velocity = 15.31(Ft/s) Travel time through pipe = 0.04 mm. Time of concentration (TC) = 10.03 mm. + ++++ + + + + + + + + + +++++++++ ++++++++++++++++ + ++++++++++++++++++++++++++++++ Process from Point/Station 222.000 to Point/Station 222.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: ]. Stream flow area = 21.730(Ac.) Runoff from this stream = 90.622(CFS) Time of concentration = 10.03 mm. Rainfall intensity = 4.374(In/Hr) Program is now starting with Main Stream No. 2 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 243.000 to Point/Station 222.000 INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (Neighborhod Commercial Impervious value, Ai = 0.800 Sub-Area C Value = 0.770 Initial subarea total flow distance = 1045.000(Ft.) Highest elevation = 227.000(Ft.) Lowest elevation = 176.500(Ft.) Elevation difference = 50.500(Ft.) Slope = 4.833 % Top of Initial Area Slope adjusted by User to 30.000 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 30.00 %, in a development type of Neighborhod Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 1.91 minutes TC = [1.8*(1.1_C)*distance(Ft.)s.5)/(% slope'(1/3)] TC = [1.8*(1.1_0.7700)*( 100.000.5)/( 30.000(1/3)1= 1.91 The initial area total distance of 1045.00 (Ft.) entered leaves a remaining distance of 945.00 (Ft.) Using Figure 3-4, the travel time for this distance is 4.90 minutes for a distance of 945.00 (Ft.) and a slope of 4.83 % with an elevation difference of 45.67(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))].385 *60(min/hr) = 4.901 Minutes Tt=[ (11.9*0.17903)/( 45.67)].385= 4.90 Total initial area Ti = 1.91 minutes from Figure 3-3 formula plus 4.90 minutes from the Figure 3-4 formula = 6.81 minutes Rainfall intensity (I) = 5.611(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.770 Subarea runoff = 10.283(CFS) Total initial stream area = 2.380(Ac.) ++ ++++ + + + + + + + ++++++++ +++++ ++++++++++++++++++++++++++ ++++++ ++++++++++ ++ Process from Point/Station 222.000 to Point/Station 222.000 CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 2.380(Ac.) Runoff from this stream = 10.283(CFS) Time of concentration = 6.81 mm. Outfall B TAKEN FROM HYDROLOGY PHASE II Page 11 of 13 Rainfall intensity = 5.611(In/Hr) Program is now starting with Main Stream No. 3 Process from Point/Station 222.000 to Point/Station 222.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** User specified 'C' value of 0.760 given for subarea Rainfall intensity (I) = 6.472(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 5.46 mm. Rain intensity = 6.47(In/Hr) Total area = 12.780(Ac.) Total runoff = 65.167(CFS) +++..+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 222.000 to Point/Station 222.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 3 Stream flow area = 12.780(Ac.) Runoff from this stream = 65.167(CFS) Time of concentration 5.46 mm. Rainfall intensity = 6.472(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 90.622 10.03 4.374 2 10.283 6.81 5.611 3 65.167 5.46 6.472 Qmax(l) = 1.000 * 1.000 * 90.622) + 0.779 * 1.000 * 10.283) + 0.676 * 1.000 * 65.167) + = 142.673 Qmax(2) 1.000 * 0.680 * 90.622) + 1.000 * 1.000 * 10.283) + 0.867 * 1.000 * 65.167) + = 128.360 Qmax(3) = 1.000 * 0.545 * 90.622) + 1.000 * 0.801 * 10.283) + 1.000 * 1.000 * 65.167) + = 122.763 Total of 3 main streams to confluence: Flow rates before confluence point: 90.622 10.283 65.167 Maximum flow rates at confluence using above data: 142.673 128.360 122.763 Area of streams before confluence: 21.730 2.380 12.780 Results of confluence: Total flow rate = 142.673(CFS) Time of concentration = 10.025 mm. Effective stream area after confluence = 36.890(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 222.000 to Point/Station 244.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 167.590 (Ft.) Downstream point/station elevation = 167.270(Ft.) Pipe length = 15.73(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 142.673(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 Outfall B TAKEN FROM HYDROLOGY PHASE II Page 12 of 13 9.889(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss = 0.720(Ft.) Minor friction loss = 9.489(Ft.) K-factor 1.50 Pipe flow velocity = 20.18(Ft/s) Travel time through pipe = 0.01 mm. Time of concentration (TC) = 10.04 mm. End of computations, total study area = 36.890 (Ac.) Outfall B TAKEN FROM HYDROLOGY PHASE II Page 13 of 13 San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software, (c)1991-2012 Version 7.9 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 04/28/15 ------------------------------------------------------------------------ PLANNING AREA NO. 5 - RESORT SITE PHASE III 100 YEAR STORM POST-DEVELOPMENT Outfall A Program License Serial Number 6312 Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.500 P6/P24 = 57.8% San Diego hydrology manual 'C' values used Process from Point/Station 301.000 to Point/Station 301.100 **** 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 66.000 (Ft.) Highest elevation = 220.000(Ft.) Lowest elevation = 214.500(Ft.) Elevation difference = 5.500(Ft.) Slope = 8.333 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 8.33 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 4.17 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = (1.8*(1.1_0.6300)*( 100.000.5)/( 8.333(1/3)1= 4.17 Calculated TC of 4.173 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.263(CFS) Total initial stream area = 0.061 (Ac.) + ++++++++++++++++ +++ + + + + + ++++++++ + +++++ +++++++++++++++++++++ + Process from Point/Station 301.100 to Point/Station 302.000 **** IRREGULAR CHANNEL FLOW TRAVEL TIME Estimated mean flow rate at midpoint of channel 0.958(CFS) Irregular Channel Data ----------------------------------------------------------------- Information entered for subchannel number 1 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 1 of 31 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.12 2 1.50 0.00 3 3.00 0.12 Manning's 'N' friction factor = 0.015 --------------------------------------------------- Sub-Channel flow In 0.380(CFS) flow top width = 3.000(Ft.) velocity= 2.113(Ft/s) area = 0.180(Sq.Ft) Froude number = 1.520 Upstream point elevation = 214.500(Ft.) Downstream point elevation = 211.000(Ft.) Flow length = 180.000(Ft.) Travel time = 0.56 mm. Time of concentration = 4.74 mm. Depth of flow = 0.120(Ft.) Average velocity = 5.323(Ft/s) Total irregular channel flow = 0.958(CFS) Irregular channel normal depth above invert elev. = 0.120(Ft.) Average velocity of channel(s) = 5.323(Ft/s) Adding area flow to channel Calculated TC of 4.737 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm User specified C' value of 0.630 given for subarea Rainfall intensity = 6.850(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.241 Subarea runoff = 1.390(CFS) for 0.322(Ac.) Total runoff = 1.653(CFS) Total area = 0.383(Ac.) +++++++++++++++++++++++.++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 302.000 to Point/Station 303.000 ''' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 202.640(Ft.) Downstream point/station elevation = 202.260 (Ft.) Pipe length = 71.00(Ft.) Slope = 0.0054 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.653(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow 1.653(CFS) Normal flow depth in pipe = 6.94 (In.) Flow top width inside pipe = 11.85(In.) Critical Depth = 6.55(In.) Pipe flow velocity = 3.51 (Ft/s) Travel time through pipe = 0.34 mm. Time of concentration (TC) = 5.07 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 303.000 to Point/Station 303.000 SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 6.786(In/Rr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 5.07 mm. Rainfall intensity = 6.786(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.490 Subarea runoff 1.673(CFS) for 0.395(Ac.) Total runoff = 3.326(CFS) Total area = 0.778(Ac.) Process from Point/Station 303.000 to Point/Station 304.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 2 of 31 Upstream point/station elevation = 202.260 (Ft.) Downstream point/station elevation = 201.730 (Ft.) Pipe length = 75.00(Ft.) Slope = 0.0071 Manning's N 0.013 No. of pipes = 1 Required pipe flow = 3.326(CFS) Nearest computed pipe diameter = 15.00(In.) Calculated individual pipe flow 3.326(CFS) Normal flow depth in pipe = 8.48(In.) Flow top width inside pipe = 14.87(In.) Critical Depth = 8.82(In.) Pipe flow velocity = 4.65(Ft/s) Travel time through pipe = 0.27 mm. Time of concentration (TC) = 5.34 mm. ++++++ +++++++++ + ++++++ +++++++++ + + + ++++++ + ++++++++ + Process from Point/Station 304.000 to Point/Station 304.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 6.564(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 5.34 mm. Rainfall intensity = 6.564(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.641 Subarea runoff = 0.883(CFS) for 0.240(Ac.) Total runoff = 4.210(CFS) Total area = 1.018(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 304.000 to Point/Station 305.000 '''' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 201.730(Ft.) Downstream point/station elevation = 201.210 (Ft.) Pipe length = 49.00(Ft.) Slope = 0.0106 Manning's N 0.013 No. of pipes = 1 Required pipe flow = 4.210(CFS) Nearest computed pipe diameter = 15.00(m.) Calculated individual pipe flow = 4.210(CFS) Normal flow depth in pipe 8.66(In.) Flow top width inside pipe = 14.82(In.) Critical Depth = 9.97 (In.) Pipe flow velocity = 5.74 (Ft/s) Travel time through pipe = 0.14 min. Time of concentration (TC) = 5.48 mm. Process from Point/Station 305.000 to Point/Station 305.000 **** SUBAREA FLOW ADDITION Rainfall intensity (I) = 6.454(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 5.48 mm. Rainfall intensity = 6.454(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.925 Subarea runoff = 1.759(CFS) for 0.450(Ac.) Total runoff = 5.969(CFS) Total area = 1.468(Ac.) ++ +++ +++++ +++++++ +++++++++++ + + + + ++++++ +++++++++++++ + ++++++ + ++++++++++ + Process from Point/Station 305.000 to Point/Station 306.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 201.210(Ft.) Downstream point/station elevation = 193.500 (Ft.) Pipe length = 140.00(Ft.) Slope = 0.0551 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.969(CFS) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 3 of 31 Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 5.969(CFS) Normal flow depth in pipe = 7.50(In.) Flow top width inside pipe = 11.62(In.) Critical depth could not be calculated. Pipe flow velocity = 11.57(Ft/s) Travel time through pipe = 0.20 mm. Time of concentration (TC) = 5.69 mm. + + +++++++++++ + + +++++ ++++++++.++++++++ ++++++ ++++++++++++ + Process from Point/Station 306.000 to Point/Station 306.000 SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 6.305(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration 5.69 mm. Rainfall intensity = 6.305(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 1.537 Subarea runoff = 3.723(CFS) for 0.972(Ac.) Total runoff = 9.692(CFS) Total area = 2.440(Ac.) + ++++++++++++++ +++++ + + ++++++ + +++++++ + ++++++ +++++++++ .I-++ + + + Process from Point/Station 306.000 to Point/Station 306.000 SUBAREA FLOW ADDITION Rainfall intensity (I) = 6.305(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 5.69 mm. Rainfall intensity = 6.305(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 1.634 Subarea runoff = 0.608(CFS) for 0.153(Ac.) Total runoff = 10.300(CFS) Total area = 2.593(Ac.) + + +++++++++++ ++++++++ + +++++++ ++++++ + +++++++ ++++++++++++ + Process from Point/Station 306.000 to Point/Station 324.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 190.280(Ft.) Downstream point/station elevation = 190.000(Ft.) Pipe length = 54.00(Ft.) Slope = 0.0052 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 10.300(CFS) Nearest computed pipe diameter = 21.00(In.) Calculated individual pipe flow 10.300(CFS) Normal flow depth in pipe = 15.61 (In.) Flow top width inside pipe = 18.35(In.) Critical Depth = 14.36(In.) Pipe flow velocity = 5.37(Ft/s) Travel time through pipe = 0.17 mm. Time of concentration (TC) = 5.85 mm. Process from Point/Station 324.000 to Point/Station 324.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 1 Stream flow area = 2.593(Ac.) Runoff from this stream = 10.300(CFS) Time of concentration = 5.85 mm. Rainfall intensity = 6.188(In/Rr) Program is now starting with Main Stream No. 2 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 4 of 31 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 313.000 to Point/Station 314.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 107.000(Ft.) Highest elevation 240.000(Ft.) Lowest elevation = 222.000(Ft.) Elevation difference = 18.000(Ft.) Slope = 16.822 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 16.82 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.30 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = (1.8*(1.1_0.6300)*( 100.000.5)/( 16.822(1/3)]= 3.30 The initial area total distance of 107.00 (Ft.) entered leaves a remaining distance of 7.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.07 minutes for a distance of 7.00 (Ft.) and a slope of 16.82 % with an elevation difference of 1.18(Ft.) from the end of the top area Tt = (11.9*length(Mi)3)/(elevation change(Ft.))]".385 *60(min/hr) 0.069 Minutes Tt=[ (11.9*0.O0133)/( 1.18)1^.385= 0.07 Total initial area Ti 3.30 minutes from Figure 3-3 formula plus 0.07 minutes from the Figure 3-4 formula = 3.37 minutes Calculated TC of 3.371 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.561(CFS) Total initial stream area = 0.130(Ac.) Process from Point/Station 314.000 to Point/Station 315.000 IRREGULAR CHANNEL FLOW TRAVEL TIME Estimated mean flow rate at midpoint of channel = 2.050(CFS) Depth of flow = 0.205(Ft.), Average velocity = 2.512(Ft/s) ******* Irregular Channel Data ------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.31 2 16.50 0.13 3 18.00 0.00 4 19.50 0.13 5 44.00 0.63 Manning's 'N' friction factor = 0.015 Sub-Channel flow = 2.050(CFS) flow top width = 13.556(Ft.) velocity= 2.512(Ft/s) area = 0.816(Sq.Ft) Froude number = 1.804 Upstream point elevation = 222.000 (Ft.) Downstream point elevation = 216.000 (Ft.) Flow length = 220.000(Ft.) Travel time = 1.46 mm. 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page of 31 Time of concentration = 4.83 mm. Depth of flow = 0.205 (Ft.) Average velocity = 2.512(Ft/s) Total irregular channel flow = 2.050(CFS) Irregular channel normal depth above invert elev. = 0.205 (Ft.) Average velocity of channel(s) = 2.512(Ft/s) Adding area flow to channel Calculated TC of 4.831 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm User specified ICI value of 0.630 given for subarea Rainfall intensity = 6.850(In/Rr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.517 Subarea runoff = 2.978(CFS) for 0.690(Ac.) Total runoff = 3.539(CFS) Total area = 0.820(Ac.) Depth of flow = 0.233(Ft.), Average velocity = 2.820(Ft/s) +++++++ + +++++++ + + ++++++++++ + +++++ +++++++ + +++++++ ++++++++ + Process from Point/Station 315.000 to Point/Station 316.000 '''' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 213.070(Ft.) Downstream point/station elevation = 208.970 (Ft.) Pipe length = 132.00(Ft.) Slope = 0.0311 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.539(CFS) Nearest computed pipe diameter = 12.00 (In.) Calculated individual pipe flow = 3.539(CFS) Normal flow depth in pipe = 6.45(In.) Flow top width inside pipe = 11.97(In.) Critical Depth = 9.64(In.) Pipe flow velocity = 8.23(Ft/s) Travel time through pipe = 0.27 mm. Time of concentration (TC) = 5.10 mm. Process from Point/Station 316.000 to Point/Station 316.000 SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 6.765(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 5.10 mm. Rainfall intensity = 6.765(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.699 Subarea runoff = 1.192(CFS) for 0.290(Ac.) Total runoff = 4.731(CFS) Total area = 1.110(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 316.000 to Point/Station 321.000 "'' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 208.970(Ft.) Downstream point/station elevation = 203.200(Ft.) Pipe length = 145.00(Ft.) Slope = 0.0398 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 4.731(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 4.731(CFS) Normal flow depth in pipe = 7.16(In.) Flow top width inside pipe = 11.77 (In.) Critical Depth = 10.82(In.) Pipe flow velocity = 9.69(Ft/s) Travel time through pipe = 0.25 mm. Time of concentration (TC) = 5.35 mm. 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 6 of 31 Process from Point/Station 321.000 to Point/Station 321.000 **** CONFLUENCE OF MINOR STREAMS '''' Along Main Stream number: 2 in normal stream number 1 Stream flow area = 1.110(Ac.) Runoff from this stream 4.731(CFS) Time of concentration = 5.35 mm. Rainfall intensity = 6.560(In/Hr) +++ +++++++++.+++++++++ + + + ++++++++++ + +++++++ + + +++++++++ + ++ + +++++++..++ + Process from Point/Station 317.000 to Point/Station 318.000 '''' 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 99.000(Ft.) Highest elevation = 226.000(Ft.) Lowest elevation = 224.000(Ft.) Elevation difference = 2.000(Ft.) Slope = 2.020 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 80.00 (Ft) for the top area slope value of 2.02 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration 5.99 minutes TC = (1.8*(1.1_C)*diStance(Ft.).5)/(% slope(1/3)] TC = (1.8*(1.1_0.6300)*( 80.000.5)/( 2.020(1/3)1= 5.99 The initial area total distance of 99.00 (Ft.) entered leaves a remaining distance of 19.