The URL can be used to link to this page

Home My WebLink AboutDEV 2017-0074; ROYAL JET HANGER EXPANSION; DRAINAGE STUDY; 2017-10-01OCT 03 2017 LAND DEVELOPMENT ENGINEERING I I DRAINAGE STUDY for ROYAL JET REMODEL REMOVAL & REPLACEMENT OF EXISTING HANGAR 2220 Palomar Airport Rd., Carlsbad, CA, 92011 Proj. ID: DEV2017-0074 Dwg. No.: 503-6A Prepared for: Department of Public Works, Airports County of San Diego 1560 Joe Crosson Dr. El Cajon, CA 92020 (619) 956-4819 Prepared by: Consultants, Inc. Bruce A. Robertson REC Consultants, Inc. 2442 Second Avenue San Diego, CA 92101 619-232-9200 ESSi, k\125' 6/30/18 7 or C Report Prepared: October 1, 2017 TABLE OF CONTENTS Chapter 1 - Executive Summary...........................................................................................................1 1.1 Introduction .............................................................................................................................. . ........................ 1 Project Site ........................................................................................................................................................1 PrimaryConsiderations .....................................................................................................................................1 Pointof Comparison ..........................................................................................................................................1 Rationale for Analysis of Run-On Areas ............................................................................................................ 1 FloodZone .............................. .......................................................................................................................... 1 1.2 Summary of Pre-Development Conditions......................................................................................................2 1.3 Summary of Post- DevelopmEnt Conditions .....................................................................................................2 — 1.4 Summary of Hydrology Results .............................................................................................. ......................... 3 RationalMethod Results ...................................................................................................................................3 - Modified Rational Method Results ..................................................................................................................... 3 PeakFlow Comparison ......................................................... .............................................................................. .4 1.5 Summary of Hydraulics Results ......................................................................................................................4 StormDrain Pipes..............................................................................................................................................4 StormDrain Channels .......................................................................................................................................5 1.6 References ......................................................................................................................................................5 1.7 Declaration of Responsible Ciarge ................................................................................................................. 6 Chapter2 — Methodology ....................................................................................................................... 7 2.1 Design Criteria ....................... . .......................................................................................................................... 