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.34 minutes for a distance of 19.00 (Ft.) and a slope of 2.02 % with an elevation difference of 0.38(Ft.) from the end of the top area Tt = [11.9*1ength(Mi)3)/(e1evation change(Ft.))]".385 *60(min/hr) = 0.339 Minutes Tt=[(11.9*0.00363)/( 0.38)].385= 0.34 Total initial area Ti = 5.99 minutes from Figure 3-3 formula plus 0.34 minutes from the Figure 3-4 formula = 6.32 minutes Rainfall intensity (I) = 5.887(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.749(CFS) Total initial stream area = 0.202(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 318.000 to Point/Station 319.000 **** IMPROVED CHANNEL TRAVEL TIME Covered channel Upstream point elevation = 224.000(Ft.) Downstream point elevation = 215.190(Ft.) Channel length thru subarea = 478.000(Ft.) Channel base width = 0.500(Ft.) Slope or 'Z' of left channel bank = 0.000 Slope or 'Z' of right channel bank = 0.000 Estimated mean flow rate at midpoint of channel = 2.648(CFS) Manning's 'N' = 0.015 Maximum depth of channel = 0.500(Ft.) Flow(q) thru subarea = 2.648(CFS) Pressure flow condition in covered channel: Wetted perimeter = 2.00(Ft.) Flow area = 0.25(Sq.Ft) Hydraulic grade line required at box inlet = 135.375(Ft.) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 7ot 31 Friction loss = 141.573(Ft.) Minor Friction loss = 2.611(Ft.) K-Factor = 1.500 Flow Velocity = 10.59 (Ft/s) Travel time = 0.75 mm. Time of concentration = 7.08 mm. Adding area flow to channel Rainfall intensity (I) = 5.475(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Rainfall intensity = 5.475(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C 0.630 CA = 0.814 Subarea runoff = 3.707(CFS) for 1.090(Ac.) Total runoff = 4.457(CFS) Total area = 1.292(Ac.) Process from Point/Station 319.000 to Point/Station 320.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 215.190(Ft.) Downstream point/station elevation = 204.160(Ft.) Pipe length = 112.00(Ft.) Slope = 0.0985 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 4.457(CFS) Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow = 4.457(CFS) Normal flow depth in pipe = 6.42(In.) Flow top width inside pipe = 8.14 (In.) Critical depth could not be calculated. Pipe flow velocity = 13.21 (Ft/s) Travel time through pipe = 0.14 mm. Time of concentration (TC) = 7.22 mm. Process from Point/Station 320.000 to Point/Station 320.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.406(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 7.22 mm. Rainfall intensity = 5.406(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.971 Subarea runoff = 0.795(CFS) for 0.250(Ac.) Total runoff = 5.252(CFS) Total area = 1.542(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 320.000 to Point/Station 321.000 '''' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 204.160(Ft.) Downstream point/station elevation = 203.200 (Ft.) Pipe length = 47.00(Ft.) Slope = 0.0204 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.252(CFS) Nearest computed pipe diameter = 15.00(In.) Calculated individual pipe flow = 5.252(CFS) Normal flow depth in pipe = 8.10(In.) Flow top width inside pipe = 14.95(In.) Critical Depth = 11.14(In.) Pipe flow velocity = 7.76(Ft/s) Travel time through pipe = 0.10 mm. Time of concentration (TC) = 7.32 mm. Process from Point/Station 321.000 to Point/Station 321.000 **** CONFLUENCE OF MINOR STREAMS **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 8 of 31 Along Main Stream number: 2 in normal stream number 2 Stream flow area = 1.542(Ac.) Runoff from this stream = 5.252(CFS) Time of concentration = 7.32 mm. Rainfall intensity = 5.358(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 4.731 5.35 6.560 2 5.252 7.32 5.358 Qmax(1) = 1.000 * 1.000 * 4.731) + 1.000 * 0.731 * 5.252) + = 8.568 Qmax(2) = 0.817 * 1.000 * 4.731) + 1.000 * 1.000 * 5.252) + = 9.115 Total of 2 streams to confluence: Flow rates before confluence point: 4.731 5.252 Maximum flow rates at confluence using above data: 8.568 9.115 Area of streams before confluence: 1.110 1.542 Results of confluence: Total flow rate = 9.115(CFS) Time of concentration = 7.319 mm. Effective stream area after confluence = 2.652(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 321.000 to Point/Station 322.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 203.200(Ft.) Downstream point/station elevation = 201.190 (Ft.) Pipe length = 51.00(Ft.) Slope = 0.0394 Manning's N 0.013 No. of pipes = 1 Required pipe flow = 9.115(CFS) Nearest computed pipe diameter = 15.00 (In.) Calculated individual pipe flow = 9.115(CFS) Normal flow depth in pipe = 9.34 (In.) Flow top width inside pipe = 14.54 (In.) Critical Depth = 13.91(In.) Pipe flow velocity = 11.34 (Ft/s) Travel time through pipe = 0.07 mm. Time of concentration (TC) = 7.39 mm. Process from Point/Station 322.000 to Point/Station 322.000 SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.323(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 7.39 mm. Rainfall intensity = 5.323(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C 0.630 CA = 2.452 Subarea runoff = 3.935(CFS) for 1.240(Ac.) Total runoff = 13.051(CFS) Total area = 3.892(Ac.) Process from Point/Station 322.000 to Point/Station 323.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 9 of 31 Upstream point/station elevation = 201.190(Ft.) Downstream point/station elevation = 199.500(Ft.) Pipe length = 27.00(Ft.) Slope = 0.0626 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 13.051(CFS) Nearest computed pipe diameter = 15.00(In.) Calculated individual pipe flow = 13.051(CFS) Normal flow depth in pipe = 10.22(In.) Flow top width inside pipe = 13.98(m.) Critical depth could not be calculated. Pipe flow velocity = 14.66 (Ft/s) Travel time through pipe = 0.03 mm. Time of concentration (TC) = 7.42 mm. Process from Point/Station 323.000 to Point/Station 323.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.308(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 7.42 mm. Rainfall intensity = 5.308(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 2.719 Subarea runoff = 1.383(CFS) for 0.424(Ac.) Total runoff = 14.434(CFS) Total area = 4.316(Ac.) Process from Point/Station 323.000 to Point/Station 324.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 196.500 (Ft.) Downstream point/station elevation = 190.000 (Ft.) Pipe length = 41.00(Ft.) Slope = 0.1585 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 14.434(CFS) Nearest computed pipe diameter = 15.00(In.) Calculated individual pipe flow = 14.434(CFS) Normal flow depth in pipe = 8.04 (In.) Flow top width inside pipe = 14.96(m.) Critical depth could not be calculated. Pipe flow velocity = 21.56 (Ft/s) Travel time through pipe = 0.03 mm. Time of concentration (TC) = 7.46 mm. Process from Point/Station 324.000 to Point/Station 324.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 4.316(Ac.) Runoff from this stream = 14.434(CFS) Time of concentration = 7.46 mm. Rainfall intensity = 5.294 (In/Br) Program is now starting with Main Stream No. 3 Process from Point/Station 307.000 to Point/Station 308.000 **** 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 (MEDIUM DENSITY RESIDENTIAL 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 10 of 31 (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 82.000(Ft.) Highest elevation = 234.000(Ft.) Lowest elevation = 231.770(Ft.) Elevation difference = 2.230(Ft.) Slope = 2.720 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 2.72 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.75 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 90.000.5)/( 2.720(1/3)1= 5.75 Rainfall intensity (I) = 6.260(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.189(CFS) Total initial stream area = 0.048(Ac.) Process from Point/Station 308.000 to Point/Station 309.000 **** IRREGULAR CHANNEL FLOW TRAVEL TIME Estimated mean flow rate at midpoint of channel = 1.076(CFS) Depth of flow 0.175(Ft.), Average velocity = 2.295(Ft/s) Irregular Channel Data ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.31 2 16.50 0.13 3 18.00 0.00 4 19.50 0.13 5 44.00 0.63 Manning's 'N' friction factor = 0.015 ----------------------------------------------------------------- Sub-Channel flow = 1.076(CFS) flow top width = 9.276(Ft.) velocity= 2.295(Ft/s) area = 0.469(Sq.Ft) Froude number = 1.799 Upstream point elevation = 231.770(Ft.) Downstream point elevation = 224.000(Ft.) Flow length 270.000(Ft.) Travel time = 1.96 mm. Time of concentration = 7.71 mm. Depth of flow = 0.175(Ft.) Average velocity = 2.295(Ft/s) Total irregular channel flow = 1.076(CFS) Irregular channel normal depth above invert elev. = 0.175(Ft.) Average velocity of channel(s) = 2.295(Ft/s) Adding area flow to channel Rainfall intensity (I) = 5.181(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Rainfall intensity = 5.181(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.360 Subarea runoff = 1.674(CFS) for 0.523(Ac.) Total runoff = 1.864(CFS) Total area = 0.571(Ac.) Depth of flow = 0.199(Ft.), Average velocity = 2.519(Ft/s) ++ + +++++ + ++++++ ++ + ++ +++++++++..++ +++++++ + +++++++++++ + Process from Point/Station 309.000 to Point/Station 310.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 11 of 31 Upstream point/station elevation = 221.980(Ft.) Downstream point/station elevation = 221.800 (Ft.) Pipe length = 50.00(Ft.) Slope = 0.0036 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.864(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 1.864(CFS) Normal flow depth in pipe 8.67 (In.) Flow top width inside pipe = 10.74 (In.) Critical Depth = 6.98(In.) Pipe flow velocity = 3.07(Ft/s) Travel time through pipe = 0.27 mm. Time of concentration (TC) = 7.98 mm. Process from Point/Station 310.000 to Point/Station 310.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.066(In/Hr) for a 100.0 year Storm User specified 'C' value of 0.630 given for subarea Time of concentration 7.98 mm. Rainfall intensity = 5.066(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.729 Subarea runoff = 1.829(CFS) for 0.586(Ac.) Total runoff = 3.693(CFS) Total area = 1.157(Ac.) Process from Point/Station 310.000 to Point/Station 311.000 '''' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 218.800 (Ft.) Downstream point/station elevation = 213.040 (Ft.) Pipe length = 228.00(Ft.) Slope = 0.0253 Manning's N 0.013 No. of pipes = 1 Required pipe flow = 3.693(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 3.693(CFS) Normal flow depth in pipe = 7.07 (In.) Flow top width inside pipe = 11.81(In.) Critical Depth = 9.83(In.) Pipe flow velocity = 7.68(Ft/s) Travel time through pipe = 0.49 mm. Time of concentration (TC) = 8.48 mm. Process from Point/Station 311.000 to Point/Station 311.000 CONFLUENCE OF MINOR STREAMS Along Main Stream number: 3 in normal stream number 1 Stream flow area = 1.157(Ac.) Runoff from this stream = 3.693(CFS) Time of concentration 8.48 mm. Rainfall intensity = 4.874(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 325.000 to Point/Station 326.000 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 12 of 31 Initial subarea total flow distance = 113.000(Ft.) Highest elevation = 224.000(Ft.) Lowest elevation = 223.000(Ft.) Elevation difference = 1.000(Ft.) Slope = 0.885 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.89 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.10 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope'(1/3)] TC = L1.8*(1.1_0.6300)*( 65.000.5)/( 0.885(1/3)1= 7.10 The initial area total distance of 113.00 (Ft.) entered leaves a remaining distance of 48.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.95 minutes for a distance of 48.00 (Ft.) and a slope of 0.89 % with an elevation difference of 0.42(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))].385 *60(min/hr) = 0.950 Minutes Tt=[ (11.9*0.00913)/( 0.42)]A.385= 0.95 Total initial area Ti = 7.10 minutes from Figure 3-3 formula plus 0.95 minutes from the Figure 3-4 formula = 8.05 minutes Rainfall intensity (I) = 5.037(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.568(CFS) Total initial stream area = 0.179(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++•f+++ Process from Point/Station 326.000 to Point/Station 312.000 IMPROVED CHANNEL TRAVEL TIME Covered channel Upstream point elevation = 223.000 (Ft.) Downstream point elevation = 222.000(Ft.) Channel length thru subarea = 72.000(Ft.) Channel base width = 0.500(Ft.) Slope or 'Z' of left channel bank = 0.000 Slope or 'Z' of right channel bank 0.000 Estimated mean flow rate at midpoint of channel = 1.226(CFS) Manning's 'N' = 0.015 Maximum depth of channel = 1.000(Ft.) Flow(q) thru subarea = 1.226(CFS) Depth of flow = 0.656(Ft.), Average velocity = 3.737(Ft/s) Channel flow top width = 0.500 (Ft.) Flow Velocity 3.74(Ft/s) Travel time = 0.32 mm. Time of concentration = 8.37 mm. Critical depth = 0.570(Ft.) Adding area flow to channel Rainfall intensity (I) = 4.912(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Rainfall intensity = 4.912(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.374 Subarea runoff = 1.270(CFS) for 0.415(Ac.) Total runoff = 1.838(CFS) Total area = 0.594(Ac Depth of flow = 0.930(Ft.), Average velocity = 3.954(Ft/s) Critical depth = 0.750(Ft.) ++++++++++++++++++++++ ++++++ + ++++++ + +++++++++ +++++++++++++++++ + + + Process from Point/Station 312.000 to Point/Station 311.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 219.000 (Ft.) Downstream point/station elevation = 213.040 (Ft.) Pipe length = 74.00(Ft.) Slope = 0.0805 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.838(CFS) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 13 of 31 Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow = 1.838(CFS) Normal flow depth in pipe = 3.91 (In.) Flow top width inside pipe 8.92 (In.) Critical Depth = 7.44 (In.) Pipe flow velocity = 9.98(Ft/s) Travel time through pipe = 0.12 mm. Time of concentration (TC) = 8.50 mm. ++++++++++ + ++++++ ++++++++ + ++++++++ +++++++++++++++++++++++++ ++ + Process from Point/Station 311.000 to Point/Station 311.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 3 in normal stream number 2 Stream flow area = 0.594 (Ac.) Runoff from this stream = 1.838(CFS) Time of concentration = 8.50 mm. Rainfall intensity = 4.865(m/Fir) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Fir) 1 3.693 8.48 4.874 2 1.838 8.50 4.865 Qmax(l) = 1.000 * 1.000 * 3.693) + 1.000 * 0.997 * 1.838) + 5.526 Qmax(2) = 0.998 * 1.000 * 3.693) + 1.000 * 1.000 * 1.838) + = 5.525 Total of 2 streams to confluence: Flow rates before confluence point: 3.693 1.838 Maximum flow rates at confluence using above data: 5.526 5.525 Area of streams before confluence: 1.157 0.594 Results of confluence: Total flow rate = 5.526(CFS) Time of concentration = 8.476 mm. Effective stream area after confluence = 1.751(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 311.000 to Point/Station 324.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 213.040(Ft.) Downstream point/station elevation = 190.000(Ft.) Pipe length = 495.00(Ft.) Slope = 0.0465 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.526(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 5.526(CFS) Normal flow depth in pipe = 7.54 (In.) Flow top width inside pipe = 11.60(In.) Critical Depth = 11.28(In.) Pipe flow velocity = 10.65(Ft/s) Travel time through pipe = 0.77 mm. Time of concentration (TC) 9.25 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 324.000 to Point/Station 324.000 **** CONFLUENCE OF MAIN STREAMS **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 14 of 31 The following data inside Main Stream is listed: In Main Stream number: 3 Stream flow area = 1.751 (Ac.) Runoff from this stream = 5.526(CFS) Time of concentration = 9.25 mm. Rainfall intensity = 4.606(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 10.300 5.85 6.188 2 14.434 7.46 5.294 3 5.526 9.25 4.606 Qmax(1) = 1.000 * 1.000 * 10.300) + 1.000 * 0.785 * 14.434) + 1.000 * 0.633 * 5.526) + = 25.128 Qmax(2) = 0.855 * 1.000 * 10.300) + 1.000 * 1.000 * 14.434) + 1.000 * 0.806 * 5.526) + = 27.699 Qmax(3) = 0.744 * 1.000 * 10.300) + 0.870 * 1.000 * 14.434) + 1.000 * 1.000 * 5.526) + = 25.753 Total of 3 main streams to confluence: Flow rates before confluence point: 10.300 14.434 5.526 Maximum flow rates at confluence using above data: 25.128 27.699 25.753 Area of streams before confluence: 2.593 4.316 1.751 Results of confluence: Total flow rate = 25.753(CFS) Time of concentration = 9.251 mm. Effective stream area after confluence = 8.660(Ac.) + +++ +++++++++ +++++++++++++++++++ +++++ +++++++ + +++++ +++++++ ++++++++++ + + + Process from Point/Station 324.000 to Point/Station 233.000 '''' PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 190.000(Ft.) Downstream point/station elevation = 182.830(Ft.) Pipe length = 75.00(Ft.) Slope = 0.0956 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 25.753(CFS) Nearest computed pipe diameter = 18.00(In.) Calculated individual pipe flow = 25.753(CFS) Normal flow depth in pipe = 12.09(In.) Flow top width inside pipe = 16.90 (In.) Critical depth could not be calculated. Pipe flow velocity = 20.38 (Ft/s) Travel time through pipe = 0.06 mm. Time of concentration (TC) = 9.31 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 233.000 to Point/Station 233.000 **** CONFLUENCE OF MAIN STREAMS The following data inside Main Stream is listed: In Main Stream number: 1 Stream flow area = 8.660(Ac.) Runoff from this stream = 25.753(CFS) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 15 of 31 Time of concentration = 9.31 mm. Rainfall intensity = 4.587(In/Hr) Program is now starting with Main Stream No. Process from Point/Station 231.000 to Point/Station 229.000 '''' INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (General Commercial Impervious value, Ai = 0.850 Sub-Area C Value = 0.800 Initial subarea total flow distance = 829.000(Ft,) Highest elevation = 230.600(Ft.) Lowest elevation = 193.300(Ft.) Elevation difference = 37.300(Ft.) Slope = 4.499 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 4.50 %, in a development type of General Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 3.10 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope"(1/3)] TC = f1.8*(1.1_0.8000)*( 90.000.5)/( 4.499(1/3)1= 3.10 The initial area total distance of 829.00 (Ft.) entered leaves a remaining distance of 739.00 (Ft.) Using Figure 3-4, the travel time for this distance is 4.17 minutes for a distance of 739.00 (Ft.) and a slope of 4.50 % with an elevation difference of 33.25(Ft.) from the end of the top area Tt = [11.9*length(Mi)3)/(elevation change(Ft.))J".385 *60(min/hr) = 4.169 Minutes Tt=[ (1l.9*0.l4003)/( 33.25)].385= 4.17 Total initial area Ti = 3.10 minutes from Figure 3-3 formula plus 4.17 minutes from the Figure 3-4 formula = 7.27 minutes Rainfall intensity (I) = 5.380(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.800 Subarea runoff = 5.057(CFS) Total initial stream area = 1.175(Ac.) +++++++++++++++++++.++.+++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 229.000 to Point/Station 230.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.320 (Ft.) Downstream point/station elevation = 185.010(Ft.) Pipe length = 15.85(Ft.) Slope = 0.0196 Manning's N 0.013 No. of pipes = 1 Required pipe flow 5.057(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 5.057(CFS) Normal flow depth in pipe = 6.49(In.) Flow top width inside pipe = 21.32 (In.) Critical Depth = 9.51 (In.) Pipe flow velocity = 7.38(Ftf s) Travel time through pipe = 0.04 mm. Time of concentration (TC) = 7.31 mm. Process from Point/Station 230.000 to Point/Station 230.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 2 in normal stream number 1 Stream flow area = 1.175(Ac.) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 16 of 31 Runoff from this stream = 5.057(CFS) Time of concentration = 7.31 mm. Rainfall intensity = 5.363 (In/Br) Process from Point/Station 231.000 to Point/Station 232.000 INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 [COMMERCIAL area type (General Commercial Impervious value, Ai = 0.850 Sub-Area C Value = 0.800 Initial subarea total flow distance = 840.000(Ft.) Highest elevation = 230.600(Ft.) Lowest elevation = 193.300(Ft.) Elevation difference = 37.300(Ft.) Slope = 4.440 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 90.00 (Ft) for the top area slope value of 4.44 %, in a development type of General Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration 3.12 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)1 TC = [1.8*(1.1_0.8000)*( 90.000A.5)/( 4.440"(1/3)1= 3.12 The initial area total distance of 840.00 (Ft.) entered leaves a remaining distance of 750.00 (Ft.) Using Figure 3-4, the travel time for this distance is 4.24 minutes for a distance of 750.00 (Ft.) and a slope of 4.44 % with an elevation difference of 33.30(Ft.) from the end of the top area Tt = [11.9*length(Mi)'3)/(elevation change(Ft.))]".385 *60(min/hr) = 4.238 Minutes Tt=[(l1.9*0.14203)/( 33.30)].385= 4.24 Total initial area Ti = 3.12 minutes from Figure 3-3 formula plus 4.24 minutes from the Figure 3-4 formula = 7.35 minutes Rainfall intensity (I) = 5.341(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.800 Subarea runoff = 3.444(CFS) Total initial stream area = 0.806 (Ac.) Process from Point/Station 232.000 to Point/Station 230.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 185.520 (Ft.) Downstream point/station elevation = 185.010 (Ft.) Pipe length = 51.15(Ft.) Slope = 0.0100 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.444(CFS) Given pipe size 18.00(In.) Calculated individual pipe flow = 3.444(CFS) Normal flow depth in pipe = 7.10(In.) Flow top width inside pipe = 17.59(In.) Critical Depth = 8.49(In.) Pipe flow velocity = 5.32(Ft/s) Travel time through pipe = 0.16 mm. Time of concentration (TC) = 7.52 mm. ++++++++++ + + ++++++++++ ++ +++ + ++++++++ + ++++++++ + ++++++++ + + Process from Point/Station 230.000 to Point/Station 230.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 2 in normal stream number 2 Stream flow area = 0.806 (Ac.) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 17 of 31 Runoff from this stream = 3.444(CFS) Time of concentration = 7.52 mm. Rainfall intensity = 5.267(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 5.057 7.31 5.363 2 3.444 7.52 5.267 Qmax(1) = 1.000 * 1.000 * 5.057) + 1.000 * 0.972 * 3.444) + = 8.406 Qmax(2) = 0.982 * 1.000 * 5.057) + 1.000 * 1.000 * 3.444) + = 8.411 Total of 2 streams to confluence: Flow rates before confluence point: 5.057 3.444 Maximum flow rates at confluence using above data: 8.406 8.411 Area of streams before confluence: 1.175 0.806 Results of confluence: Total flow rate = 8.411(CFS) Time of concentration = 7.515 mm. Effective stream area after confluence = 1.981(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 230.000 to Point/Station 233.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/Station elevation = 184.670 (Ft.) Downstream point/Station elevation = 182.990(Ft.) Pipe length = 115.65(Ft.) Slope = 0.0145 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 8.411(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 8.411(CFS) Normal flow depth in pipe = 9.15(In.) Flow top width inside pipe = 23.31(In.) Critical Depth = 12.39(m.) Pipe flow velocity = 7.65(Ft/s) Travel time through pipe = 0.25 mm. Time of concentration (TC) = 7.77 mm. Process from Point/Station 233.000 to Point/Station 233.000 **** CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 1.981 (Ac.) Runoff from this stream = 8.411(CFS) Time of concentration = 7.77 mm. Rainfall intensity = 5.156(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 25.753 9.31 4.587 2 8.411 7.77 5.156 Qmax(l) = 1.000 * 1.000 * 25.753) + 100 YR POST-DEVELOPMENT CILC (Outfall A) 4-28-15 Page 18 of 31 0.890 * 1.000 * 8.411) + = 33.234 Qmax(2) = 1.000 * 0.834 * 25.753) + 1.000 * 1.000 * 8.411) + = 29.890 Total of 2 main streams to confluence: Flow rates before confluence point: 25.753 8.411 Maximum flow rates at confluence using above data: 33.234 29.890 Area of streams before confluence: 8.660 1.981 Results of confluence: Total flow rate = 33.234(CFS) Time of concentration = 9.312 mm. Effective stream area after confluence = 10.641(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 233.000 to Point/Station 101.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.990(Ft.) Downstream point/station elevation = 180.860(Ft.) Pipe length = 200.00(Ft.) Slope = 0.0106 Manning's N = 0.013 No. of pipes = 1 Required pipe flow 33.234(CFS) Given pipe size = 30.00(In.) Calculated individual pipe flow = 33.234(CFS) Normal flow depth in pipe = 20.02 (In.) Flow top width inside pipe = 28.27(In.) Critical Depth = 23.53(In.) Pipe flow velocity = 9.55(Ft/s) Travel time through pipe = 0.35 mm. Time of concentration (TC) = 9.66 mm. Process from Point/Station 101.000 to Point/Station 101.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 1 Stream flow area = 10.641(Ac.) Runoff from this stream = 33.234(CFS) Time of concentration = 9.66 mm. Rainfall intensity = 4.479(In/Hr) Process from Point/Station 101.000 to Point/Station 101.000 **** USER DEFINED FLOW INFORMATION AT A POINT User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 6.077(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 6.02 mm. Rain intensity = 6.08(In/FIr) Total area = 0.100(Ac.) Total runoff = 0.383(CFS) Process from Point/Station 101.000 to Point/Station 101.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.100(Ac.) Runoff from this stream = 0.383(CFS) Time of concentration = 6.02 mm. Rainfall intensity = 6.077(In/Hr) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 19 of 31 Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 33.234 9.66 4.479 2 0.383 6.02 6.077 Qmax(l) = 1.000 * 1.000 * 33.234) + 0.737 * 1.000 * 0.383) + = 33.517 Qmax(2) = 1.000 * 0.623 * 33.234) + 1.000 * 1.000 * 0.383) + = 21.091 Total of 2 streams to confluence: Flow rates before confluence point: 33.234 0.383 Maximum flow rates at confluence using above data: 33.517 21.091 Area of streams before confluence: 10.641 0.100 Results of confluence: Total flow rate = 33.517(CFS) Time of concentration = 9.661 mm. Effective stream area after confluence 10.741 (Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 101.000 to Point/Station 102.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 180.860 (Ft.) Downstream point/station elevation = 180.160(Ft.) Pipe length = 166.00(Ft.) Slope = 0.0042 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 33.517(CFS) Given pipe size = 36.00(m.) Calculated individual pipe flow = 33.517(CFS) Normal flow depth in pipe = 23.77 (In.) Flow top width inside pipe = 34.10 (In.) Critical Depth = 22.56(In.) Pipe flow velocity = 6.76(Ft/s) Travel time through pipe = 0.41 mm. Time of concentration (TC) = 10.07 mm. + +++ ++ ++++ + ++++ + +++++ ++++++++++ +++++++++++ + ++++++ ++++ +++ + Process from Point/Station 102.000 to Point/Station 102.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 10.741(Ac.) Runoff from this stream = 33.517(CFS) Time of concentration 10.07 mm. Rainfall intensity = 4.361(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 102.000 to Point/Station 102.000 USER DEFINED FLOW INFORMATION AT A POINT **** User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 5.613(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 6.81 mm. Rain intensity = 5.61 (In/Hr) Total area = 0.157(Ac.) Total runoff = 0.520(CFS) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 20 of 31 Process from Point/Station 102.000 to Point/Station 102.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.157 (Ac.) Runoff from this stream = 0.520(CFS) Time of concentration = 6.81 mm. Rainfall intensity = 5.613(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 33.517 10.07 4.361 2 0.520 6.81 5.613 Qmax(1) = 1.000 * 1.000 * 33.517) + 0.777 * 1.000 * 0.520) + = 33.921 Qmax(2) = 1.000 * 0.676 * 33.517) + 1.000 * 1.000 * 0.520) + = 23.185 Total of 2 streams to confluence: Flow rates before confluence point: 33.517 0.520 Maximum flow rates at confluence using above data: 33.921 23.185 Area of streams before confluence: 10.741 0.157 Results of confluence: Total flow rate = 33.921(CFS) Time of concentration = 10.070 mm. Effective stream area after confluence = 10.898(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 102.000 to Point/Station 103.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 180.160(Ft.) Downstream point/station elevation = 179.780(Ft.) Pipe length = 91.00(Ft.) Slope = 0.0042 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 33.921(CFS) Given pipe size = 36.00(In.) Calculated individual pipe flow = 33.921(CFS) Normal flow depth in pipe = 24.07 (In.) Flow top width inside pipe = 33.89(In.) Critical Depth = 22.70 (In.) Pipe flow velocity = 6.75(Ft/s) Travel time through pipe = 0.22 mm. Time of concentration (TC) = 10.29 mm. Process from Point/Station 103.000 to Point/Station 103.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 10.898(Ac.) Runoff from this stream = 33.921(CFS) Time of concentration 10.29 mm. Rainfall intensity = 4.299(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 103.000 to Point/Station 103.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 21 of 31 User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 5.018(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 8.10 mm. Rain intensity = 5.02(In/Hr) Total area = 0.220(Ac.) Total runoff = 0.708(CFS) Process from Point/Station 103.000 to Point/Station 103.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.220 (Ac.) Runoff from this stream 0.708(CFS) Time of concentration = 8.10 mm. Rainfall intensity = 5.018(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 103.000 to Point/Station 103.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 4.028(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 11.39 mm. Rain intensity = 4.03(In/Hr) Total area = 5.290(Ac.) Total runoff = 14.190(CFS) ++++++++++++++++++++.+++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 103.000 to Point/Station 103.000 CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 3 Stream flow area = 5.290(Ac.) Runoff from this stream = 14.190(CFS) Time of concentration = 11.39 mm. Rainfall intensity = 4.028(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 33.921 10.29 4.299 2 0.708 8.10 5.018 3 14.190 11.39 4.028 Qmax(l) = 1.000 * 1.000 * 33.921) + 0.857 * 1.000 * 0.708) + 1.000 * 0.904 * 14.190) + = 47.353 Qmax(2) = 1.000 * 0.787 * 33.921) + 1.000 * 1.000 * 0.708) + 1.000 * 0.711 * 14.190) + = 37.488 Qmax(3) = 0.937 * 1.000 * 33.921) + 0.803 * 1.000 * 0.708) + 1.000 * 1.000 * 14.190) + = 46.538 Total of 3 streams to confluence: Flow rates before confluence point: 33.921 0.708 14.190 Maximum flow rates at confluence using above data: 47.353 37.488 46.538 Area of streams before confluence: 10.898 0.220 5.290 Results of confluence: Total flow rate = 47.353(CFS) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 22 of 31 Time of concentration = 10.295 mm. Effective stream area after confluence = 16.408(Ac.) Process from Point/Station 103.000 to Point/Station 104.000 "'" PIPEFLOW TRAVEL TIME (User specified size) Upstream point/station elevation = 179.780 (Ft.) Downstream point/station elevation = 179.430 (Ft.) Pipe length = 84.00(Ft.) Slope = 0.0042 Manning's N = 0.013 No. of pipes = 1 Required pipe flow 47.353(CFS) Given pipe size = 48.00(In.) Calculated individual pipe flow = 47.353(CFS) Normal flow depth in pipe 24.30(In.) Flow top width inside pipe = 48.00(In.) Critical Depth = 24.71(In.) Pipe flow velocity = 7.42(Ft/s) Travel time through pipe = 0.19 mm. Time of concentration (TC) = 10.48 mm. Process from Point/Station 104.000 to Point/Station 104.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 16.408 (Ac.) Runoff from this stream = 47.353(CFS) Time of concentration = 10.48 mm. Rainfall intensity = 4.249(In/Hr) Process from Point/Station 330.000 to Point/Station 331.000 **** INITIAL AREA EVALUATION **** Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.580 Initial subarea total flow distance = 49.000(Ft.) Highest elevation = 196.000(Ft.) Lowest elevation = 195.000(Ft.) Elevation difference = 1.000(Ft.) Slope = 2.041 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 80.00 (Ft) for the top area slope value of 2.04 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 6.60 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.5800)*( 80.000.5)/( 2.041(1/3)1= 6.60 Rainfall intensity (I) = 5.727(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.580 Subarea runoff = 0.262(CFS) Total initial stream area = 0.079(Ac.) ++++++++++++.+++++++.+++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 331.000 to Point/Station 332.000 IRREGULAR CHANNEL FLOW TRAVEL TIME Estimated mean flow rate at midpoint of channel = 0.676(CFS) Irregular Channel Data 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28.15 Page 23 of 31 ----------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.50 2 0.00 0.00 3 0.50 0.00 4 0.50 0.50 Manning's 'N' friction factor = 0.013 ----------------------------------------------------- Sub-Channel flow = 0.612(CFS) flow top width = 0.500(Ft.) velocity= 2.448(Ft/s) area = 0.250(Sq.Ft) Froude number = 0.610 Upstream point elevation = 195.000 (Ft.) Downstream point elevation = 194.390 (Ft.) Flow length = 122.000(Ft.) Travel time = 0.75 mm. Time of concentration = 7.35 mm. Depth of flow = 0.500(Ft.) Average velocity = 2.703(Ft/s) Total irregular channel flow = 0.676(CFS) Irregular channel normal depth above invert elev. = 0.500(Ft.) Average velocity of channel(s) = 2.703(Ft/s) Adding area flow to channel Rainfall intensity (I) = 5.342(In/Hr) for a 100.0 year storm User specified 'C' value of 0.580 given for subarea Rainfall intensity = 5.342(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.580 CA = 0.190 Subarea runoff = 0.754(CFS) for 0.249(Ac.) Total runoff = 1.016(CFS) Total area = 0.328(Ac.) Process from Point/Station 332.000 to Point/Station 333.000 PIPEFLOW TRAVEL TIME (User specified size) '''' Upstream point/station elevation = 186.740(Ft.) Downstream point/station elevation = 181.370(Ft.) Pipe length = 232.00(Ft.) Slope = 0.0231 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.016(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 1.016(CFS) Normal flow depth in pipe = 3.52 (In.) Flow top width inside pipe = 10.93(In.) Critical Depth = 5.08(In.) Pipe flow velocity = 5.29(Ft/s) Travel time through pipe = 0.73 mm. Time of concentration (TC) 8.08 mm. Process from Point/Station 333.000 to Point/Station 333.000 '' SUBAREA FLOW ADDITION Rainfall intensity (I) = 5.025(In/Hr) for a 100.0 year storm User specified 'C' value of 0.580 given for subarea Time of concentration 8.08 mm. Rainfall intensity = 5.025(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C 0.580 CA = 0.443 Subarea runoff = 1.208(CFS) for 0.435(Ac.) Total runoff = 2.224(CFS) Total area = 0.763(Ac.) Process from Point/Station 333.000 to Point/Station 104.000 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 24 of 31 PIPEFLOW TRAVEL TIME (User specified size) Upstream point/station elevation = 181.370 (Ft.) Downstream point/station elevation = 179.430 (Ft.) Pipe length = 13.00(Ft.) Slope = 0.1492 Mannings N = 0.013 No. of pipes = 1 Required pipe flow = 2.224(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 2.224(CFS) Normal flow depth in pipe = 3.26(In.) Flow top width inside pipe = 10.68(In.) Critical Depth = 7.65(In.) Pipe flow velocity = 12.87(Ft/s) Travel time through pipe = 0.02 mm. Time of concentration (TC) = 8.10 mm. Process from Point/Station 104.000 to Point/Station 104.000 **** CONFLUENCE OF MINOR STREAMS ''' Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.763 (Ac.) Runoff from this stream = 2.224(CFS) Time of concentration = 8.10 mm. Rainfall intensity = 5.019(In/Hr) +++++++++++..++++++++.++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 338.000 to Point/Station 339.000 ''' INITIAL AREA EVALUATION '''' Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 1.000 Decimal fraction soil group C = 0.000 Decimal fraction soil group D = 0.000 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.580 Initial subarea total flow distance = 94.000(Ft.) Highest elevation = 192.000(Ft.) Lowest elevation = 190.500(Ft.) Elevation difference = 1.500(Ft.) Slope = 1.596 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 80.00 (Ft) for the top area slope value of 1.60 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.16 minutes TC = (1.8*(1.1_C)*distance(Ft.)".5)/(% slope(1/3)1 TC = [1.8*(1.1_0.5800)*( 80.000.5)/( 1.596(1/3)J= 7.16 The initial area total distance of 94.00 (Ft.) entered leaves a remaining distance of 14.