7 2.2 Hydrology ......................................................................................................................................................... 7 Rational Method ....................... ........................................................................................................................... 7 RunoffCoefficient (C) ........................................................................................................................................7 Timeof Concentration RainfallIntensity (I)............................................................................................................................................7 (ta) .................................................................................................................................. 8 2.3 Hydraulics ........................................................................................................................................................ 9 GratedInlets in Sag ........................................................................................................................................... 9 Pipesand Channels ........................................................................................................................................... 9 Chapter 3 - Conclusions........................................................................................................................9 APPENDIX A: Maps & Details APPENDIX B: Calculations 1 I CHAPTER 1 - EXECUTIVE SUMMARY 1.1 Introduction Proiect Site The project site is located along the southern edge of Palomar Airport at 2200 Palomar Airport Rd, City of Carlsbad, County of San Diego, California. The project site is bound by Palomar Airport Road to the south and the existing airport to the north, east and west. The project site is a leasehold property with a total area of approximately 1.37 acres; however, the total area analyzed for this study is 4.01 acres, which includes 2.95 acres of existing run-on areas and 1.06 acres of disturbed area within the project site. The proposed site improvements include proposed building extensions to the western and eastern sides of the existing airplane hangar and the removal, regrading, and replacements of pavement on site. Proposed impervious areas will drain to two (2) proposed Biofiltration Best Management Practices (BMP), which will treat runoff for water quality purposes, detain low flows for hydromodification purposes, and manage larger flows for flood control purposes. Primary Considerations This study analyzes pre- and post-development 100-yr peak flow rates (Qioo). Treatment of storm water runoff for Pollutant Control and Hydromodification from the site has been addressed in a separate report - the "Storm Water Quality Management Plan for Royal Jet Aircraft Hangar" dated June 2017 by REC Consultants. Per the San Diego County Hydrology Manual (SDCHM), the Rational Method is recommended for analyzing the runoff response from drainage areas up to approximately I square mile in size. Hand calculations were used to model the pre- and post-development condition runoff response. Methodologies pertaining to the Hydrology of the site are consistent with Chapter 3 (Rational Method & Modified Rational Method) of the SDCHM. Methodologies pertaining to the Hydraulic design of the site improvements are consistent with the San Diego County Hydraulic Design Manual (2014). Point of Comparison For drainage analysis, one (1) point of comparison, denoted as POC-1, has been designated within an existing concrete swale approximately 30 feet north of the southeast corner project site boundary. From POC-1, flows continue east along an existing concrete swale that terminates at an existing catch basin, which