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.29 minutes for a distance of 14.00 (Ft.) and a slope of 1.60 % with an elevation difference of 0.22(Ft.) from the end of the top area Tt = (11.9*1ength(Mi)3)/(elevation change(Ft.))].385 *60(mmn/hr) 0.293 Minutes Tt=((11.9*0.00273)/( 0.22)1.385= 0.29 Total initial area Ti = 7.16 minutes from Figure 3-3 formula plus 0.29 minutes from the Figure 3-4 formula = 7.46 minutes Rainfall intensity (I) = 5.294(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.580 Subarea runoff = 0.405(CFS) Total initial stream area = 0.132 (Ac.) Process from Point/Station 339.000 to Point/Station 337.000 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 25 of 31 IRREGULAR CHANNEL FLOW TRAVEL TIME **** Estimated mean flow rate at midpoint of channel = 0.663(CFS) Depth of flow = 0.350(Ft.), Average velocity = 3.786(Ft/s) Irregular Channel Data *********** ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.50 2 0.00 0.00 3 0.50 0.00 4 0.50 0.50 Manning's 'N' friction factor = 0.013 ----------------------------------------------------------------- Sub-Channel flow = 0.663(CFS) flow top width = 0.500 (Ft.) velocity= 3.786(Ft/s) area = 0.175(Sq.Ft) Froude number = 1.128 Upstream point elevation = 190.500(Ft.) Downstream point elevation = 190.000 (Ft.) Flow length = 35.000(Ft.) Travel time = 0.15 mm. Time of concentration = 7.61 mm. Depth of flow = 0.350(Ft.) Average velocity = 3.786(Ft/s) Total irregular channel flow = 0.663(CFS) Irregular channel normal depth above invert elev. = 0.350(Ft.) Average velocity of channel(s) = 3.786(Ft/s) Adding area flow to channel Rainfall intensity (I) = 5.224(In/Hr) for a 100.0 year storm User specified 'C' value of 0.580 given for subarea Rainfall intensity = 5.224(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.580 CA = 0.174 Subarea runoff = 0.504(CFS) for 0.168(Ac.) Total runoff = 0.909(CFS) Total area = 0.300(Ac.) Depth of flow = 0.450(Ft.), Average velocity = 4.039(Ft/s) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 337.000 to Point/Station 340.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.080(Ft.) Downstream point/station elevation = 184.120(Ft.) Pipe length = 196.00(Ft.) Slope = 0.0100 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 0.909(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 0.909(CFS) Normal flow depth in pipe 4.13(In.) Flow top width inside pipe = 11.40(In.) Critical Depth = 4.79(In.) Pipe flow velocity = 3.79(Ft/s) Travel time through pipe = 0.86 mm. Time of concentration (TC) = 8.47 mm. Process from Point/Station 340.000 to Point/Station 340.000 SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 4.875(In/Hr) for a 100.0 year storm User specified 'C' value of 0.580 given for subarea Time of concentration = 8.47 mm. Rainfall intensity = 4.875(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.580 CA = 0.418 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 26 of 31 Subarea runoff = 1.127(CFS) for 0.420(Ac.) Total runoff = 2.036(CFS) Total area = 0.720(Ac.) Process from Point/Station 340.000 to Point/Station 104.000 '"' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 184.120(Ft.) Downstream point/station elevation = 179.430 (Ft.) Pipe length = 110.00(Ft.) Slope = 0.0426 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 2.036(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 2.036(CFS) Normal flow depth in pipe = 4.32 (In.) Flow top width inside pipe = 11.52 (In.) Critical Depth = 7.30(In.) Pipe flow velocity = 8.01 (Ft/s) Travel time through pipe = 0.23 mm. Time of concentration (TC) = 8.70 mm. ++ + ++++ +++++++++++++++++ + + ++++++ + + +++++++++ +++++ + +++++++++++++++ + + + Process from Point/Station 104.000 to Point/Station 104.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 3 Stream flow area = 0.720 (Ac.) Runoff from this stream = 2.036(CFS) Time of concentration = 8.70 mm. Rainfall intensity = 4.792(In/}1r) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 47.353 10.48 4.249 2 2.224 8.10 5.019 3 2.036 8.70 4.792 Qmax(1) = 1.000 * 1.000 * 47.353) + 0.847 * 1.000 * 2.224) + 0.887 * 1.000 * 2.036) + = 51.041 Qmax(2) = 1.000 * 0.773 * 47.353) + 1.000 * 1.000 * 2.224) + 1.000 * 0.931 * 2.036) + = 40.703 Qmax(3) = 1.000 * 0.830 * 47.353) + 0.955 * 1.000 * 2.224) + 1.000 * 1.000 * 2.036) + = 43.461 Total of 3 streams to confluence: Flow rates before confluence point: 47.353 2.224 2.036 Maximum flow rates at confluence using above data: 51.041 40.703 43.461 Area of streams before confluence: 16.408 0.763 0.720 Results of confluence: Total flow rate = 51.041(CFS) Time of concentration = 10.484 mm. Effective stream area after confluence = 17.891(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 104.000 to Point/Station 105.000 PIPEFLOW TRAVEL TIME (User specified size) **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4.28-15 Page 27 of 31 Upstream point/station elevation = 179.430(Ft.) Downstream point/station elevation = 179.240 (Ft.) Pipe length = 37.40(Ft.) Slope = 0.0051 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 51.041(CFS) Given pipe size = 48.00(m.) Calculated individual pipe flow = 51.041(CFS) Normal flow depth in pipe = 23.95(m.) Flow top width inside pipe = 48.00(In.) Critical Depth = 25.73(In.) Pipe flow velocity = 8.14(Ft/s) Travel time through pipe = 0.08 mm. Time of concentration (TC) = 10.56 mm. ++++++++ + +++++++ + +++++ + + +++++++ + + ++++++++++ + ++++++++ + Process from Point/Station 105.000 to Point/Station 106.000 IRREGULAR CHANNEL FLOW TRAVEL TIME Depth of flow = 1.167(Ft.), Average velocity = 2.937(Ft/s) Irregular Channel Data *********** ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 1.64 2 6.00 0.00 3 11.00 0.00 4 24.98 1.04 5 44.34 10.26 Manning's 'N' friction factor = 0.035 Sub-Channel flow = 51.041(CFS) flow top width = 23.513(Ft.) velocity= 2.937(Ft/s) area = 17.377(Sq.Ft) Froude number = 0.602 Upstream point elevation = 179.240(Ft.) Downstream point elevation 175.700 (Ft.) Flow length = 488.000(Ft.) Travel time = 2.77 mm. Time of concentration = 13.33 mm. Depth of flow = 1.167 (Ft.) Average velocity = 2.937(Ft/s) Total irregular channel flow = 51.041(CFS) Irregular channel normal depth above invert elev. = 1.167(Ft.) Average velocity of channel(s) = 2.937(Ft/s) ++++ + +++++ +++++ ++++ +++++ + +++++ +++++ ++ +++++++ +++++++ +++++ ++++ + Process from Point/Station 106.000 to Point/Station 106.000 CONFLUENCE OF MAIN STREAMS ''' The following data inside Main Stream is listed: In Main Stream number: 1 Stream flow area = 17.891 (Ac.) Runoff from this stream 51.041(CFS) Time of concentration = 13.33 mm. Rainfall intensity = 3.640(In/Hr) Program is now starting with Main Stream No. 2 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 75.000 to Point/Station 75.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 5.159(In/Hr) for a 100.0 year storm User specified values are as follows: 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 28 of 31 TC = 7.76 mm. Rain intensity = 5.16(In/Hr) Total area = 0.694(Ac.) Total runoff = 2.255(CFS) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 75.000 to Point/Station 75.000 '' SUBAREA FLOW ADDITION Rainfall intensity (I) = 5.159(In/Hr) for a 100.0 year storm User specified 'C' value of 0.580 given for subarea Time of concentration = 7.76 mm. Rainfall intensity = 5.159(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.611 CA = 0.685 Subarea runoff = 1.281(CFS) for 0.428(Ac.) Total runoff = 3.536(CFS) Total area = 1.122(Ac.) ++++++.+.++ + +++++++++++ ++++++++++++ + +++++++ ++++++++ + + + + + Process from Point/Station 75.000 to Point/Station 76.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 183.240 (Ft.) Downstream point/station elevation = 181.380(Ft.) Pipe length = 190.00(Ft.) Slope = 0.0098 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.536(CFS) Given pipe size = 12.00(In.) NOTE: Normal flow is pressure flow in user selected pipe size. The approximate hydraulic grade line above the pipe invert is 0.484(Ft.) at the headworks or inlet of the pipe(s) Pipe friction loss 1.871(Ft.) Minor friction loss = 0.472(Ft.) K-factor = 1.50 Pipe flow velocity = 4.50(Ft/s) Travel time through pipe = 0.70 mm. Time of concentration (TC) = 8.46 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 76.000 to Point/Station 76.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 2 in normal stream number 1 Stream flow area = 1.122(Ac.) Runoff from this stream = 3.536(CFS) Time of concentration = 8.46 mm. Rainfall intensity = 4.878(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 76.000 to Point/Station 76.000 **** USER DEFINED FLOW INFORMATION AT A POINT **** User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 3.740(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 12.78 mm. Rain intensity = 3.74 (In/Hr) Total area = 2.782(Ac.) Total runoff = 7.255(CFS) Process from Point/Station 76.000 to Point/Station 76.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 2 in normal stream number 2 Stream flow area = 2.782(Ac.) Runoff from this stream = 7.255(CFS) Time of concentration = 12.78 mm. Rainfall intensity = 3.740(In/Hr) Summary of stream data: 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 29 of 31 Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 3.536 8.46 4.878 2 7.255 12.78 3.740 Qmax(l) = 1.000 * 1.000 * 3.536) + 1.000 * 0.662 * 7.255) + = 8.341 Qmax(2) = 0.767 * 1.000 * 3.536) + 1.000 * 1.000 * 7.255) + = 9.966 Total of 2 streams to confluence: Flow rates before confluence point: 3.536 7.255 Maximum flow rates at confluence using above data: 8.341 9.966 Area of streams before confluence: 1.122 2.782 Results of confluence: Total flow rate = 9.966(CFS) Time of concentration = 12.780 mm. Effective stream area after confluence = 3.904 (Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 76.000 to Point/Station 106.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 181.380 (Ft.) Downstream point/station elevation = 180.640(Ft.) Pipe length = 45.00(Ft.) Slope = 0.0164 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 9.966(CFS) Given pipe size = 24.00(In.) Calculated individual pipe flow = 9.966(CFS) Normal flow depth in pipe = 9.70(In.) Flow top width inside pipe 23.56(In.) Critical Depth = 13.56(In.) Pipe flow velocity = 8.37(Ft/s) Travel time through pipe = 0.09 mm. Time of concentration (TC) = 12.87 mm. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 106.000 to Point/Station 106.000 '''' CONFLUENCE OF MAIN STREAMS **** The following data inside Main Stream is listed: In Main Stream number: 2 Stream flow area = 3.904 (Ac.) Runoff from this stream = 9.966(CFS) Time of concentration = 12.87 mm. Rainfall intensity = 3.723(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 51.041 13.33 3.640 2 9.966 12.87 3.723 Qmax(l) = 1.000 * 1.000 * 51.041) + 0.978 * 1.000 * 9.966) + = 60.784 Qmax(2) = 1.000 * 0.966 * 51.041) + 1.000 * 1.000 * 9.966) + = 59.247 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 30 of 31 Total of 2 main streams to confluence: Flow rates before confluence point: 51.041 9.966 Maximum flow rates at confluence using above data: 60.784 59.247 Area of streams before confluence: 17.891 3.904 Results of confluence: Total flow rate = 60.784(CFS) Time of concentration = 13.329 mm. Effective stream area after confluence = 21.795 (Ac.) End of computations, total study area = 21.795 (Ac.) 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 Page 31 of 31 San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software, (c) 1991-2012 Version 7.9 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 04/28/15 --------------------------------------------------------------- PLIU4NING AREA NO. 5 - RESORT SITE PHASE III 100 YEAR STORM POST-DEVELOPMENT Outfall A Continued Program License Serial Number 6312 ----------------------------------------------------------------- Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.500 P6/P24 = 57.8% San Diego hydrology manual 'C' values used Process from Point/Station 106.000 to Point/Station 106.000 USER DEFINED FLOW INFORMATION AT A POINT User specified 'C' value of 0.630 given for subarea Rainfall intensity (I) = 3.640(In/Hr) for a 100.0 year storm User specified values are as follows: TC = 13.33 mm. Rain intensity = 3.64 (In/Hr) Total area = 21.795(Ac.) Total runoff = 60.784(CFS) Process from Point/Station 106.000 to Point/Station 107.000 IRREGULAR CHANNEL FLOW TRAVEL TIME '''' Estimated mean flow rate at midpoint of channel = 60.823(CFS) Depth of flow 1.678(Ft.), Average velocity 3.965(Ft/s) Irregular Channel Data *********** ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 3.70 2 10.30 0.00 3 15.40 0.00 4 27.40 5.90 Manning's 'N' friction factor = 0.035 ----------------------------------------------------------------- Sub-Channel flow = 60.823(CFS) flow top width = 13.183(Ft.) velocity= 3.965(Ft/s) area = 15.338(Sq.Ft) Froude number = 0.648 Upstream point elevation = 175.700 (Ft.) Downstream point elevation = 173.260 (Ft.) Flow length = 320.000(Ft.) Travel time = 1.34 mm. Time of concentration = 14.67 mm. Depth of flow = 1.678(Ft.) Average velocity = 3.965(Ft/s) 100 YR POST-DEVELOPMENT CALC (Outfall A continued) 4-28-15 Page 1 of 2 Total irregular channel flow = 60.823(CFS) Irregular channel normal depth above invert elev. = 1.678(Ft.) Average velocity of channel(s) = 3.965(Ft/s) Adding area flow to channel Rainfall intensity (I) = 3.421(In/Hr) for a 100.0 year storm User specified C value of 0.580 given for subarea The area added to the existing stream causes a a lower flow rate of 0 = 47.418(CFS) therefore the upstream flow rate of Q = 60.784(CFS) is being used Rainfall intensity = 3.421(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.629 CA = 13.862 Subarea runoff = 0.000(CFS) for 0.226(Ac.) Total runoff = 60.784(CFS) Total area = 22.021(Ac.) Depth of flow = 1.677(Ft.), Average velocity = 3.965(Ft/s) End of computations, total study area = 22.021 (Ac.) 100 YR POST-DEVELOPMENT CALC (Outfall A continued) 4-28-15 Page 2 of 2 San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software, (C) 1991-2012 Version 7.9 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 04/28/15 PLANNING AREA NO. 5 - RESORT SITE PHASE III 100 YEAR STORM POST-DEVELOPMENT Outfall B Program License Serial Number 6312 ------------------------------------------------------------------- Rational hydrology study storm event year is 100.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.500 P6/P24 = 57.8% San Diego hydrology manual 'C' values used ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 400.000 to Point/Station 401.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 125.000(Ft.) Highest elevation = 196.000(Ft.) Lowest elevation = 193.000(Ft.) Elevation difference = 3.000(Ft.) Slope = 2.400 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 80.00 (Ft) for the top area slope value of 2.40 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 5.65 minutes TC = (1.8*(1.1_C)*distance(Ft.).5)/(% slope'(1/3)] TC = (1.8*(1.1_0.6300)*( 80.000.5)/( 2.400(1/3)1= 5.65 The initial area total distance of 125.00 (Ft.) entered leaves a remaining distance of 45.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.62 minutes for a distance of 45.00 (Ft.) and a slope of 2.40 % with an elevation difference of 1.08(Ft.) from the end of the top area Tt = (ll.9*length(Mi)'3)/(elevation change(Ft.))1'.385 *60(min/hr) = 0.615 Minutes Tt=( (ll.9*0.00853)/( 1.08)]A.385= 0.62 Total initial area Ti = 5.65 minutes from Figure 3-3 formula plus 0.62 minutes from the Figure 3-4 formula = 6.27 minutes Rainfall intensity (I) = 5.922(In/Hr) for a 100.0 year storm 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Page 1 of 7 Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.735(CFS) Total initial stream area = 0.197(Ac.) + ++ +++++++++ ++ ++ + + ++++++++ + + +++++++ ++++++++++ + +++++ + Process from Point/Station 401.000 to Point/Station 402.000 IRREGULAR CHANNEL FLOW TRAVEL TIME Estimated mean flow rate at midpoint of channel = 2.060(CFS) Depth of flow = 0.204(Ft.), Average velocity = 2.584(Ft/s) Irregular Channel Data *********** ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.31 2 16.50 0.13 3 18.00 0.00 4 19.50 0.13 5 44.00 0.63 Manning's 'N' friction factor = 0.015 ----------------------------------------------------------------- Sub-Channel flow = 2.060(CFS) flow top width = 13.359(Ft.) velocity= 2.584(Ft/s) area = 0.797(Sq.Ft) Froude number = 1.864 Upstream point elevation = 193.000 (Ft.) Downstream point elevation = 186.430 (Ft.) Flow length = 225.000(Ft.) Travel time = 1.45 mm. Time of concentration = 7.72 mm. Depth of flow = 0.204(Ft.) Average velocity = 2.584(Ft/s) Total irregular channel flow = 2.060(CFS) Irregular channel normal depth above invert elev. = 0.204(Ft.) Average velocity of channel(s) = 2.584(Ft/s) Adding area flow to channel Rainfall intensity (I) = 5.177(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Rainfall intensity = 5.177(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.642 Subarea runoff = 2.589(CFS) for 0.822(Ac.) Total runoff = 3.324(CFS) Total area = 1.019(Ac.) Depth of flow = 0.228(Ft.), Average velocity = 2.856(Ft/s) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 402.000 to Point/Station 403.000 ''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 182.680(Ft.) Downstream point/station elevation = 181.370(Ft.) Pipe length = 133.00(Ft.) Slope = 0.0098 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.324(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 3.324(CFS) Normal flow depth in pipe 9.25(In.) Flow top width inside pipe = 10.09(In.) Critical Depth = 9.37(In.) Pipe flow velocity = 5.12 (Ft/s) Travel time through pipe = 0.43 mm. 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Page 2 of 7 Time of concentration (TC) = 8.15 mm. Process from Point/Station 403.000 to Point/Station 403.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 4.998(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 8.15 mm. Rainfall intensity = 4.998(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.820 Subarea runoff = 0.776(CFS) for 0.283(Ac.) Total runoff = 4.100(CFS) Total area = 1.302(Ac.) +++++++ ++ + + + +++++++++ +++++++ +++++++ + ++++++ + ++++++ + ++++++++++++ ++ +++++ + Process from Point/Station 403.000 to Point/Station 404.000 '''' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 181.370(Ft.) Downstream point/station elevation = 180.000 (Ft.) Pipe length = 88.00(Ft.) Slope = 0.0156 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 4.100(CFS) Given pipe size 12.00(In.) Calculated individual pipe flow = 4.100(CFS) Normal flow depth in pipe = 9.09(In.) Flow top width inside pipe = 10.28(In.) Critical Depth = 10.27(In.) Pipe flow velocity = 6.42 (Ft/s) Travel time through pipe = 0.23 mm. Time of concentration (TC) = 8.38 mm. Process from Point/Station 404.000 to Point/Station 404.000 '''' SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 4.910(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 8.38 mm. Rainfall intensity = 4.910(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 1.130 Subarea runoff = 1.446(CFS) for 0.491(Ac.) Total runoff = 5.546(CFS) Total area = 1.793(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 404.000 to Point/Station 107.000 "'' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 177.000(Ft.) Downstream point/station elevation = 168.000(Ft.) Pipe length = 167.00(Ft.) Slope = 0.0539 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.546(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 5.546(CFS) Normal flow depth in pipe = 7.20 (In.) Flow top width inside pipe = 11.76(In.) Critical Depth = 11.29(In.) Pipe flow velocity = 11.29(Ft/s) Travel time through pipe = 0.25 mm. 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Page 3 of 7 Time of concentration (TC) = 8.63 mm. Process from Point/Station 107.000 to Point/Station 107.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 4.819(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 8.63 mm. Rainfall intensity = 4.819(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 1.363 Subarea runoff = 1.024(CFS) for 0.371(Ac.) Total runoff = 6.570(CFS) Total area = 2.164(Ac.) +++++ + + +++++++++++++++++ + + +++++++++ ++ + +++++++ + +++ + Process from Point/Station 107.000 to Point/Station 102.000 ''' PIPEFLOW TRAVEL TIME (User specified size) Upstream point/station elevation = 168.000(Ft.) Downstream point/Station elevation = 163.380(Ft.) Pipe length = 98.00(Ft.) Slope = 0.0471 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 6.570(CFS) Given pipe size = 18.00(m.) Calculated individual pipe flow = 6.570(CFS) Normal flow depth in pipe 6.62(m.) Flow top width inside pipe = 17.36(In.) Critical Depth = 11.90(m.) Pipe flow velocity = 11.16 (Ft/s) Travel time through pipe = 0.15 mm. Time of concentration (TC) = 8.77 mm. Process from Point/Station 102.000 to Point/Station 102.000 **** SUBAREA FLOW ADDITION '"' Rainfall intensity (I) = 4.767(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 8.77 mm. Rainfall intensity = 4.767(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 1.715 Subarea runoff = 1.608(CFS) for 0.559(Ac.) Total runoff = 8.177(CFS) Total area = 2.723(Ac.) Process from Point/Station 102.000 to Point/Station 102.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 2.723(Ac.) Runoff from this stream = 8.177(CFS) Time of concentration = 8.77 mm. Rainfall intensity = 4.767(In/Hr) Process from Point/Station 406.000 to Point/Station 407.000 INITIAL AREA EVALUATION **** 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Page 4 of 7 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 [MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 Initial subarea total flow distance = 59.000(Ft.) Highest elevation 197.000(Ft.) Lowest elevation = 192.300(Ft.) Elevation difference = 4.700(Ft.) Slope = 7.966 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 100.00 (Ft) for the top area slope value of 7.97 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration 4.24 minutes TC = [1.8*(1.1_C)*distance(Ft.)s.5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 100.000.5)/( 7.966(1/3)1= 4.24 Calculated TC of 4.236 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.630 Subarea runoff = 0.324(CFS) Total initial stream area = 0.075 (Ac.) Process from Point/Station 407.000 to Point/Station 408.000 IRREGULAR CHANNEL FLOW TRAVEL TIME Estimated mean flow rate at midpoint of channel = 1.208(CFS) Depth of flow = 0.377(Ft.), Average velocity = 2.839(Ft/s) Irregular Channel Data *********** ----------------------------------------------------------------- Information entered for subchannel number 1 Point number 'X' coordinate 'Y' coordinate 1 0.00 0.50 2 1.50 0.00 3 3.00 0.50 Manning's 'N' friction factor = 0.035 ----------------------------------------------------------- Sub-Channel flow = 1.208(CFS) flow top width = 2.260 (Ft.) velocity= 2.839(Ft/s) area = 0.426(Sq.Ft) Froude number = 1.153 Upstream point elevation = 192.300(Ft.) Downstream point elevation = 189.500(Ft.) Flow length = 63.000(Ft.) Travel time = 0.37 mm. Time of concentration = 4.61 mm. Depth of flow = 0.377(Ft.) Average velocity = 2.839(Ft/s) Total irregular channel flow = 1.208(CFS) Irregular channel normal depth above invert elev. = 0.377(Ft.) Average velocity of channel(s) = 2.839(Ft/s) Adding area flow to channel Calculated TC of 4.606 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Pages of 7 Rainfall intensity = 6.850(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.306 Subarea runoff = 1.769(CFS) for 0.410(Ac.) Total runoff = 2.093(CFS) Total area = 0.485(Ac.) Depth of flow = 0.463(Ft.), Average velocity = 3.257(Ft/s) +++++++++++++.+++ +++++.+ + + +++++++++++++++ ++ ++++ + Process from Point/Station 408.000 to Point/Station 102.000 ""' PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 186.500 (Ft.) Downstream point/station elevation = 163.380(Ft.) Pipe length = 249.00(Ft.) Slope = 0.0929 Manning's N 0.013 No. of pipes = 1 Required pipe flow = 2.093(CFS) Given pipe size = 12.00(In.) Calculated individual pipe flow = 2.093(CFS) Normal flow depth in pipe 3.57(In.) Flow top width inside pipe 10.97(In.) Critical Depth = 7.42 (In.) Pipe flow velocity = 10.68 (Ft/s) Travel time through pipe = 0.39 mm. Time of concentration (TC) = 4.99 mm. +++++++++++++++++ ++ +++++++++ + + + ++++ ++++++++++ + +++++++++++++++++ + +++++ + Process from Point/Station 102.000 to Point/Station 102.000 **** CONFLUENCE OF MINOR STREAMS Along Main Stream number: 1 in normal stream number 2 Stream flow area = 0.485(Ac.) Runoff from this stream = 2.093(CFS) Time of concentration = 4.99 mm. Rainfall intensity = 6.850(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Hr) 1 8.177 8.77 4.767 2 2.093 4.99 6.850 Qmax(l) = 1.000 * 1.000 * 8.177) + 0.696 * 1.000 * 2.093) + = 9.634 Qmax(2) = 1.000 * 0.569 * 8.177) + 1.000 * 1.000 * 2.093) + = 6.749 Total of 2 streams to confluence: Flow rates before confluence point: 8.177 2.093 Maximum flow rates at confluence using above data: 9.634 6.749 Area of streams before confluence: 2.723 0.485 Results of confluence: Total flow rate = 9.634(CFS) Time of concentration = 8.773 mm. Effective stream area after confluence = 3.208(Ac.) + + + ++++.+ +++++++ + +++++++++++++++++ ++ + + + +++ + 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Page 6 of 7 Process from Point/Station 102.000 to Point/Station 103.000 PIPEFLOW TRAVEL TIME (User specified size) **** Upstream point/station elevation = 163.210 (Ft.) Downstream point/station elevation = 162.500 (Ft.) Pipe length = 37.46(Ft.) Slope = 0.0190 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 9.634(CFS) Given pipe size = 18.00(In.) Calculated individual pipe flow = 9.634(CFS) Normal flow depth in pipe = 10.73(In.) Flow top width inside pipe = 17.66(In.) Critical Depth = 14.39(In.) Pipe flow velocity = 8.76(Ft/s) Travel time through pipe = 0.07 mm. Time of concentration (TC) = 8.84 mm. Process from Point/Station 103.000 to Point/Station 103.000 SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 4.742(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 8.84 mm. Rainfall intensity = 4.742(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 2.659 Subarea runoff = 2.973(CFS) for 1.012(Ac.) Total runoff = 12.607(CFS) Total area = 4.220(Ac.) End of computations, total study area = 4.220 (Ac.) 100 YR POST-DEVELOPMENT CALC (Outall B) 4-28-15 Page 7 of 7 Attachment F Storm Drain Calculations 14wrirnfinw Sfrrm Rowara Fv+nirin fnr AiifneimaknR A,.toCAD® Civil 3D® Plan 13 4 10 iber of lines: 13 Date: 10130/2015 'm So 40 ycuI3r 'e Line (ompations _e I Line Size Q Downstream Len Upstream Check JL Minor ------oeff loss Invert HGL Depth Area Val Val EGL Sf Invert HGL Depth Area Val Val EGL St Ave Enrgy elev elev head elev elev elev head elev St loss (in) (cfs) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (ft) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (%) (ft) (K) (ft) 1 18 12.00 199.50 202.00 1.50 1.64 6.79 0.72 202.72 1.306 25.000 201.17 202.48 1.31** 1.64 7.32 0.83 203.32 1.182 1.244 n/a 0.36 0.30 2 12 8.64 201.19 202.48 1.00 0.79 11.00 1.88 204.37 5.889 50.340 203.20 205.45 1.00 0.79 11.00 1.88 207.33 5.886 5.887 2.964 1.00 1.88 3 12 5.50 203.20 207.33 1.00 0.79 7.00 0.76 208.09 2.385 46.000 204.13 208.43 1.00 0.79 7.00 0.76 209.19 2.384 2.385 1.097 0.51 0.39 4 12 4.87 204.23 208.82 1.00 0.75 6.20 0.60 209.41 1.871 110.83 213.85 214.76j 0.91** 0.75 6.49 0.66 215.41 1.634 1.752 n/a 0.88 n/a 5 12 4.73 203.20 207.33 1.00 0.75 6.02 0.56 207.89 1.765 142.84 208.91 209.81 0.90** 0.75 6.35 0.63 210.44 1.552 1.658 n/a 0.34 n/a 6 12 3.54 208.97 209.81 0.84 0.68 5.02 0.43 210.24 0.000 133.00 212.95 213.75j 0.80** 0.68 5.24 0.43 214.18 0.000 0.000 n/a 1.00 n/a 7 12 2.44 214.02 214.76 0.74 0.56 3.92 0.30 215.06 0.000 73.550 214.76 215.43j 0.67** 0.56 4.37 0.30 215.73 0.000 0.000 n/a 0.87 0.26 8 12 1.83 214.76 215.43 0.67 0.47 3.28 0.24 215.67 0.000 54.610 215.31 215.89j 0.58** 0.47 3.91 0.24 216.12 0.000 0.000 n/a 0.52 0.12 9 12 1.22 215.31 215.89 0.58 0.36 2.61 0.18 216.07 0.000 83.750 216.15 216.62j 0.47** 0.36 3.40 0.18 216.80 0.000 0.000 n/a 0.43 0.08 10 12 0.61 216.15 216.62 0.47 0.22 1.70 0.12 216.73 0.000 106.11 217.21 217.53j 0.32** 0.22 2.76 0.12 217.65 0.000 0.000 n/a 1.00 n/a 11 12 2.43 214.02 214.76 0.74 0.56 3.91 0.30 215.06 0.000 87.340 214.91 215.58j 0.67** 0.56 4.37 0.30 215.87 0.000 0.000 n/a 0.41 0.12 12 12 1.62 214.91 215.58 0.67 0.43 2.91 0.22 215.80 0.000 88.840 215.79 216.33j 0.54 0.43 3.74 0.22 216.55 0.000 0.000 n/a 0.42 n/a 13 12 0.81 215.79 216.33 0.54 0.27 1.87 0.14 216.47 0.000 184.29 217.64 218.02j 0.38** 0.27 3.00 0.14 218.16 0.000 0.000 n/a 1.00 0.14 Project File: Line A - J - K.stm -T--Number of lines: 13 Run Date: 10/30/2015 Notes: -- Critical depth.; j-Line contains hyd. jump. ; c = cir e = ellip b = box Storm Sewers v10. - - - .,tn SMNeVOP rdlWb - - - - - - — — — — — — = — — — = of - — — - — - — = -- - — —— — - — — — - — - - — — — - — — — - — -- - - — - ---- V _. !- -f----- - 1M'I' Storm Sewers I. I. _.. i. _•I I. I. _.. I. _.I I. I i. II - ____ _______ U -•• !- ____i.___ -___---_______w__. - -U -U -U -. -U -U -U -. - U -.----____--_-------- I Hydraflow HGL Computation Procedure General Procedure: Hydraflow Computes the HGL using the Bernoulli energy equation. Manning's equation is used to determine energy losses due to pipe friction. In a standard step, iterative procedure, Hydraflow assumes upstream HGLs until the energy equation balances. If the energy equation cannot balance, supercritical flow exists and critical depth is temporarily assumed at the upstream end. A supercritical flow Profile is then computed using the same procedure in a downstream direction using momentum principles. Col. I The line number being computed. Calculations begin at Line I and proceed upstream. Col. 2 The line size. In the case of non-circular pipes, the line rise is printed above the span. Col. 3 Total flow rate in the line. Col. 4 The elevation of the downstream invert. Col. 5 Elevation of the hydraulic grade line at the downstream end. This is computed as the upstream HGL + Minor loss of this line's downstream line. Col. 6 The downstream depth of flow inside the pipe (HGL - Invert elevation) but not greater than the line size. Col. 7 Cross-sectional area of the flow at the downstream end. Col. 8 The velocity of the flow at the downstream end, (Col. 3/ Col. 7). Col. 9 Velocity head (Velocity squared I 2g). Col. 10 The elevation of the energy grade line at the downstream end, HGL + Velocity head, (Col. 5 + Col. 9). Col. 11 The friction slope at the downstream end (the S or Slope term in Manning's equation). Col. 12 The line length. Col. 13 The elevation of the upstream invert. Col. 14 Elevation of the hydraulic grade line at the upstream end. Col. 15 The upstream depth of flow inside the pipe (HGL - Invert elevation) but not greater than the line size. Col. 16 Cross-sectional area of the flow at the upstream end. Col. 17 The velocity of the flow at the upstream end, (Col. 3 I Col. 16). Col. 18 Velocity head (Velocity squared / 29). Col. 19 The elevation of the energy grade line at the upstream end, HGL + Velocity head, (Col. 14 + Col. 18). Col. 20 The friction slope at the upstream end (the S or Slope term in Manning's equation). Col. 21 The average of the downstream and upstream friction slopes. Col. 22 Energy loss. Average S9100 x Line Length (Col. 21/100 x Col. 12). Equals (EGL upstream - EGL downstream) +1- tolerance. Col. 23 The junction loss coefficient (K). Col. 24 Minor loss. (Col. 23 x Col. 18). Is added to upstream HGL and used as the starting HGL for the next upstream line(s). Page 1 Storm Line 9M 10 B-4 B-I Project File: Storm Line B.stm Number of lines: 10 I Date: 10/30/2015 Storm Sewers vi 0.40 Hydraulic Grade Line Computations Page 1 Line Size Q Downstream Len Upstream Check JL Minor coeff loss Invert HGL Depth Area Vel Vel EGL Sf Invert HGL Depth Area Vel Vel EGL Sf Ave Enrgy elev elev head cloy elev elev head elev Sf loss (in) (cfs) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (ft) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (%) (ft) (K) (ft) 1 30 25.93 182.99 188.10 2.50 3.63 5.28 0.43 188.53 0.400 75.540 190.00 191.73j 1.73 3.63 7.14 0.79 192.53 0.584 0.492 n/a 1.00 0.79 2 18 13.20 194.48 195.29 0.81* 0.97 13.62 0.96 196.25 0.000 40.770 196.50 197.86 1.36** 1.68 7.85 0.96 198.82 0.000 0.000 n/a 1.00 0.96 3 18 8.81 190.02 191.73 1.50 1.77 4.99 0.39 192.12 0.704 51.140 190.28 192.09 1.50 1.77 4.99 0.39 192.48 0.704 0.704 0.360 1.00 0.39 4 18 5.05 190.03 191.73 1.50 1.05 2.86 0.13 191.86 0.231 369.77 209.12 209.98j 0.86** 1.05 4.79 0.36 210.34 0.582 0.406 n/a 1.00 0.36 5 12 5.05 209.16 209.98 0.82 0.69 7.29 0.69 210.68 0.000 18.270 209.75 210.67 0.92** 0.76 6.69 0.69 211.36 0.000 0.000 n/a 0.44 0.31 6 12 5.05 209.75 210.67 0.92 0.76 6.69 0.69 211.36 0.000 100.82 212.46 213.38 0.92** 0.76 6.69 0.69 214.07 0.000 0.000 n/a 1.00 0.69 7 12 1.71 213.04 213.40 0.36* 0.25 6.71 0.23 213.63 0.000 72.660 215.22 215.78 0.56** 0.45 3.82 0.23 216.00 0.000 0.000 n/a 1.00 n/a 8 12 3.58 212.46 213.38 0.92 0.68 4.74 0.43 213.81 0.000 81.250 214.72 215.531 0.81** 0.68 5.27 0.43 215.96 0.000 0.000 n/a 0.75 0.32 9 12 3.58 214.72 215.53 0.81 0.68 5.27 0.43 215.96 0.000 118.93 218.02 218.83 0.81** 0.68 5.27 0.43 219.26 0.000 0.000 n/a 0.75 0.32 10 12 3.58 218.02 218.83 0.81 0.68 5.27 0.43 219.26 0.000 27.990 218.80 219.61 0.81** 0.68 5.27 0.43 220.04 0.000 0.000 n/a 1.00 0.43 Storm Line B Number of lines: 10 Run Date: 10/30/2015 Notes: * Normal depth assumed.; ** Critical depth.; j-Line contains hyd. jump. ; c = dr e = ellip b = box torm 5 O. i rr Pi : S Line n - O. gc(I) oaa CD ;co Elev.(ft) 0 LU C43HuujiIj .E> SE>> coOS 252.00 -t- - C as CQO. IC - 0 - CQO C - CO.S C - caO.E . - C a - O - '1010 00(D CICI *IC ' a ?gg 8 i8 pa go to N CM CM CM LU a ui Li'! C4 C%lc%l .,iIiii .oiiiiii it 0 LLE Ls -L i -252.00 236.00 220.00 204.00 188.00 172.00 I I I I I I I I I I I I I 172.00 0 50 100 150 200 250 300 350 400 450 500 550 600 650 700 750 800 HGL EGL Reach (ft) Storm Sewers storm Sewer Prome Proj. file: Storm Line B.stm 185.00 177.00 0 10 20 30 HGL EGL 40 50 60 70 80 90 100 110 120 Reach (ft) Elev. (ft) 201.00 217.00 209.00 193.00 177.00 130 torm,sewers 217.00 209.00 201.00 193.00 185.00 tn MNdPPrdfflb P1 .e: S Line n - . - - — - — - - — - - - — - - — - — - — - - ----- I — - - - I — 1I:J,1I - I- I- a- I, 1. S A' I' •I' Storm 11 Hydraflow Storm Sewers Extension for Autodesk® AutoCAD® Civil 3D® Plan 6 8 LINE C-6 !t NE-8 z 4C? m7 C.) C) S., 2 10 LINE C-2 LINE c-ic? ci 14 Outfall Project File: Storm Line C.stm Number of lines: 10 Date: 10/30/2015 m Se lycrramulic Gre Line Computations Line Size Q Downstream Len Upstream Check JL Minor -oeff loss Invert HGL Depth Area Vol Vol EGL Sf Invert HGL Depth Area Vol Vol EGL Sf Ave Enrgy elev elev head elev elev elev head elev Sf loss (in) (cfs) (ft) (ft) (It) (sqft) (ftls) (ft) (ft) (%) (It) (ft) (It) (It) (sqft) (ttls) (It) (It) (%) (%) (It) (K) (It) 1 24 5.45 193.50 195.00 1.50 1.22 2.16 0.31 195.31 0.000 105.42 194.03 194.85 0.82** 1.22 4.47 0.31 195.16 0.000 0.000 n/a 0.90 0.28 2 24 5.45 194.05 194.85 0.80 1.18 4.62 0.31 195.16 0.000 47.130 201.28 202.10 0.82** 1.22 4.47 0.31 202.41 0.000 0.000 n/a 0.41 0.13 3 12 3.97 201.30 202.10 0.80 0.68 5.87 0.49 202.59 0.000 47.130 202.32 203.16 0.84** 0.71 5.61 0.49 203.65 0.000 0.000 n/a 0.55 0.27 4 12 2.79 202.34 203.43 1.00 0.79 3.55 0.20 203.63 0.614 78.020 202.73 203.91 1.00 0.79 3.55 0.20 204.11 0.614 0.614 0.479 1.00 0.20 5 12 1.23 202.75 204.11 1.00 0.36 1.57 0.04 204.15 0.119 51.100 205.00 205.47j 0.47** 0.36 3.41 0.18 205.65 0.601 0.360 n/a 1.00 0.18 6 12 1.66 202.74 204.11 1.00 0.79 2.11 0.07 204.18 0.217 104.82 203.28 204.34 1.00 0.79 2.11 0.07 204.41 0.217 0.217 0.228 1.00 0.07 7 12 0.84 203.28 204.41 1.00 0.28 1.07 0.02 204.42 0.056 30.690 206.98 207.36j 0.38** 0.28 3.03 0.14 207.51 0.574 0.315 n/a 1.00 0.14 8 12 0.82 203.28 204.41 1.00 0.79 1.04 0.02 204.42 0.053 15.000 203.36 204.41 1.00 0.79 1.04 0.02 204.43 0.053 0.053 0.008 1.00 0.02 9 12 0.82 203.37 204.43 1.00 0.79 1.04 0.02 204.45 0.053 85.000 203.80 204.47 0.67 0.56 1.46 0.03 204.51 0.084 0.068 0.058 1.00 0.03 10 12 0.82 203.82 204.51 0.69 0.57 1.43 0.03 204.54 0.080 36.830 204.00 204.53 0.53 0.42 1.95 0.06 204.59 0.177 0.128 0.047 1.00 0.06 Project File: Storm Line C.stm Number of lines: 10 FRun'Date: 10/30/2015 Notes:; Critical depth.; j-Line contains hyd. jump. ; c = cir e = ellip b = box Storm Sewers 00. 