conveys flows to the public storm drain system. Rationale for Analysis of Run-On Areas In the existing condition, 2.95 acres of impervious area produces runoff that crosses the project site and terminates at POC-1. In the proposed condition, storm water discharge from the run-on areas, designated RI & R2, were routed around the project site via storm drain facilities. The hydrologic analysis of Ri & R2 and subsequent hydraulic analysis of the proposed storm drain facilities were required to sufficiently size proposed facilities. Furthermore, there is minimal impact in the run-on areas due to the proposed improvements; therefore, there is no expected appreciable increase in runoff contribution from Ri & R2 to POC-1. As a result, Ri & R2 are excluded from the comparison of flows at POC-I. Flood Zone Per FEMA Flood Insurance Map 06073C1610G (revised May 16, 2012), the project site resides in Zone X, indicating that the site is an area determined to be outside the 0.2% annual chance floodplain. I 1.2 Summary of Pre-Development Conditions In the pre-development condition, there is a single contributing drainage management area (DMA), denoted as El, that ultimately discharges to P00-1. El has an area of 46,173 sf (1.06 ac), length of 160 ft, slope of 4%, and impervious area fraction of 97%. El generally drains north to south discharging to a concrete swale that terminates at POC-l. El consists of the existing hangar to be remodeled, asphalt and concrete pavement, and landscaping. There are two (2) DMAs, Ri & R2, that produce storm water runoff that comingles with discharge from El in the existing condition. Runoff from Ri, R2 and El ultimately confluences downstream of P00-1. Ri is an existing DMA that drains north to south and terminates at El. Ri has a total area of 90,785 sf (2.08 ac), length of 192 ft, slope of 2%, and impervious fraction of 100%. Ri consists of an existing building to the northwest of the site, asphalt travel lanes and parking fields. Runoff from Ri flows onto El. R2 is an existing DMA that drains west to east and terminates at El. R2 has a total area of 37,613 sf (0.86 ac), length of 156 ft, slope of 2%, and impervious fraction of 100%. R2 consists of two existing buildings to the west of the site, asphalt travel - lanes and parking fields. Runoff from R2 flows onto El. U 1.3 Summary of Post-Development Conditions See Appendix for a detailed view of the DMAs and private storm drain improvements described in this section. The proposed site alters drainage patterns by introducing ridges, depressions, and storm drain infrastructure to divide the contributing drainage area to P00-1 into two (2) DMAs, denoted as Ni & N2. I Ni drains north to south. Ni's land cover consists of concrete pavement, the western hangar extension and the existing hangar. Ni outlets to a proposed Biofiltration BMP, denoted BMP-1. Ni has a total area of 38,960 sf (0.894 ac); length of 192 ft, slope of 3.5% and impervious fraction of 99.6%. BMP-i at the outlet of Ni has an area of 1153 sf; runoff from Ni is I managed by a low flow orifice within the gravel layer of BMP-1 and a grated catch basin that acts as a weir for larger flows. Flows from the catch basin outlet via a proposed 12" PVC storm drain pipe that terminates at a proposed 24" RCP storm drain pipe to the south, confluencing with runoff from R2. I N2 drains west to east. N2's land cover consists of concrete pavement as well as the eastern extension of the existing hangar; all impervious areas drain to landscaping and ultimately to a proposed Biofiltration BMP, denoted BMP-2. N2 has a total area of 5,586 sf (0.128 ac); length of 156 ft, sl ope of i% and impervious fraction of 98.8%. BMP-2 at the outlet of N2 has an area of I 474 sf; runoff from N2 is managed by a low flow orifice within the gravel layer of BMP-2 and a grated catch basin that acts as a weir for larger flows. Flows from the catch basin outlet via a 6" PVC storm drain pipe that terminates at P00-1, confluencing with flows from Ni & R2. I Ri remains relatively undisturbed and outlets to a proposed trench drain along Ri's southern edge. The trench drain, flowing west to east, outlets directly to a 24" diameter pipe. The trench drain outlets to an existing 24" RCP approximately 35' south of the northeast corner of the project site. Runoff from Ri eventually confluences with flows from Ni, N2 & R2 downstream of ' P00-i. R2 remains relatively undisturbed and outlets to a proposed trench drain along R2's eastern edge. The trench drain, flowing north to south, outlets directly to an 18' diameter pipe. The trench drain outlets to a proposed 18" RCP to the south of the disturbed area, which ultimately flows east to P00-11 as described previously. I I 2 I I 1.4 Summary of Hydrology Results I Rational Method Results To determine the 100-yr runoff for each DMA, the Rational Method was performed for all the pre- and post-development DMAs. The following table outlines the results from the analysis. Please note that if tc is less than or equal to 5 minutes, a t of 5 minutes was used per the Hydrology Manual to analyze Qioo. Table I. Rational Method Results DMA tc min A ac Q100 cfs Pre-Development Area El 5 1 1.06 1 6.67 Run-on Areas (Undisturbed) RI 5 2.08 13.34 R2 5 0.86 5.53 Post-Development Areas NI 5 0.89 5.71 N2 5 0.13 0,82 The disparity between El and the sum of Ni & N2 is the sum of the BMP areas, which is 1,626 sf (0.04 ac). Modified Rational Method Results I To determine the hydrologic impact of the development, Q100 for El was compared with the confluence of Ni & N2, which was determined by a Modified Rational Method (MRM) analysis. The results of the analysis are shown in Table 2 below. Table 2. Post-Development Flows at POC-I DMA tc min I in/hr Qioo cfs QT cfs Ni 5 7.11 5.71 6.53 N2 5 7.11 0.82 6.53 Qioo 6.53 cfs t 5 mm I I, 1 3 I Peak Flow Comparison Table 3 below outlines the comparison of Qioo for the existing and proposed conditions, indicating that the proposed condition I mitigates an increase in runoff while increasing time of concentration. The decrease in Qioo can be attributed to the slight increase in pervious area due to the proposed BMPs in post-development conditions. The increase in t is likely the result of - shallower slopes in the proposed condition. The Modified Rational Method analyses results in a decrease of Qioo in the post- development condition; therefore, it was not apt to perform a routing analysis. Table 3. Peak Flow Comparison Summary Condition A ac Tc min Q cfs Pre-Development 1.06 5 6,67 Post-Development 1 1.06 1 5 1 6.53 Change 0.00 0.00 -0.14 % Difference 0.00 0.0% -2.1% 1.5 Summary of Hydraulics Results See Appendix A to see the storm drain layout for the project site. Storm Drain Pipes There are nine (9) proposed private storm drain pipes, denoted as P1 through P9. The following table summarizes the storm drain pipe properties and flow depths corresponding to post-development Qioo. Table 4.Manning's Equation Results for Proposed Pipes Pipe Upstream DMAs Q100 cfs d in n h in Ix ff2 P ft R ft S ft/ft v ft/s P1 R2 5.53 18 0.013 9.7 0.98 2.48 0.39 085% 5.7 P2 R2 5.53 18 0.013 6.3 0.55 1.90 0.29 4.1% 10.1 P3 NI 5.71 12 0.013 6.0 0.40 1.58 0.25 10.0% 14.4 P4 Ni 5.71 12 0.013 5.2 0.33 1.43 0.23 17.1% 17.6 P5 NI +R2 11.24 18 0.013 9.3 0.93 2.41 0.38 4,05% 12.1 P6 N2 0.82 6 0.013 3.1 0.10 0.80 0.13 7.9% 8.1 P7 Ni +N2 +R2 12.06 24 0.013 14.9 2.05 3.63 0.56 0.6% 5.9 P8 Ri 13.34 24 0.013 16.0 2.22 3.81 0.58 0.6% 6.0 P9 Ri 13.34 24 0.013 6.8 0.73 2.24 0.33 11.5% 18.3 Where: d = diameter of pipe (in); n = Manning's roughness coefficient = 0.013 (per San Diego County Hydraulic Design Manual); S = pipe slope (ft/ft); h = flow depth (ft); AX = cross-sectional area of flow (ft2); P = wetted perimeter (ft); R = hydraulics radius (ft); and, v = flow velocity (ftls) Where erosive flows may occur, e.g. pipes flowing to BMPs, downstream riprap energy dissipaters and headwalls have been employed (see Appendix A). 