220.00 212.00 204.00 196.00 co Elev. (ft) a.5W 228.00 0 Co F0 . Gi Ic,1 WLU ('3 E 228.00 220.00 212.00 204.00 2" @ 0.49% 196.00 _L L storm sewer Prome Proj. file: Storm Line C.stm 188.00 1 1 1 I I I 1 1 1 1 I 188.00 0 50 100 150 200 250 300 350 400 450 500 550 HGL EGL Reach (ft) - - - - - - - - - - - - - - - - torm oewerS ...,t1 NG'F Pr : St .me Etev.(ft) OM O(VIg) 'op-) I- 8oeicii ii:ijjjuj C Qa - 224.00 224.00 - - _________ ____________ ____________ ___________ ____________ __________ -219.00 __________ 219.00 - - ________ ___________ ___________ __________ ___________ _________ -214.00 214.00 - - - - 209.00 ___ _____ 209.0C - 204.00 L - _________ ____________ ____________ ____________ __________ - _______ ____________ ____________ ____________ - 204.00 -199.00 ______ ______ - _____ ______ ______ ______ 199.00 - __________ __________ __________ __________ __________ __________ 0 10 20 30 40 50 60 70 80 90 100 HGL EGL Reach (ft) Storm Sewers 220.00 216.00 212.00 208.00 204.00 Elev. (ft) 220.00 216.00 212.00 208.00 204.00 storm Sewer Frome Proj. file: Storm Line C.stm 1-. .- 50 200.00 ' I I I I I I 1 200.00 0 10 20 30 40 50 60 70 80 90 100 HOL EGL Reach (ft) Lonii oewerS Jl'!L uutraui I Project File: LINE L.stm I Number of lines: 5 1 Date: 10/30/2015 I Storm Sewers v1U.4U Hydraulic Grade Line Computations Page 1 Line Size Q Downstream Len Upstream Check JL Minor ------.--:oeff loss Invert H Depth Area Vel Val EGL Sf Invert HGL Depth Area Val Vol EGL Sf Ave Enrgy dcv, elev head elev elev elev head elev Sf loss (in) (cfs) (ft) (ft) (ft) (sqft) (ft!s) (ft) (ft) (%) (ft) (ft) (ft) (ft) (sqft) (ft.Is) (ft) (ft) (%) (%) (ft) (K) (ft) 1 8 2.36 181.26 181.90 0.64 0.35 6.83 0.73 182.63 3.348 10.810 181.37 182.31 0.67 0.35 6.76 0.71 183.02 3.819 3.583 0.387 1.00 0.71 2 8 1.10 181.37 183.02 0.67 0.35 3.15 0.15 183.17 0.830 102.25 182.39 183.87 0.67 0.35 3.15 0.15 184.02 0.830 0.830 0.848 0.48 0.07 3 6 1.10 182.56 183.94 0.50 0.20 5.60 0.49 184.43 3.850 52.840 183.09 185.97 0.50 0.20 5.60 0.49 186.46 3.849 3.849 2.034 0.52 0.25 4 6 1.10 183.09 186.23 0.50 0.20 5.60 0.49 186.72 3.850 76.460 186.91 189.17 0.50 0.20 5.60 0.49 189.66 3.849 3.849 2.943 1.00 0.49 5 6 1.27 181.54 183.02 0.50 0.20 6.45 0.65 183.66 5.100 9.660 185.87 186.36j 0.49** 0.20 6.49 0.65 187.01 4.538 4.819 n/a 1.00 0.65 LINE L Number of lines: 5 Run Date: 10/30/2015 Notes: ** Critical depth.; j-Line contains hyd. jump. ; C = cir e = ellip b = box Lorm 6 ~ MARK t I ic rd 'roj. .INE_.n 8cE C O. CctO.E 0 - ' ,.... -' C..1 - - c ?— l) 0oicu 0 CD Elev.(ft) 8j i!02 U2 6 El C3 .jjj t 5 IUW .E> SE>> in O..S wO.E U3 w Ir in 203.00 - - ________ __________ ___________ ___________ _____ — ___________ ______ — __________ ___________ _______ — - 203.00 198.00 - - ________ _________ __________ __________ _____ - __________ ______ — __________ __________ ______ - - 198.00 193.00 - - — __________ ______ - __________ __________ ______ — - 193.00 188.00 - ___ ______ ___ ___ ___ - 188.00 183.00 - . ___ — - ___ - 183.00 ------ ___________ - -_at _ .MLI I -ijj 1-00% 7 00% 178.00 - 1U.1U 1-b1.UCYo —178.00 0 25 50 75 100 125 150 175 200 225 250 HGL - EGL Reach (ft) Storm Si storm sewer Prome Proj. file: LINE L.stm 19 10 - pO.S 0 10 20 30 40 50 60 70 80 90 HGL EGL Reach (ft) 178.00 0 198.00 194.00 190.00 186.00 182.00 178.00 100 - torm sewers Elev. (ft) 198.00 194.00 190.00 186.00 182.00 .JIM Project File: LINE M.stm Number of lines: 5 I Date: 1013012015 Storm Sewers vi 0.40 Page I Hydraulic Grade Line Computations Line Size Q Downstream Len Upstream Check JL Minor oeff loss Invert HGL Depth Area Vel Vel EGL Sf Invert HGL Depth Area Vel Vel EGL St Ave Enrgy elev elev head elev elev elev head elev Sf loss (in) (cfs) (ft) (if) (ft) (sqft) (ftls) (if) (ft) (%) (ft) (if) (ft) (if) (sqft) (ftls) (ft) (ft) (%) (%) (if) (K) (ft) 1 8 2.08 183.04 183.67 0.63 0.34 6.08 0.58 184.25 2.566 26.230 183.30 184.42 0.67 0.35 5.96 0.55 184.97 2.966 2.766 0.726 0.72 0.40 2 8 2.08 183.30 184.82 0.67 0.35 5.96 0.55 185.37 2.967 82.140 184.12 187.25 0.67 0.35 5.96 0.55 187.81 2.966 2.967 2.437 0.40 0.22 3 8 0.93 183.87 187.48 0.67 0.35 2.66 0.11 187.59 0.593 41.810 184.29 187.72 0.67 0.35 2.66 0.11 187.83 0.593 0.593 0.248 0.40 0.04 4 8 0.93 184.29 187.77 0.67 0.35 2.66 0.11 187.88 0.593 114.64 185.44 188.45 0.67 0.35 2.66 0.11 188.56 1 188.84 0.593 0.593 0.39 0.04 5 8 0.93 185.44 188.49 0.67 0.35 2.66 0.11 188.60 0.593 39.620 185.84 188.73 0.67 0.35 1 2.66 0.11 0.593 0.593 10,680 0.235 1.00 0.11 LINE M Number of lines: 5 Run Date: 10/30/2015 c=cir e=ellip b=box torm 1 10.. Hydraflow Storm Sewers Extension for Autodesk® AutoCAD® Civil 3138 Plan Project File: Storm Line Estm Number of lines: 4 I Date: 1013012015 rm Se 40 Uti wc rdfflb Pi ,. ...3: S,--.... _ine _._-. n Cl CD cO.E c O.E C•2o. 5 O Elev. (ft) 192.00 192.00 189.00 189.00 186.00 186.00 183.00 183.00 180.00 180.00 177.00 177.00 0 25 50 75 100 125 150 175 200 225 HGL EGL Reach (ft) 1AiAI U I'RLMA 11 Storm jEE ; IL: ._ -----_-_ Hydraulic Grade Line Computations Page 1 Line Size Q Downstream Len Upstream Check JL Minor coeff loss Invert H Depth Area Vel Vel EGL Sf Invert HGL Depth Area Vel Vel EGL Sf Ave Enrgy elev elev head elev elev elev head elev Sf loss (in) (cts) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (ft) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (%) (ft) (K) (ft) 1 18 4.10 180.00 182.00 1.50 1.77 2.32 0.08 182.08 0.153 35.800 180.18 182.05 1.50 1.77 2.32 0.08 182.14 0.152 0.152 0.055 0.45 0.04 2 18 4.10 180.18 182.09 1.50 1.77 2.32 0.08 182.18 0.153 45.200 180.41 182.16 1.50 1.77 2.32 0.08 182.24 0.152 0.152 0.069 0.56 0.05 3 12 3.32 180.42 182.21 1.00 0.79 4.23 0.28 182.49 0.869 76.020 180.80 182.87 1.00 0.79 4.23 0.28 183.15 0.869 0.869 0.661 0.75 0.21 4 12 3.32 180.80 183.08 1.00 0.79 4.23 0.28 183.36 0.869 54.290 181.07 183.55 1.00 0.79 4.23 0.28 183.83 0.869 0.869 0.472 1.00 0.28 Project File: Storm Line E.stm Number of lines: 4 Run Date: 10/30/2015 c=cir e=ellip b=box torm C, 0.' iyffl%flaW H. MbpEbtifflF Pee General Procedure: Hydrafiow computes the HGL using the Bernoulli energy equation. Manning's equation is used to determine energy losses due to pipe friction. In a standard step, iterative procedure, Hydrafiow assumes upstream HGLs until the energy equation balances. If the energy equation cannot balance, supercritical flow exists and critical depth is temporarily assumed at the upstream end. A supercritical flow Profile is then computed using the same procedure in a downstream direction using momentum principles. Col. I The line number being computed. Calculations begin at Line I and proceed upstream. Col. 2 The line size. In the case of non-circular pipes, the line rise is printed above the span. Col. 3 Total flow rate in the line. Col. 4 The elevation of the downstream invert. Col. 5 Elevation of the hydraulic grade line at the downstream end. This is computed as the upstream HGL + Minor loss of this line's downstream line. Col. 6 The downstream depth of flow inside the pipe (HGL - Invert elevation) but not greater than the line size. Col. 7 Cross-sectional area of the flow at the downstream end. Col. 8 The velocity of the flow at the downstream end, (Col. 3 I Col. 7). Col. 9 Velocity head (Velocity squared / 2g). Col. 10 The elevation of the energy grade line at the downstream end, HGL + Velocity head, (Col. 5 + Col. 9). Col. 11 The friction slope at the downstream end (the S or Slope term in Manning's equation). Col. 12 The line length. Col. 13 The elevation of the upstream invert. Col. 14 Elevation of the hydraulic grade line at the upstream end. Col. 15 The upstream depth of flow inside the pipe (HGL - Invert elevation) but not greater than the line size. Col. 16 Cross-sectional area of the flow at the upstream end. Col. 17 The velocity of the flow at the upstream end, (Col. 3/ Col. 16). Col. 18 Velocity head (Velocity squared / 2g). Col. 19 The elevation of the energy grade line at the upstream end, HGL + Velocity head, (Col. 14 + Col. 18). Col. 20 The friction slope at the upstream end (the S or Slope term in Manning's equation). Col. 21 The average of the downstream and upstream friction slopes. Col. 22 Energy loss. Average S9100 x Line Length (Col. 21/100 x Col. 12). Equals (EGL upstream - EGL downstream) +1- tolerance. Col. 23 The junction loss coefficient (K). Col. 24 Minor loss. (Col. 23 x Col. 18). Is added to upstream HGL and used as the starting HGL for the next upstream line(s). PL,_ - LINE F Outfall Project File: LINE F.stm Number of lines: 2 I Date: 10130/2015 M Se H'ydrauUi3rae Line Computations Line Size Q Downstream Len Upstream Check JL ;oeff Minor loss Invert HGL Depth Area Val Vol EGL St Invert HGL Depth Area Vol Vol EGL Ave Enrgy elev elev head elev elev elev, head elev JSf St loss (in) (cfs) (ft) (ft) (ft) (sqft) (ttls) (ft) (ft) (%) (ft) (It) (ft) (ft) (sqft) (ILls) (ft) (ft) (%) (%) (It) (K) (ft) 1 12 2.09 180.25 182.00 1.00 0.79 2.66 0.11 182.11 0.345 12.660 180.69 182.04 1.00 0.79 2.66 0.11 182.15 0.344 0.345 0.044 0.70 0.08 2 12 2.09 180.69 182.12 1.00 0.51 2.66 0.11 182.23 0.345 169.94 186.50 187.12j 0.62** 0.51 4.11 0.26 187.38 0.701 0.523 n/a 1.00 0.26 LINE F bar oflines: 2 Run Date: 10/30/2015 Notes: Critical depth.; j-Line contains hyd. jump. ; c = cir e = ellip b = box Storm Sewers vlO.' storm sewer Prome Proj. file: LINE F.stm • I- I- I- v.ii'ii 25 50 75 100 125 150 175 HGL EGL Reach (ft) Elev. (ft) 201.00 196.00 191.00 186.00 181.00 176.00 0 201.00 196.00 191.00 186.00 181.00 -'--- 176.00 200 - _1 à(orm otmuis LING Outfall I Project File: LINE G.stm I Number of lines: 1 1 Date: 10/30/2015 I Storm Sewers vi 0.40 Hydraulic Grade Line Computations Page 1 Line - Size (in) Q (cfs) Downstream Len (ft) Upstream Invert HGL Depth Area Val Val EGL Sf elev elev head elev (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) ------;oeff Check Ave Enrgy Sf loss (%) (ft) JL (K) Minor loss (ft) Invert elev (ft) HGL elev (ft) Depth (ft) Area (sqft) Val (ftls) Val head (ft) EGL elev (ft) Sf (%) 1 12 0.78 193.50 195.00 1.00 0.79 0.99 0.02 195.02 0.048 56.470 194.00 195.03 1.00 0.79 0.99 0.02 195.04 0.048 0.048 0.027 1.00 0.02 LINE C Number of lines: I fn Date: 10/30/2015 - c=cir e=ellip b=box torm 0.. .,ti 8LMNdFPrdVft roj. INE Elev.(ft) C, c?i' 8u I.W Ca 0 C sci CM C-11 ul 71 - 206.00 206.00 - - _________ ____________ ____________ ____________ ____________ _______ - ____________ ____________ ____________ - 203.00 _______ ____________ ____________ ____________ ____________ 203.00 - _________ ____________ ____________ ____________ ____________ - 200.00 200.00 - - _________ ___________ ___________ ___________ ___________ ____ ___________ ___________ ___________ ___________ —197.00 - 197.00 - - ________ __________ __________ __________ - - —194.00 - 194.00 - __________ - —191.00 191.00 -. __________ __________ __________ __________ __________ _________ 0 10 20 30 40 50 60 70 80 90 100 HGL EGL Reach (ft) Storm Sewers Date: 10/30/2015 m Se Ay nrulfflcbraTe Line mputatuons Line Size Q Downstream Len Upstream Check JL Minor oeff loss Invert H Depth Area Vol Vol EGL Sf Invert HGL Depth Area Vol Vol EGL Sf Ave Enrgy elev elev head elev elev elev head elev Sf loss (in) (cfs) (ft) (ft) (ft) (sqft) (ftls) (ft) (ft) (%) (ft) (ft) (ft) (ft) (sqft) (ft!s) (ft) (ft) (%) (%) (ft) (K) (ft) 1 12 1.91 221.80 223.00 1.00 0.79 2.44 0.09 223.09 0.289 37.790 221.98 223.11 1.00 0.79 2.44 0.09 223.20 0.289 0.289 0.109 1.00 0.09 LINE H [Number of lines: I Run Date: 10/30/2015 c=cir e=ellip b= box Storm Sewers vlO.' storm Sewer Prome Proj. file: LINE H.stm _____ Elev. (ft) 235.00 232.00 229.00 226.00 223.00 235.00 232.00 229.00 226.00 223.00 220.00 220.00 0 10 20 30 40 50 60 70 80 90 100 HGL EGL Reach (ft) torm bewers I A2 EXHIBIT - I --------------- ADDENDUM 3/05/201 ADDENDUM TO HYDROLOGY STUDY FOR CARLSBAD RANCH PA 5- MARBRISA PHASE III HOTEL 6 AND TIMESHARE VILLA, DATED OCTOBER 29, 2015 PREPARED FOR: GRAND PACIFIC CARLSBAD, L.P. 5900 PASTEUR COURT, SUITE 200 CARLSBAD, CA 92008 (760)431-8500 PREPARED BY: uml ENGINEERING LAWI) RA nAG 'ffRV9SU&) 44ØSTATEPLIa (SCONL CA 92029 PH (760)145-8118 FAX (160)145-1890 EXCEL ENGINEERING 440 STATE PLACE ESCONDIDO, CA 92029 (760)745-8118 ENGINEER OF WORK: ROBERT D. DENTINO RCE 45629 DATE: MARCH 5, 2020 UPDATED: 08/17/2020 ADDENDUM A 03/05/20 This report is an addendum to the Hydrology Study for Carlsbad Ranch PA 5- Marbrisa Phase Ill Hotel 3 and Timeshare Villa, dated October 29, 2015, prepared by Excel Engineering (herein referred to as the "Marbrisa Phase Ill Study). The Marbrisa Phase Ill Study analyzed phase Ill of the Carlsbad Ranch, Planning Area 5 project which includes a combination of parking areas, time share villas, swimming pools, landscaping, and hotel buildings with associated site utility improvements including new storm drains, water and sewer main extensions, and dry utility runs and/or extensions. The included addendum has been put forth to analyze new drainage patterns resulting from a design change eliminating a proposed tennis court for the expansion of the proposed Sheraton Hotel 6. Overall, the DMA for the hotel addition decreased from 0.594-ac to 0.351-ac with a mitigated Qoo of 1.519-cfs from the previously reported 1.838-cfs in the Marbrisa Phase Ill Study. The new mitigated Qioo of 1.519-cfs was developed from the unmitigated Qioo of 1.970-cfs after incorporating a ponding/storage volume of 466-cf as shown in Exhibit E. Therefore, the hotel expansion results in a more conservative condition and will not affect the outflow design for the proposed stormwater system located approximately 100-ft northeast of the DMA at node 311 shown on the included post-development hydrology map addendum. See Exhibit E for the development of the mitigated Qioo. An analysis of both the pre- and post-development conditions was conducted to ensure appropriate and relevant data was used for site comparisons. Primarily, the new mitigated and unmitigated post- development Qioo was compared to that of the post-development Qioo in the Marbrisa Phase Ill Study indicating a decrease in Q100 as described above. Please see attached exhibits for further details. Exhibits *Note: Pre-Development Hydrologic Maps (From Phases 1 & 2) and associated Civil-D calculations were included in original Marbrisa Phase Ill Study as Attachments C and D. Exhibit A Vicinity Map Exhibit B Post-Development Hydrologic Map, Marbrisa Phase Ill Study Post-Development Hydrologic Map, Addendum A Exhibit C Civil-D Post-Development Hydrology Calculations, Marbrisa Phase Ill Study Exhibit D Civil-D Post-Development Hydrology Calculations, Addendum A Exhibit E 6-Hour Hydrograph and Mitigated Qioo EXH I BIT A Vicinity Map VICINITY MAP CITY OF OCEANSIDE HIGHWAY & 7 :7 .1' NOT TO SCALE cd . \ \\. RD J CITY OF VISTA OAD ALOMAR 1/I?p ' IDDEN '1 \ '\y VALLEY RD. CITY OF go SAN MARCOS ALG 7 PACIFIC P, Cos AVE OCEAN /0 CITY OF ENCINITAS EXHIBIT B Figure 1: Post-Development Hydrologic Map, Marbrisa Phase Ill Study Figure 2: Post-Development Hydrologic Map, Current Design Changes Figure 3: Post-Development Hydrologic Map, Addendum A _ - - _ - - - - - - - - - - FIGURE 1: POST—DEVELOPMENT HYDROLOGIC MAP, MARBRISA PHASE III STUDY Post.D.vslopmsnt Hydrologic Thbury Are Phase HI Carlsbad Ranch, Planning Area 5 MarBrisa CARL•AD, CALIFORNIA 4, GrandGrand Paclftc Rssorts - - J - LEGO'C APPROVED — / IMD 8 - - , I - -- •• oo, - ---- — — \ ' 977 ': '• 170 IMP - " -"-" '", M P - 4 _. •- -*- -- \ A- 97 -- 4 I ! 2) I -JMP-7 I SUMMARY TABLE — — . EXCE S ( ) ( ) .— ( (554 ( ) a ENGINEERING A 5285 2/725 911 - 5972 - /292! - /917 — c_ — •1 _) 55 5MNc 5/k oaf/ac SRI! 440 STATE PLACE 515 - 1/99 7285 7279 25/9 25- . ESCONDIDA. CA 92029 TEL (760) 745-8118 FAX (760) 745-1890 J p Post-Development Hydrologic Tributary Areas Phase Ill 'r 270 ADDENDUM A, 03/05/20 21 Carlsbad Ranch, Planning Area 5 MarBrisa '1 CARLSBAD. CALIFORN!A I - Grand Pacific Resorts IF 0.0 05 MARCH 2020 0 60 /00 /80 010 LEGEM wAgpc4Qz &øA E: ! SUMMARY TABLE, ADDENDUM A CO I Ilk - - - - - — - . --,.- 'MP3 - - GRAND PACIFIC DRIVE 00\- - - — — L .: j:\ __:•i/i All- 4lqk C, -- EXCEJ!!J ENGINEERING 1.50 .5AII( 005 DOCIR 501500 040 STATE PLACE [091920, CA 92029 TEL (760) 745-9160 FAX 760) 745-1890 240 235 777 21304 10 woo 'ZOO 2 -000 — If '1k 21B — 000 0.3008 ACRES _I2 IF 21900 —i N N//J7 ri 1 1107ZZ6 MR- /7 L1TTr-L] t T-DEVELOPMENT DDENDUM A Post-Development Hydrologic Tributary Areas Phase Ill ADDENDUM A, 03/05/20 Carlsbad Ranch, Planning Area 5 MarBrisa CARLSBAD, CALIFORNIA Grand Pacific Resorts Date: 05 MARCH 2020 Project Number: 19-111 SUMMARY TABLE EXIST DEVELOPMENT POST DEl/EL OPEMEN? ADDENDUM A Q,, (Cr5) AREA (ACRES) Tc (MIN) 0,00 (CFS) 41/776,4 TED J AREA (ACRES,M Tc (YIN) 1.838 0.594 / 4.07 1.519 0.391 J 4.07 LEGEND H4 TERCOURSL PIP/NO I4 TERCOURSL SURFACE SUBAREA BOUNDARY NODE NUMBER ELEVA liON AREA (ACRES) <- - - - — — — — — — EXCEL ENGINEERING [AND PLANNING CIVIL ENGINEERING SURVE1NC 440 STATE PLACE ESCONDIDO, CA 92029 TEL (760) 745-8118 FAX (760) 745-1890 SCALE 1 "-60' 0 60 120 190 '461 EXHIBIT C Civil-D Post-Development Hydrology Calculations, Marbrisa Phase Ill Study Nodes 325, 326, 312, 311 [APPROV(D:] Upstream point/station elevation = 221.980(Ft.) Downstream point/station elevation = 221.800 (Ft.) Pipe length = 50.00(Ft.) Slope = 0.0036 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 1.864(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 1.864(CFS) Normal flow depth in pipe = 8.67(In.) Flow top width inside pipe = 10.74 (In.) Critical Depth = 6.98(In.) Pipe flow velocity = 3.07(Ft/s) Travel time through pipe = 0.27 mm. Time of concentration (TC) = 7.98 mm. + ++++ ++++.+ ++++++ + +++..+ + +++++++ +++++ +++.+ + + Process from Point/Station 310.000 to Point/Station 310.000 **** SUBAREA FLOW ADDITION **** Rainfall intensity (I) = 5.066(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Time of concentration = 7.98 mm. Rainfall intensity = 5.066(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.729 Subarea runoff = 1.829(CFS) for 0.586(Ac.) Total runoff = 3.693(CFS) Total area = 1.157(Ac.) Process from Point/Station 310.000 to Point/Station 311.