4 I Storm Drain Channels There are two (2) storm drain channels that convey flow from minor areas within their respective contributing DMAs. The following table summarizes the storm drain channel properties and flow depths corresponding to post-development Qioo. Table 5. Manning's Equation Results for Proposed Channels Channel Upstream DMAs Qioo cfs H ft W ft n h ft Fb ft A ft2 P ft R ft S ft/ft v ft/s DI Part of NI 0.06 0.5 2.0 0.015 0.06 0.44 0.03 0.68 0.04 3.8% 2.2 D2 Part ofN2 0.47 0.5 2.0 0.015 0.18 0.32 0.15 1.27 0.12 1.9% 3.2 Where: H = max depth of channel (ft); W = max top width of channel (ft); n = Manning's roughness coefficient = 0.015 (per San Diego County Hydraulic Design Manual); h = flow depth (ft); Fb = available freeboard (ft); AX = cross-sectional area of flow (ft2); P = wetted perimeter (ft); R = hydraulics radius (ft); S = channel slope (ft/ft); and, v = flow velocity (ftls) As Table 5 indicates, all channels are sufficiently sized to convey Qioo flows in post-development condition. Qioo for the channels were determined by assuming a time of concentration of 5 minutes, since the areas are relatively small and are unlikely to yield a t larger than 5 minutes. 1.6 References San Diego County Hydrology Manual, 2003 San Diego County Hydraulic Design Manual, 2014 City of Carlsbad BMP Design Manual (2016) USDA Websoil Survey 5 I 1.7 Declaration of Responsible Charge I hereby declare that I am the Engineer of Work for this project, that I have exercised responsible charge over the design of I the project as defined in Section 6703 of the Business and Professions Code, and that the design is consistent with current standards. I understand that the check of project drawings and specifications by the County of San Bernardino is confined to a review only and does not relieve me, as Engineer of Work, of my responsibilities for project design. I Bruce A. Robertson, R.C.E. 48529 I I I I I I I CHAPTER 2- METHODOLOGY All calculations per the Methodology described in this section can be found in Appendix B. 2.1 Design Criteria Per section 6.2.1 of the San Diego Hydraulic Design Manual: "Where there are undersized facilities downstream and when a basin is being used to mitigate post project downstream impacts, the basin capacity and outlet shall be designed such that the post-project peak flow rate shall be less than or equal to the pre-project flow rate for all frequency storms up to and including the 100-yr event." For water quality and hydromodification purposes, we have employed Biofiltration BMPs (i.e. basins) to manage and treat flows; therefore, the above provision pertains to this project and we demonstrate that the requirement is fulfilled by mitigating the 100-yr peak event while negligibly impacting the time of concentration. 2.2 Hydrology All methods in the "Hydrology" section comply with the San Diego County Hydrology Manual (2003), hereafter referred to as "Hydrology Manual". Per the Section 2.3, the Rational Method or Modified Rational Method shall be used for drainage areas between 0 and 1 square-mile. Rational Method The Rational Method was performed per Section 3 of the Hydrology Manual and was applied for the existing and proposed conditions. The equation for the Rational Method is as follows. Q = CIA (Equation 1) 1 Where: Q = peak flow rate (cfs); = peak rainfall intensity (in/hr); and, A = contributing drainage area (ac) 1 The Rational Method does not yield a hydrograph, it can only determine the maximum runoff flow rate for a design storm. For this Drainage Study, the design storm is the 100-yr storm event. Runoff Coefficient (C) Per Section 3.1.2 of the Hydrology Manual, the runoff coefficient (C) represents the fraction of precipitation that becomes runoff. For each drainage area, "C" was determined using the following equation. I = 0.90a + Ca (Equation 2) Where: C = dimensionless runoff coefficient; ai = impervious fraction of contributing area = (impervious area within DMA) I (total DMA area); Cp = dimensionless runoff coefficient for pervious areas, 0.35 for soil type D per Table 3-1 of the Hydrology Manual; and, pervious fraction of the contributing area = 1 - a From the USDA Websoil Survey, it was determined that the site was underlain with soil designated as Hydrologic Soil Group (HSG) D. Rainfall Intensity (I) Per Section 3.1.3 of the Hydrology Manual, peak rainfall intensity (I) represents the rate at which precipitation falls within a given time increment. "I" can be determined using the following equation. I = 7.44P6 t-0.641 (Equation 3) Where: I = peak rainfall intensity (in/hr); P6 = adjusted 6-hr rainfall for a given storm event (in); and, = time or duration (mm) (if t is less than 5 mins, use 5 mins in determining peak Q) 7 d Li U I I I 1 I I 111 I For the Rational Method, we are concerned with the peak "I"; therefore, "t" is the time of concentration (ta) (explained below) for the 100-yr storm event. Per Figure 3-1 in the Hydrology Manual, t has a minimum value of 5 minutes. The 100-yr "P6' value can be found using the Rainfall Isopluvials in the Hydrology Manual. As mentioned above, P6 is an adjusted value; P6 must be greater than or equal to 45% and less than or equal to 65% of the 24-hr precipitation (P24). P24 can also be determined using the provided isopluvials in the Hydrology Manual. I Time of Concentration (tl Per Section 3.1.4, the time of concentration (ta) refers to the time it takes for runoff from the most remote point within the watershed to reach the outlet. The time of concentration can be determined using the following equation. I tc = tC + tt (Equation 4) Where: t time of concentration (mm), I td = initial time of concentration (mm) = 1.8*(1.1 - C)*L1/2 / S113 (from Figure 3-3 in Hydrology Manual); C = dimensionless runoff coefficient of the initial area; L = distance for sheet flow to become concentrate flow (ft); s = slope of initial area (%); and, 1 tt = travel time of concentrated flow (mm) - As Equation 3 indicates, tc consists of an initial time of concentration (t1) and travel time (ti). The initial time of concentration I represents the duration associated with initial precipitation that becomes runoff to concentrate from sheet flow. "t1" is dependent on impervious fraction (ai) and slope of the initial subarea (see Table 3-2 of the Hydrology Manual). Travel time (ti) is the estimated time it takes for flow to travel along the flow path. It is estimated by dividing the average flow :I velocity (v) into the flow length per the following equation. = (Equation 5) 1 Manning's equation (shown below) was applied to determine the flow velocity along the flow path. Q = (Equation 6) Where: Q = pipe flow (cfs), n = Manning's roughness coefficient = 0.013 (per San Diego County Hydraulic Design Manual); A = cross-sectional area of flow (ft2) R = hydraulic radius (ft) = NP; P = wetted perimeter (ft); and, S = pipe slope (ft/ft) [;] 2.3 Hydraulics All methods in the "Hydraulics" section comply with the San Diego County Hydraulic Design Manual (2014), hereafter referred to as "Hydraulics Manual". Grated Inlets in Sag BMP-i and BMP-2 have grates to manage large flows. Per the "Grated Inlets in Sag" section in Chapter 2 of the