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 218.800(Ft.) Downstream point/station elevation = 213.040 (Ft.) Pipe length = 228.00(Ft.) Slope = 0.0253 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.693(CFS) Nearest computed pipe diameter = 12.00 (In.) Calculated individual pipe flow = 3.693(CFS) Normal flow depth in pipe = 7.07(In.) Flow top width inside pipe = 11.81 (In.) Critical Depth = 9.83(In.) Pipe flow velocity = 7.68(Ft/s) Travel time through pipe = 0.49 mm. Time of concentration (TC) = 8.48 mm. +++++ + ++++++ +++++ ++++ ++++ + +++ + + ++++ + ++++++++++++++++++++++++ +++++ + Process from Point/Station 311.000 to Point/Station 311.000 CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 3 in normal stream number 1 Stream flow area = 1.157 (Ac.) Runoff from this stream 3.693(CFS) Time of concentration = 8.48 mm. Rainfall intensity = 4.874(In/Hr) Process from Point/Station 325.000 to Point/Station !326.000 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 (MEDIUM DENSITY RESIDENTIAL (14.5 DU/A or Less Impervious value, Ai = 0.500 Sub-Area C Value = 0.630 100 YR POST-DEVELOPMENT CALC (Outfall A) APPROVED 4-28-15 Page 12 of 31 Highest elevation = 224.000(Ft.) Lowest elevation 223.000(Ft.) Elevation difference = 1.000(Ft.) Slope = 0.885 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 65.00 (Ft) for the top area slope value of 0.89 %, in a development type of 14.5 DU/A or Less In Accordance With Figure 3-3 Initial Area Time of Concentration = 7.10 minutes TC = [1.8*(1.1_C)*distance(Ft.).5)/(% slope(1/3)] TC = [1.8*(1.1_0.6300)*( 65.000.5)/( 0.885(1/3)1= 7.10 The initial area total distance of 113.00 (Ft.) entered leaves a remaining distance of 48.00 (Ft.) Using Figure 3-4, the travel time for this distance is 0.95 minutes for a distance of 48.00 (Ft.) and a slope of 0.89 % with an elevation difference of 0.42(Ft.) from the end of the top area Tt = (11.9*length(Mi)3)/(elevation change(Ft.))1".385 *60(min/hr) = 0.950 Minutes Tt=[(11.9*0.00913)/( 0.42)]A.385= 0.95 Total initial area Ti = 7.10 minutes from Figure 3-3 formula plus 0.95 minutes from the Figure 3-4 formula = 8.05 minutes Rainfall intensity (I) = 5.037(In/Hr) for a 100.0 year storm Effective runoff coefficient used for area (QKCIA) is C = 0.630 Total initial stream area = 0.179(Ac.) Process from Point/Station 326.000 to Point/Station 312.000 ' IMPROVED CHANNEL TRAVEL TIME Covered channel Upstream point elevation = 223.000 (Ft.) Downstream point elevation = 222.000 (Ft.) ---. Channel base width 0.500(Ft.) Slope or 'Z' of left channel bank = 0.000 Slope or 'Z' of right channel bank = 0.000 Estimated mean flow rate at midpoint of channel = 1.226(CFS) Manning's 'N' = 0.015 Maximum depth of channel 1.000(Ft.) Flow(q) thru subarea = 1.226(CFS) Depth of flow = 0.656(Ft.), Average velocity = 3.737(Ft/s) Channel flow top width = 0.500 (Ft.) Flow Velocity = 3.74(Ft/s) Travel time = 0.32 mm. Time of concentration = 8.37 mm. Critical depth = 0.570(Ft.) Adding area flow to channel Rainfall intensity (I) = 4.912(In/Hr) for a 100.0 year storm User specified 'C' value of 0.630 given for subarea Rainfall intensity = 4.912(In/Hr) for a 100.0 year storm Effective runoff coefficient used for total area (Q=KCIA) is C = 0.630 CA = 0.374 for 0.415 (Ac.) Total area = 0.594 (Ac.) Depth of flow = 0.930(Ft.), Average velocity 3.954(Ft/s) Critical depth = 0.750(Ft.) Process from Point/Station :312.000 to Point/Station 311.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 219.000(Ft.) Downstream point/station elevation = 213.040 (Ft.) Slope = 0.0 U5 Mannlng'p N = 0.013 No. of pipes = 1 IMMUMMOMMEWo • I 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 APPROVED Page 13 of 31 Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow = 1.838(CFS) Normal flow depth in pipe = 3.91 (In.) Flow top width inside pipe = 8.92(In.) Critical Depth = 7.44(In.) Pipe flow velocity = 9.98 (Ft/s) Travel time through pipe = 0.12 mm. Time of concentration (TC) = 8.50 mm. + +++++ + ++++++ +++++ +++++ + +++++++ ++++++++++++++ +++++ ++++++++ + Process from Point/Station' '311.000 to Point/Station 311.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 3 in normal stream number 2 Stream flow area = 0.594 (Ac.) Runoff from this stream 1.838(CFS) Time of concentration = 8.50 mm. Rainfall intensity = 4.865(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (mm) (In/Br) 1 3.693 8.48 4.874 2 1.838 8.50 4.865 Qmax(1) = 1.000 * 1.000 * 3.693) + 1.000 * 0.997 * 1.838) + = 5.526 Qmax(2) = 0.998 * 1.000 * 3.693) + 1.000 * 1.000 * 1.838) + = 5.525 Total of 2 streams to confluence: Maximum flow rates at confluence using above data: 5.526 5.525 Area of streams before confluence: 1.157 0.594 Time of concentration -R A74 in. Effective stream area after confluence = 1.751(Ac.) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 311.000 to Point/Station 324.000 PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 213.040(Ft.) Downstream point/station elevation = 190.000 (Ft.) Pipe length = 495.00(Ft.) Slope = 0.0465 Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.526(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow 5.526(CFS) Normal flow depth in pipe = 7.54(In.) Flow top width inside pipe = 11.60(In.) Critical Depth = 11.28(In.) Pipe flow velocity = 10.65(Ft/s) Travel time through pipe = 0.77 mm. Time of concentration (TC) 9.25 mm. Process from Point/Station 324.000 to Point/Station 324.000 **** CONFLUENCE OF MAIN STREAMS **** 100 YR POST-DEVELOPMENT CALC (Outfall A) 4-28-15 APPROVED Page 14 of 31 EXHIBIT D Civil-D Post-Development Hydrology Calculations, Addendum A Hydraulic Calculations: Storm Line B-5 I San Diego County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software,(c) 1991-2014 Version 9.0 Rational method hydrology program based on San Diego County Flood Control Division 2003 hydrology manual Rational Hydrology Study Date: 02/27/20 ------------------------------------------------------------------------ ********* Hydrology Study Control Information * * * * * * * * * * Program License Serial Number 6332 Rational hydrology study storm event year is 24.0 English (in-lb) input data Units used Map data precipitation entered: 6 hour, precipitation(inches) = 2.600 24 hour precipitation(inches) = 4.500 P6/P24 = 57.8% San Diego hydrology manual 'C' values used Process from Point/Station '401.000 to Point/Station '402.000 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 [COMMERCIAL area type ] (General Commercial ) Impervious value, Ai = 0.850 Sub-Area C Value = 0.820 ITha an $N$ Highest elevation = 224.100(Ft.) Lowest elevation = 223.930(Ft.) Elevation difference = 0.170(Ft.) Slope = 0.515 % INITIAL AREA TIME OF CONCENTRATION CALCULATIONS: The maximum overland flow distance is 50.00 (Ft) for the top area slope value of 0.52 %, in a development type of General Commercial In Accordance With Figure 3-3 Initial Area Time of Concentration = 4.45 minutes TC = [1.8*( 1.1 _C)*distance(Ft.).5)/(% slope A(1/3)] TC = [l.8*(1.10.8200)*( 50,000A,5)/( 0,515A(1/3)1= 4.45 Calculated TC of 4.446 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations HOTEL 6 ADDENDUrY 1 nn-YRAR POST-T)WRT.OPMP.NT tfll2R/2( Rainfall intensity (I) = 6.850(In/Hr) for a 24.0 year storm Effective runoff coefficient used for area (Q=KCIA) is C = 0.820 tSbateaiiuniff MET, J Total initial stream area = 0.050(Ac.) Process from Point/Station 402.000 to Point/Station 403.000 SUBAREA FLOW ADDITION **** Calculated TC of 4.446 minutes is less than 5 minutes, resetting TC to 5.0 minutes for rainfall intensity calculations Rainfall intensity (I) = 6.850(In/Hr) for a 24.0 year storm 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 [COMMERCIAL area type ] (General Commercial ) Impervious value, Ai = 0.850 Sub-Area C Value = 0.820 Time of concentration = 4.45 mm. Rainfall intensity = 6.850(In/Hr) for a 24.0 year storm Effective runoff coefficient used for total area =KCIA)isC=0.820 CA= 0.288 for 030 1( 1(Ac.) 11111111111 11111111111 I I I + 11111 I I I ++++ I I I I I ++++++ 11111111 ++++++++++++ 'Process from Point/Station '403.000 to Point/Station' '404.000 PIPEFLOW TRAVEL TIME (Program estimated size) Upstream point/station elevation = 218.500(Ft.) Downstream ,oint/station elevation = 216.020(Ft.) Sloe = 0.0200 Manning's N = 0.013 No. of pipes = 1 •e iiitesl j1tiv U9i,2')) Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow = 1.972(CFS) Normal flow depth in pipe = 6.33(In.) Flow top width inside pipe = 8.22(In.) Critical Depth = 7.66(In.) Pipe flow velocity = 5.94(Ft/s) Travel time through pipe = 0.35 mm. Time of concentration (TC) = 4.79 mm. ++++++++++ 1111111111 + I I I i I I 11111111 I I I I I I I I I a I -I—f+++++ ++ I I I 1111111 Process from Point/Station 404.000 to Point/Station, 311.000 '''K PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 216.020(Ft.) Downstream point/station elevation = 213.040(Ft.) pengti— Slope = 0.0584 Manning's N = 0.013 HOTEL 6 ADDENDUM I 1 (1A-YF.A R PflST-IWVRT.OPMRNT fl/RI( I No. of pipes = 1 I)J Nearest computed pipe diameter = 9 O0(In.) Calculated individual pipe flow = 1 .972(CFS) Normal flow depth in pipe = 4.46(In.) Flow top width inside pipe = 9.00(In.) Critical Depth = 7.66(In.) Pipe flow velocity = 9.02(Ft/s) Travel time through pipe = 0.09 mm. Time of concentration (TC) = 4.89 mm. End of computations, total study area = 0.351 (Ac.) UNMITIGATED Qioo SEE EXHIBIT E FOR 6-HR HYDROGRAPH AND MITIGATED Qioo HOTEL 6 ADDENDUM l nn-VP AP PncT.npvpT flPMP!..TT (YI1R/If EXHIBIT E 6-Hour Hydrograph and Q100 Mitigation Hydraulic Calculations: SD Line B-5 Watershed Model Schematic Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2015 by Autodesk, Inc. vl0.4 Legend xt Orlain DescnDtion I Manual HYDROGRAPH FOR IMP-8 2 Reservoir IMP-8, NODE 311 Project: New.gpw Monday, 03/2/2020 Hydrograph Summary Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2015 by Autodesk, Inc. v10.4 Hyd. No. Hydrograph type (origin) Peak flow (cfs) Time interval (mm) Time to Peak (mm) Hyd. volume (cuft) Inflow hyd(s) Maximum elevation (ft) Total strge used (cuft) Hydrograph Description I 2 Manual Reservoir 1.970 4 4 244 244 2,640 2,271 1 -- 219.20 466 HYDROGRAPH FOR IMP-8 IMP-8, NODE 311 GATED- Q1 I New.gpw Return Period: 100 Year Monday, 03/2/2020 3 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2015 by Autodesk, Inc. v1 0.4 Hyd. No. I HYDROGRAPH FOR IMP-8 Hydrograph type = Manual Peak discharge Storm frequency = 100 yrs Time to peak Time interval = 4 min Hyd. volume Monday, 03/2/2020 = 1.970cfs = 4.07 hrs = 2,640 cuft HYDROGRAPH FOR IMP-8 Q (cfs) Hyd. No. 1 -- 100 Year Q (cfs) 2.00 2.00 1.00 1.00 1.0 2.0 3.0 4.0 5.0 6.0 Hyd No. 1 .-- 0.00 7.0 Time (hrs) 4 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3138 2015 by Autodesk, Inc. v10.4 Monday. 03 / 2 / 2020 Hyd. No. 2 IMP-8, NODE 311 Hydrograph type = Reservoir Peak discharge = 1.519 cfs Storm frequency = 100 yrs Time to peak = 4.07 hrs Time interval = 4 min Hyd. volume = 2,271 cuft Inflow hyd. No. = I - HYDROGRAPH FOR IMP-$.4ax. Elevation = 219.20 ft Reservoir name = IMP-8 Max. Storage = 466 cuft Storage Indication method used. IMP-8, NODE 311 Q (cfs) Hyd. No. 2 -- 100 Year Q (cfs) 2.00 2.00 1.00 1.00 I....' 0.0 1.0 2.0 Hyd No. 1 3.0 4.0 To tal storage used = 466 cuft - 0.00 7.0 Time (hrs) Pond Report Hydrafiow Hydrographs Extension for AutoCAD® Civil 3D® 2015 by Autodesk, Inc. v10.4 Monday, 03/2/2020 Pond No. I - IMP-8 Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 218.50 ft Stage I Storage Table Stage (ft) Elevation (ft) Contour area (sqft) Incr. Storage (cult) Total storage (cuft) 0.00 218.50 477 0 0 1.00 219.50 1,037 739 739 Culvert! Orifice Structures Weir Structures [A] (B] [C] [PrfRsr] [A] [B] [C] [D] Rise (in) = 8.00 0.00 0.00 0.00 Crest Len (ft) = 11.00 0.00 0.00 0.00 Span (In) = 8.00 0.00 0.00 0.00 Crest El. (ft) = 219.00 0.00 0.00 0.00 No. Barrels = 1 0 0 0 Weir Coeff. = 3.33 3.33 3.33 3.33 Invert El. (ft) = 215.00 0.00 0.00 0.00 Weir Type = I - Length (ft) = 124.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope (%) = 1.64 0.00 0.00 n/a N-Value = .013 .013 .013 n/a Orifice Coeff. = 0.60 0.60 0.60 0.60 Exfil.(in/hr) = 0.000 (by Contour) Multi-Stage = n/a No No No TW Elev. (ft) = 0.00 Note: Culvert/Orifice outflows are analyzed under Inlet (Ic) and outlet (oc) control. Weir risers checked for orifice conditions (IC) and submergence (a). Stage! Storage I Discharge Table Stage Storage Elevation Clv A Clv B Clv C PrfRsr Wr A Wr B Wr C Wr D Exfll User Total ft cuft ft cfs cfs cfs cfs cfs cfs cfs cfs cfs cfs cfs 0.00 0 218.50 0.00 - - - 0.00 - - - --- -- 0.000 1.00 739 219.50 2.39oc - --- - 2.37s - - - --- -- 2.374 Storm Line B 8 *.31 6 10 ip LINE B-4 11 —LINE B-6b 12 —LINE B-6c LINE B-6d 13 LINE B-6e---- 14 LINE B-6f 15 LINE B-6 16 m4 3 2 _______ LINE B-I LINE B-2 m (1)1 —i C) Project File: Storm Line B_rev2.stm Number of lines: 16 Date: 5/26/2020 Storm Sewers 00.40 1 Storm Sewer Summary Report page I Line Line ID Flow Line Line Line Invert invert Line HGL HGL Minor HGL Dns Junction No. rate Size shape length EL Dn EL Up Slope Down Up loss Junct Line Type (cts) (in) (ft) (ft) (It) (%) (It) (ft) (It) (It) No. I EXISTING 27.67 30 Cir 75.540 182.99 190.00 9.280 183.79 191.79 0.84 191.79 End Manhole 2 LINE B-2 13.20 18 Cir 40.770 194.48 196.50 4.955 195.29 197.86 0.96 197.86 1 Manhole 3 LINE B-1 8.81 18 Cir 51.140 190.02 190.28 0.508 191.79 192.15* 0.39 192.54 1 Manhole 4 LINE 8-3 5.66 18 Cir 369.770 190.03 209.12 5.163 191.79 210.04 n/a 210.04j I Manhole 5 LINE 8-4 5.66 12 Cir 18.270 209.16 209.75 3.229 210.04 210.69 n/a 210.69 4 None • Cir 100.820 209.75 212.46 2.688 210.69 213.40 n/a 213.40 5 None • Cir 50.780 213.04 214.13 2.147 213.47 214.73 n/a 214.73 6 Manhole 8 LINE 8-7 3.69 12 Cir 81.250 212.46 214.72 2.782 213.40 215.54 n/a 215.54j 6 None 9 LINE B-8 3.69 12 Cir 118.930 214.72 218.02 2.775 215.54 218.84 n/a 218.84 8 None 10 LINE B-9 3.69 12 Cir 27.990 218.02 218.80 2.787 218.84 219.62 n/a 219.62 9 Manhole • • Cir 35.490 214.58 214.93 0.986 215.25* 216.19* 0.22 216.41 7 None • • Cir 22.490 214.93 215.16 1.023 216.41 217.01* 0.22 217.23 11 None • Cir 15.460 215.16 215.31 0.970 217.23* 217.64 0.22 217.86 12 None • Cir 13.560 215.31 215.99 5.015 217.86 218.22* 0.22 218.43 13 None • • Cir 23.210 215.99 217.15 4.998 218.43* 219.05* 0.22 219.27 14 None • • Cir 11.010 217.15 217.70 4.995 219.27* 219.56 0.50 220.06 15 Manhole Water tight jo nts ar to be used for p ropose d 8 inch line. Se grading plans Storm Line B Number of lines: 16 Run Date: 5/22/2020 NOTES: Return period = 100 Yrs. ; Surcharged (HGL above crown). j - Line contains hyd. jump. Storm Sewers 00.40 Storm Sewer Inventory Report Line Alignment Flow Data Physical Data Line ID No. Dnstr Line Defi June Known 0mg Runoff Inlet Invert Line Invert Line Line N J-Loss Inlet! Line Length angle Type Q Area Coeff Time El On Slope El Up Size Shape Value Coeff Rim El No. (ft) (deg) (cfs) (ac) (C) (mm) (ft) (%) (It) (in) (n) (K) (It) I End 75.540 -94.510 MH 27.67 0.00 0.00 0.0 182.99 9.28 190.00 30 Cir 0.013 1.00 202.00 EXISTING 2 1 40.770 90.000 MH 13.20 0.00 0.00 0.0 194.48 4.95 196.50 18 Cir 0.013 1.00 199.50 LINE B-2 3 1 51.140 -90.000 MH 8.81 0.00 0.00 0.0 190.02 0.51 190.28 18 Cir 0.013 1.00 193.50 LINE B-1 4 1 369.770 0.000 MH 5.86 0.00 0.00 0.0 190.03 5.16 209.12 18 Cir 0.013 1.00 215.70 LINE B-3 5 4 18.270 90.000 None 5.66 0.00 0.00 0.0 209.16 3.23 209.75 12 Cir 0.013 0.44 216.10 LINE B-4 • 5 100.820 -22.500 None 0.00 0.00 0.0 209.75 2.69 212.48 12 Cir 0.013 1.00 217.90 • 6 50.780 90.000 MH 0.00 0.00 0.0 213.04 2.15 214.13 12 Cir 0.013 0.94 219.10 -- 8 6 81.250 0.000 None 3.69 0.00 0.00 0.0 212.46 2.78 214.72 12 Cir 0.013 0.75 220.00 LINE B-7 9 8 118.930 45.000 None 3.69 0.00 0.00 0.0 214.72 2.77 218.02 12 Cir 0.013 0.75 224.00 LINE B-8 10 9 27.990 45.000 MH 3.69 0.00 0.00 0.0 218.02 2.79 218.80 12 Cir 0.013 1.00 221.80 LINE B-9 • 7 35.490 67.685 None 0.00 0.00 0.0 214.58 0.99 214.93 8 Cir 0.013 0.44 219.82 • II 22.490 -22.500 None 0.00 0.00 0.0 214.93 1.02 215.16 8 Cir 0.013 0.44 220.17 • 12 15.460 -22.500 None 0.00 0.00 0.0 215.16 0.97 215.31 8 Cir 0.013 0.44 220.53 • 13 13.560 -22.500 None 0.00 0.00 0.0 215.31 5.01 215.99 8 Cir 0.013 0.44 221.25 • 14 23.210 -22.500 None 0.00 0.00 0.0 215.99 5.00 217.15 8 Cir 0.013 0.44 221.60 • 15 11.010 22.500 MH 0.00 0.00 0.0 217.15 5.00 217.70 8 Cir 0.013 1.00 221.96 - Storm Line B Number of lines: 18 Date: 5/22/2020 Storm Sewers vlO, Hydraulic Grade Line Computations rage I Line Size Q Downstream Len Upstream Check JL Minor coeff loss Invert HGL Depth Area Vol Vol EGL Sf - Invert HGL Depth Area Vol Vol EGL Sf Ave Enrgy dcv dcv head dcv, Slav elev, head 01ev Sf lose (in) (cfs) (if) (ft) (ft) (sqft) (ft!s) (if) (ft) (%) (ft) (ft) (ft) (ft) (sqft) (We) (if) (It) (%) (%) (ft) (K) (It) (1) (2) (3) (4) (5) (6) (7) (8) (9) (10) (11) (12) (13) (14) (15) (16) (17) (18) (19) (20) (21) (22) (23) (24) 1 30 27.67 182.99 183.79 0.80 1.35 20.43 0.84 184.63 0.000 75.540 190.00 191.79 1.79 3.77 7.35 0.84 192.63 0.000 0.000 n/a 1.00 0.84 2 18 13.20 194.48 195.29 0.81* 0.97 13.62 0.96 196.25 0.000 40.770 196.50 197.86 1.36 1.68 7.85 0.96 198.82 0.000 0.000 n/a 1.00 0.96 3 18 8.81 190.02 191.79 1.50 1.77 4.99 0.39 192.18 0.704 51.140 190.28 192.15 1.50 1.77 4.99 0.39 192.54 0.704 0.704 0.360 1.00 0.39 4 18 5.66 190.03 191.79 1.50 1.13 3.20 0.16 191.95 0.291 369.77 209.12 210.04j 0.92 1.13 5.00 0.39 210.43 0.608 0.449 We 1.00 n/a 5 12 5.66 209.16 210.04 0.88 0.73 7.75 0.84 210.88 0.000 18.270 209.75 210.69 0.94 0.77 7.37 0.84 211.54 0.000 0.000 n/a 0.44 We • • 209.75 210.69 0.94 0.77 7.37 0.84 211.54 0.000 100.82 212.46 213.40 0.94 0.77 7.37 0.84 214.25 0.000 0.000 n/a 1.00 n/a • • 213.04 213.47 0.43* 0.32 6.17 0.25 213.72 0.000 50.780 214.13 214.73 0.60 0.49 4.02 0.25 214.98 0.000 0.000 We 0.94 We 8 12 3.89 212.46 213.40 0.94 0.69 4.80 0.45 213.85 0.000 81.250 214.72 215.54j 0.82 0.69 5.37 0.45 215.99 0.000 0.000 n/a 0.75 We 9 12 3.69 214.72 215.54 0.82 0.69 5.37 0.45 215.99 0.000 118.9: 218.02 218.84 0.82 0.69 5.37 0.45 219.29 0.000 0.000 We 0.75 n/a 10 12 3.69 218.02 218.84 0.82 0.69 5.37 0.45 219.29 0.000 27.990 218.80 219.62 0.82 0.69 5.37 0.45 220.07 0.000 0.000 n/a 1.00 n/a • • 214.58 215.25 0.67* 0.35 5.64 0.50 215.74 2.662 35.490 214.93 216.19 0.67 0.35 5.64 0.50 216.69 2.661 2.661 0.945 0.44 0.22 • • 214.93 218.41 0.67 0.35 5.64 0.50 216.90 2.682 22.490 215.16 217.01 0.67 0.35 5.64 0.50 217.50 2.681 2.661 0.599 0.44 0.22 • • 215.16 217.23 0.67 0.35 5.64 0.50 217.72 2.682 15.460 215.31 217.64 0.67 0.35 5.64 0.50 218.13 2.661 2.661 0.411 0.44 0.22 • • 215.31 217.86 0.67 0.35 5.64 0.50 218.35 2.662 13.560 215.99 218.22 0.67 0.35 5.64 0.50 218.71 2.661 2.661 0.361 0.44 0.22 • • 215.99 218.43 0.67 0.35 5.64 0.50 218.93 2.662 23.210 217.15 219.05 0.67 0.35 5.64 0.50 219.55 2.661 2.661 0.618 0.44 0.22 • • 217.15 219.27 0.67 0.35 5.64 0.50 219.77 2.682 11.010 217.70 219.56 0.87 0.35 5.64 0.50 220.06 2.661 2.661 0.293 1.00 0.50 Storm Line B Number of tines: 16 fn Date: 5/2212020 Notes: * Normal depth assumed.: Critical depth.; j-Line contains hyd. jump. ; C = cir e = ellip b = box Storm Sewers v1O. 