Hydraulics Manual, the following equation can be used to determine the flow capacity of the grates flowing as weirs. Q = CPd (Equation 7) Where: Q = inlet capacity of the grated inlet (cfs), CW = dimensionless weir coefficient = 3,0; Pe = effective grate perimeter length (ft) = (1CL)*P; CL = dimensionless clogging factor = 0.50; P = actual grate perimeter (ft) = 18.4 ft (BMP-1) and 9.2 ft (BMP-2) (see below) d = flow depth approaching inlet (ft) = 0.33' (BMP-1) and 0.25' (BMP-2) (see below) A San Diego Regional Standard Drawing (SDRSD) D-15 grate has a perimeter length of 9.2 ft. BMP-i has an overflow catch basin with two (2) D-15 grates, while BMP-2 only has one. The available head to BMP-i was determined to be 4(0.33') to ensure that the post-development Qioo from Ni will be sufficiently conveyed. Furthermore, the available head to BMP-2 was determined to be 3(0.25') to ensure that the post-development Qioo from N2 will be sufficiently conveyed. Pipes and Channels Sizing the proposed pipes and channels was performed using the Manning's Uniform Flow Equation shown in Equation 6. Per Appendix A of the Hydraulics Manual, the following table outlines the 'n' values used in this study. Table 6. Manning's Roughness Coefficient (n) Surface I Conduit Material Reference n Concrete Gutter Table A-i 0.015 Concrete Pavement Table A-i 0.014 Reinforced Concrete Pipe (RCP) Table A-2 0.013 Smooth Plastic Pipe (PVC) Table A-2 0.013 Air Blown Concrete (Channels) - 0.5-2' of flow depth Table A-3 0.019 CHAPTER 3- CONCLUSIONS In conclusion, the proposed development is expected to reduce the total peak flow leaving the property by 2.1% while mitigating a change to the time of concentration during the i 00-yr storm events. Furthermore, all hydraulic structures employed in the site design have been sufficiently sized to convey their respective peak flows. I I I I I 1 1, I I I Li I 1 I I I I I APPENDIX A Location Map Pre-Development Drainage Area Map Post-Development Drainage Area Map Proposed BMP Details USDA Websoil Survey Soil Map (E) BUILDIP N L I\0.86 ac) - I _ _ (E) BUILDING ---- / 09 LOCATION MAP 0 N TS \ 317 318 377 (E) HANGAR 1.06 ac) (317.4) FF I / RCP I (E) CONCRETE / CHANNEL 5 76 Iiuutr:=,-j i I I POC-1 [Q100 = 6.67 cfs - - \/L(E)CONCRETE CHANNEL (E) CONCRETE---, I I I I I I I I [] [I I I I 1 I I LEGEND (E): EXISTING; (N ): NEW/ PROPOSED DMA LABEL - - - - FLOW DIRECTION DMA BOUNDARY LEASEHOLD LINE (PROPER I Y) EXHIBIT NOTES DMAsRi & R2 ARE UNDISTURBED RUN-ON AREAS; ANALYZED FOR SIZING HYDRAULIC STRUCTURES. STRUCTURAL BMPS, BMP-1 & BMP-2, WERE INCORPORATED TO MEET WATER QUALITY & HYDROMODIFICATION REQUIREMENTS FOR DMAs Ni & N2 ENTIRE SITE IS UNDERLAIN WITH HYDROLOGIC SOIL GROUP 0 PER GEOTECH REPORT, NO GROUNDWATER WAS ENCOUNTERED AT 21.5'. TI IE SITE DOES NOT CONTAIN ANY EXISTING NATURAL HYDROLOGIC FEATURES (WATERCOURSES, SEEPS, SPRINGS, WETLANDS) THE SITE DOES NOT CONTAIN ANY CRITICAL COARSE SEDIMENT YIELD AREAS TO BE PROTECTED I 60 30 0 60 120 180 PALOMAR AIRPORT ROAD I SCALE: 1" = 60' App A.1 PRE-DEVELOPMENT DRAINAGE AREA MAP ROYAL JET REMODEL I I t_ W~_.4 cl - p410_20 _ 41 80 1211 -- __ SCALE: 1 _• -- p5 71 /()18" RCP (SD)f -- PALOMAR AIRPORT ROAD ( 0.8 c;) \ P8 L (N) TRENCH DRAIN ID I •. I - Ni p 0.66 ac 0 •;<./• Z ( 1 \O.6ay_ cl •\ P V. . / p 'V (N) BLDG EXTENSION 317.4 FF 4 (E) HANGAR (317.4) FF \ II N) IRENUHURAIN p - - i7 _ ,1< / - 7-1 (N) 24 RCP (SD) {P9\\ \ - N2 1(E) 24" RCP (SD) 013 /-(E) CONC. CHANNEL I C2 v . I 2' -0 BMP-2 --4(N)6" PVC (SD) Poc-1 P5 0100 = 6.53 cfs \(N) HEADWALL \(E) CONC. CHANNEL DMA TYPE / NOTES Ni DRAINS TO STRUCTURAL BMP - BIOFILTRATION BMP (BMP-1) DRAINS TO STRUCTURAL BMP - BIOFILTRATION BMP (BMP-2) N2 Ri DRAINS TO PROPOSED TRENCH DRAIN - BYPASSES BMPs R2 DRAINS TO PROPOSED TRENCH DRAIN - BYPASSES BMPs