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Ib - 0) Sq M CA CA 50o C aNiq 00.oc (:U)'AS13 WSA9J9 euq WJ0 epi roid SI!4OJd JeMa WJ0S - (i ti • I.. — I___________ —I I I 4 • U • U I U I I U • I • • I U • I U • I U • I U • I U • I U • I U • I U U I U a -- a a - - - - - = - - a Appendix I: Forms and Checklists !sIIIIUI: Form 1-7 Is there a demand for harvested water (check all that apply) at the project site that is reliably present during the wet season? Toilet and urinal flushing Landscape irrigation Other: If there is a demand; estimate the anticipated average wet season demand over a period of 36 hours. Guidance for planning level demand calculations for toilet/urinal flushing and landscape irrigation is provided in Section B.3.2. Flushing: (32,388-sf)(9.3 gal/guest)/(200-sf/guest) = 1,510 gallons (1,510 gal)(1.5 days)/(7.48 gal/cu. ft) = 302.81 cu. ft Irrigation: 36-hr Mod. Water per Table B.3-3 (Low Plant Water Use) (390 gal days/acre)(1.95 acres)/(7.48 gal/cu feet) = 404.48 cu ft Total Demand = 708 Cu. ft. Calculate the DCV using worksheet B.2-1. DCV =5.762 (cubic feet) Therefore, 0.25(5,762) = 1.441 cu ft 3a. Is the 36 hour demand greater 3b. Is the 36 hour demand greater than 3c. Is the 36 hour demand than or equal to the DCV? 0.25DCV but less than the full DCV? less than 0.2SDCV? Yes / Yes /E) E) C* C* Harvest and use appears to be Harvest and use may be feasible. Harvest and use is feasible. Conduct more detailed Conduct more detailed evaluation and considered to be infeasible. evaluation and sizing calculations sizing calculations to determine to confirm that DCV can be used feasibility. Harvest and use may only be at an adequate rate to meet able to be used for a portion of the site, drawdown criteria, or (optionally) the storage may need to be upsized to meet long term capture targets while draining in longer than 36 hours. Is harvest and use feasible based on further evaluation? Yes, refer to Appendix E to select and size harvest and use BMPs. No, select alternate BMPs. 1-26 February 2016 ATTACHMENT Id Categorization of Infiltration FcasibifitN, Condition Form 1-8 Part 1- Full Infiltration Feasibility Screening Criteria Would mfihration of the full design volume be feasible from a physical perspective without any undesirable consequences that cannot be reasonably mitigated Criteria Screening Question Yes No Is the estimated reliable infiltration rate below proposed facility locations greater than 1 0.5 inches per hour? The response to this Screening Question shall be based on a X comprehensive evaluation of the factors presented in Appendix C.2 and Appendix D. Provide basis: No. Based on the soil classification from the geotechnical investigation prepared by MTGL for the project (dated February 6, 2020 and revised May 20, 2020), the soils encountered at the site consist of silty sand. Using the Minnesota Stormwater Manual as a reference, the silty sand soils would have a infiltration rate of approximately 0.45 inch per hour, and possibly lower for the locations where the soils also contain chunks of clay. Can infiltration greater than 0.5 inches per hour be allowed without increasing risk of geotechnical hazards (slope stability, groundwater mounding, utilities, or other factors) 2 that cannot be mitigated to an acceptable level? The response to this Screening Question x shall be based on a comprehensive evaluation of the factors presented in Appendix C.2. Provide basis: Groundwater was not encountered in the explorations performed for the hotel site. The proposed biofiltration basin is considered located far enough from the existing site slopes as to not present a significant potential for affecting slope stability. However, we are concerned with discharging water from infiltration devices directly adjacent to the building foundations and saturating the soil near the foundations for extended periods of time. Criteria Screening Question Yes No Can infiltration greater than 0.5 inches per hour be allowed without increasing risk of groundwater contamination (shallow water table, storm water pollutants or other 3 factors) that cannot be mitigated to an acceptable level? The response to this Screening X Question shall be based on a comprehensive evaluation of the factors presented in Appendix C.3. Provide basis: Yes. As stated in the response for Criterion 2, groundwater was not encountered in the explorations for the hotel site, and there was no known evidence of contamination on the site. Summarize findings of studies; provide reference to studies, calculations, maps, data sources, etc. Provide narrative discussion of study/data source applicability. Can infiltration greater than 0.5 inches per hour be allowed without causing potential water balance issues such as change of seasonality of ephemeral streams or increased 4 discharge of contaminated groundwater to surface waters? The response to this X Screening Question shall be based on a comprehensive evaluation of the factors presented in Appendix C.3. Provide basis: Yes. See our response to Criterion 3. Summarize findings of studies; provide reference to studies, calculations, maps, data sources, etc. Provide narrative discussion of study/data source applicability. If all answers to rows I - 4 are "Yes" a full infiltration design is potentially feasible. The Part 1 feasibility screening category is Full Infiltration NO Result* If any answer from row 1-4 is "No" infiltration may be possible to some extent but would not generally be feasible or desirable to achieve a "full infiltration" design. Proceed to Part 2 To be completed using gathered site information and best professional judgment considering the definition of MEP in the MS4 Permit. Additional testing and/or studies may be required by City Engineer to substantiate findings. Form 1-8 Page 3 of 4 Part 2— Partial Infiltration vs No Infiltration Feasibility Screening Criteria Would infiltration of water in any appreciable amount be physically feasible without any negative consequences that cannot be reasonably mitigated? Criteria Screening Question Yes No Do soil and geologic conditions allow for infiltration in any appreciable rate or volume? 5 The response to this Screening Question shall be based on a comprehensive evaluation of the factors presented in Appendix C.2 and Appendix D. X Provide basis: The on-Site soils, by classification, would allow some appreciable infiltration. Summarize findings of studies; provide reference to studies, calculations, maps, data sources, etc. Provide narrative discussion of study/data source applicability and why it was not feasible to mitigate low infiltration rates. Can Infiltration in any appreciable quantity be allowed without increasing risk of geotechnical hazards (slope stability, groundwater mounding, utilities, or other factors) 6 that cannot be mitigated to an acceptable level? The response to this Screening Question X shall be based on a comprehensive evaluation of the factors presented in Appendix C.2. Provide basis: See our response to Criterion 2. Form 1-8 Page 4 of 4 I V I I Criteria Screening Question Yes No Can Infiltration in any appreciable quantity be allowed without posing significant risk for groundwater related concerns (shallow water table, storm water pollutants or other X factors)? The response to this Screening Question shall be based on a comprehensive evaluation of the factors presented in Appendix C.3. Provide basis: Groundwater is not located within approximately 10 feet from the bottom of the proposed basins. Ground water was not encountered in the explorations performed for the hotel site. The explorations extended to formational materials. However, ground water was encountered at a depth of 41 feet in a boring drilled for MTGL's study performed in 2015 for the overall development of the hotel site and nearby sites. The boring was located near the intersection of Cannon Road and Grand Pacific Drive, approximately eight hundred feet from the hotel site. Summarize findings of studies; provide reference to studies, calculations, maps, data sources, etc. Provide narrative discussion of study/data source applicability and why it was not feasible to mitigate low infiltration rates. Can infiltration be allowed without violating downstream water rights? The response to x 8 this Screening Question shall be based on a comprehensive evaluation of the factors presented in Appendix C.3. Provide basis: Storm water is detained in biofiltration BMPs, then discharged to a storm drain system that will eventually discharge downstream into the Agua Hedonia lagoon. Either by infiltration or by surface flow, the storm water ultimately ends up in the downstream receiving water and therefore the downstream water rights are not infringed upon. Summarize findings of studies; provide reference to studies, calculations, maps, data sources, etc. Provide narrative discussion of study/data source applicability and why it was not feasible to mitigate low infiltration rates. If all answers from row 14 are yes then partial infiltration design is potentially feasible. Part 2 The feasibility screening category is Partial Infiltration No infiltration Result* i i i If any answer from row 5-8 s no, then infiltration of any volume s considered to be infeasible within the drainage area. The feasibility screening category is No Infiltration. *To be completed using gathered site information and best professional judgment considering the definition of MEP in the MS4 Permit. Additional testing and/or studies may be required by City Engineer to substantiate findings ATTACHMENT le 0.59 INCHES NO San Diego County 85 th Percentile Isopluvials C.- L.g.od cay Figure B.1-1: 85th Percentile 24-hour lopluvial Map Automated Worksheet B.1: Calculation of Design Capture Volume (V2.0) A1Ilu.I.Iu. _uIwI1& I Drainage Basin ID or Name IMP-8 _I1II1I...1 unitless 2 85th Percentile 24-hr Storm Depth 0.59 inches 3 Impervious Surfaces Not Directed to Dispersion Area (C0.90) 11,519 sq-ft 4 Semi-Pervious Surfaces Not Serving as Dispersion Area (Cr0.30) sq-ft 5 Engineered Pervious Surfaces Not Serving as Dispersion Area (C0.10) 3,764 sq-ft 6 Natural Type A Soil Not Serving as Dispersion Area (C0.10) sq-ft 7 Natural Type B Soil Not Serving as Dispersion Area (C0.14) sq-ft 8 Natural Type C Soil Not Serving as Dispersion Area (C0.23) 9 Natural Type D Soil Not Serving as Dispersion Area (Cr0.30) sq-ft 10 Does Tributary Incorporate Dispersion, Tree Wells, and/or Rain Barrels? No yes/no 11 Impervious Surfaces Directed to Dispersion Area per SD-B (Ci0.90) sq-ft 12 Semi-Pervious Surfaces Serving as Dispersion Area per SD-B (Ci0.30) sq-ft 13 Engineered Pervious Surfaces Serving as Dispersion Area per SD-B (Ci=0.10 sq-ft 14 Natural Type A Soil Serving as Dispersion Area per SD-B (Ci0.10) sq-ft 15 Natural Type B Soil Serving as Dispersion Area per SD-B (Ci0.14) sq-ft 16 Natural Type C Soil Serving as Dispersion Area per SD-B (Ci0.23) sq-ft 17 Natural Type D Soil Serving as Dispersion Area per SD-B (Ci=0.30 sq-ft 18 Number of Tree Wells Proposed per SD-A # 19 Average Mature Tree Canopy Diameter ft 20 Number of Rain Barrels Proposed per SD-E # 21 Average Rain Barrel Size gal 22 Total Tributary Area 15,283 sq-ft Initial Runoff Factor for Standard Drainage Areas 0.70 unitless fI 23 24 Initial Runoff Factor for Dispersed & Dispersion Areas 0.00 unitless 25 Initial Weighted Runoff Factor 0.70 unitless 26 Initial Design Capture Volume 526 cubic-feet 27 Total Impervious Area Dispersed to Pervious Surface 0 sq-ft 28 Total Pervious Dispersion Area 0 sq-ft 29 Ratio of Dispersed Impervious Area to Pervious Dispersion Area n/a ratio 30 Adjustment Factor for Dispersed & Dispersion Areas 1.00 ratio 31 Runoff Factor After Dispersion Techniques 0.70 unitless 32 Design Capture Volume After Dispersion Techniques 526 cubic-feet 33 Total Tree Well Volume Reduction 0 cubic-feet IMi 34 Total Rain Barrel Volume Reduction 0 cubic-feet 35 Final Adjusted Runoff Factor 0.70 unitless 36 Final Effective Tributary Area 10,698 sq-ft 37 Initial Design Capture Volume Retained by Site Design Elements 0 cubic-feet 38 Final Design Capture Volume Tributary to BMP 526 cubic-feet No Warning Messages Automated Worksheet B.3: BMP Performance (V2.0) 111111M11) I ' tiiiiiiiii.m. Drainage Basin ID or Name IMP-8 'sq-ft Ifl 2 Design Infiltration Rate Recommended 0.000 in/hr 3 Design Capture Volume Tributary to BMP 526 cubic-feet 4 Is BMP Vegetated or Unvegetated? Vegetated unitless 5 Is BMP Impermeably Lined or Unlined? Lined unitless 6 Does BMP Have an Underdrain? Underdrain unitless 7 Does BMP Utilize Standard or Specialized Media? Standard unitless 8 Provided Surface Area 750 sq-ft I1IInmn 9 Provided Surface Ponding Depth 6 inches 10 Provided Soil Media Thickness 18 inches 11 Provided Gravel Thickness (Total Thickness) 21 inches 12 Underdrain Offset 3 inches 13 Diameter of Underdrain or Hydromod Orifice (Select Smallest) 1.00 inches 14 Specialized Soil Media Filtration Rate in/hr 15 Specialized Soil Media Pore Space for Retention unitless 16 Specialized Soil Media Pore Space for Biofiltration unidess 17 Specialized Gravel Media Pore Space unitless 18 Volume Infiltrated Over 6 Hour Storm 0 cubic-feet 19 Ponding Pore Space Available for Retention - 0.00 unitless 20 Soil Media PoreSpaceAvailablefor Retention 0.05 unitless 21 Gravel Pore Space Availablefor Retention(AboveUnderdrain) 0.00 unitless 22 Gravel Pore Space Availablefor Retention(Below Underdrain) 0.40 unitless 23 Effective Retention Depth 2.10 inches 24 Fraction of DCV Retained(Independent of Drawdown Time) 0.25 ratio 25 Calculated RetentionStorage Drawdown Time 120 hours 26 Efficacy of Retention Processes 0.26 ratio 27 Volume Retained by BMP(Considering Drawdown Time) 139 cubic-feet 28 Design Capture Volume Remaining for Biofiltration 387 cubic-feet 29 Max Hydromod Flow Ratethrough Underdrain 0.0488 cfs 30 Max Soil Filtration Rate Allowed by UnderdrainOrifice 2.81 in/hr 31 Soil Media FiltrationRate per Specifications 5.00 in/hr 32 Soil Media Filtration Rateto be usedfor Sizin 2.81 in/hr 33 Depth Biofiltered Over 6 Hour Storm 16.88 inches 34 Ponding Pore Space Availablefor Biofiltration 1.00 unitless 35 Soil Media PoreSpace Availablefor Biofiltration 0.20 unitless 36 Gravel Pore Space Available for Biofiltration (Above Underdrain) 0.40 unitless Effective Depthof Biofiltration Storag 16.80 inches 38 Drawdown Time for Surface Pon din 2 hours IIIIJJ1J_37 39 Drawdown Timefor Effective Biofiltration Depth 6 hours 40 Total Depth Biofiltered 33.68 inches 41 Option I -Biofiher1.50 DCV: Target Volume 581 cubic-feet 42 OptionI -Provided Biofiftration Volume 581 cubic-feet 43 Option 2 -Store 0.75 DCV: Target Volume 290 cubic-feet 44 Option 2 - Provided Storage Volume 290 cubic-feet 45 Portion of Biofiltration Performance Standard Satisfied 1.00 ratio 46 DoSite DesignElements and BMPs Satisfy Annual Retention Requirements? Yes yes/no UI1i- 47 Overall Portion of Performance Standard Satisfied (BMP Efficacy Factor) 1.00 ratio 48 Deficit of Effectively Treated Storrnwatei cubic_feet jNo Warning Messages ATTACHMENT 2 BACKUP FOR POP HYDROMODIFICATION CONTROL MEASURES [This is the cover sheet for Attachment 2.] Indicate which Items are Included behind this cover sheet: Attachment Contents Checklist Sequence Attachment 2a Hydromodification Management IZI Included Exhibit (Required) See Hydromodification Management Exhibit Checklist on the back of this Attachment cover sheet. Attachment 2b Management of Critical Coarse 21 Exhibit showing project Sediment Yield Areas (WMAA Exhibit drainage boundaries marked on is required, additional analyses are WMAACritical Coarse Sediment optional) Yield Area Map (Required) See Section 6.2 of the BMP Design Optional analyses for Critical Coarse Manual. Sediment Yield Area Determination 6.2.1 Verification of Geomorphic Landscape Units Onsite 6.2.2 Downstream Systems Sensitivity to Coarse Sediment 6.2.3 Optional Additional Analysis of Potential Critical Coarse Sediment Yield Areas Onsite Attachment 2c Geomorphic Assessment of Receiving 21 Not performed Channels (Optional) 0 Included See Section 6.3.4 of the BMP Design Manual. Attachment 2d Flow Control Facility Design and 21 Included Structural BMP Drawdown Calculations (Required) See Chapter 6 and Appendix G of the BMP Design Manual Use this checklist to ensure the required information has been included on the Hydromodification Management Exhibit: The Hydromodification Management Exhibit must identify: 0 Underlying hydrologic soil group Approximate depth to groundwater D Existing natural hydrologic features (watercourses, seeps, springs, wetlands) Critical coarse sediment yield areas to be protected (if present) IZI Existing topography Li Existing and proposed site drainage network and connections to drainage offsite lJ Proposed grading 0 Proposed impervious features Proposed design features and surface treatments used to minimize imperviousness Point(s) of Compliance (POC) for Hydromodification Management Existing and proposed drainage boundary and drainage area to each POC (when necessary, create separate exhibits for pre-development and post-project conditions) 0 Structural BMPs for hydromodification management (identify location, type of BMP, and size/detail) ATTACHMENT 2a I I