EXHIBIT NOTES LEGEND DMAs Ri & R2 ARE UNDISTURBED RUN-ON AREAS; SEE PRE-DEVELOPMENT DRAINAGE AREA MAP STRUCTURAL BMPS, BMP-1 & BMP-2, WERE INCORPORATED TO MEET WATER QUALITY & HYDROMODIFICATION REQUIREMENTS FOR DMAs Ni & N2 ENTIRE SITE IS UNDERLAIN WITH HYDROLOGIC SOIL GROUP D PER GEOTECH REPORT, NO GROUNDWATER WAS ENCOUNTERED AT 2i.5'. THE SITE DOES NOT CONTAIN ANY EXISTING NATURAL HYDROLOGIC FEATURES (WATERCOURSES, SEEPS, SPRINGS, WETLANDS) THE SITE DOES NOT CONTAIN ANY CRITICAL COARSE SEDIMENT YIELD AREAS TO BE PROTECTED (E): EXISTING; (N): NEW/ PROPOSED DMA LABEL -. -. -- FLOW DIRECTION DMA BOUNDARY LIMITS OF WORK LEASEHOLD LINE (PROPERTY) PIPE LABEL CHANNEL LABEL App A.2 POST-DEVELOPMENT DRAINAGE AREA MAP ROYAL JET REMODEL L SEE GRADING PLAN OUTFALL PIPE SIZE- PER GRADING PLAN I 1 SIN TOP AREA (SEE BMP TABLE) BMP AREA (SEE BMP TABLE) NJ BOTTOM AREA (SEE BMP TABLE) I SDRSD D-08 CATCH BASIN 'T SEE "B" FOR TYPE BA I- BASI PLANTING PER CITY APPROVED PLANT LIST [ PVC SCREW CAP IMPERMEABLE LINER AROUND BMP NON—PERFORATED STANDPIPE USE 45 WYE & FITTING OR EQUIV. DIRECTIONAL CLEANOUT TO CONNECT UNDERDRAIN TO STANDPIPE WATER TIGHT CAP ON TERMINAL END OF PIPE NOTES: SOIL MIX PER CITY OF SAN DIEGO LID MANUAL "WELL DRAINED SOIL" SHALL BE "SANDY LOAM" SOIL MIX WITH NO MORE THAN 5% CLAY CONTENT. THE MIX SHALL CONTAIN 50-60% SAND, 20-30% COMPOST OR HARDWOOD MULCH, AND 20-30% TOPSOIL. BEST MANAGEMENT PRACTICE (BMP) TABLE BMP# BMP TYPE BASIN TOP AREA BMP AREA BASIN BOT AREA CATCH BASIN TYPE BMP-1 BIOFILTRATION (BF-1) 1313 SF 1153 SF 620 SF DOUBLE G-2 BMP-2 BIOFILTRATION (BF-1) 1 540 SF 474 SF 285 SF SINGLE G-1 I ' - SCH 40 MALE ADAPTER (MiTPxSoC) CLASS II PERM ____ / SCH 40 PVC THREADED STORAGE LAYER END CAP (FP 1) PERFORATED 6" ° DRILL ORIFICE AT FLOWLINE OF END CAP PVC UNDERDRAIN (SEE TABLE TO RIGHT) CLASS II PERM—/' I STORAGE LAYER I I J k NATIVE SOIL LINED BASIN I fflTH Th l END CAP w/ FLOW CONTROL ORIFICE PER DETAIL BELOW TABULATED DATA BMP1 BMP2 A 14" 9" B DOUBLE G-2 SINGLE G-1 C 18" 18" D 8" 8" E F 4" 4" C 6" 6" H 6" 6" I 14" 9" J 18" 12" ORBMP IFICE DIAMETER DIAMETER 7/8- 2 1 1/4" ORIFICE DETAIL N TS App A.3 POST-DEVELOPMENT BMP & OUTLET DETAILS ROYAL JET REMODEL Hydrclogic Soil Group—San Diego County Area, California (Palomar Airport HSG) 1 __ 33 738" N _______ I - 33 7 38" N AL I g _ I I U - V i 'S g I - - - V - - - - - 33 732"N Ii 732" 8 I - V 4T4373 - 4 441~, 474430 4744E0 Map Se: 1:791 if pdnt ionAx)rtI-aIt(8.5'x 11') sheet. MeLrs — N 0 10 20 40 60 I 0 35 70 140 210 Map paection Web Mercator Come- cooe1ina WGS84 Edge tss: UTM Zone uN WG584 I USDA Natural Resources Web Soil Survey 4/4/2017 Conservation Service Nat onal Cooperative Soil Survey Pagel oF 4 I Hydrologic Soil Group—San Diego County Area, California Palomar Airport HSG Hydrologic Soil Group Hydrologic Soil Group— Summary by Map Unit - San Diego County Area, California (CA638) Map unit symbol Map unit name Rating Acres in AOl Percent of AOl LvF3 Loamy alluvial land- D 1.3 100.0% Huerhuero complex, 9 to 50 percent slopes, severely eroded Totals for Area of Interest 1.3 100.0% Description Hydrologic soil groups are based on estimates of runoff potential. Soils are assigned to one of four groups according to the rate of water infiltration when the soils are not protected by vegetation, are thoroughly wet, and receive precipitation from long-duration storms. The soils in the United States are assigned to four groups (A, B, C, and D) and three dual classes (AID, BID, and CID). The groups are defined as follows: Group A. Soils having a high infiltration rate (low runoff potential) when thoroughly wet. These consist mainly of deep, well drained to excessively drained sands or gravelly sands. These soils have a high rate of water transmission. Group B. Soils having a moderate infiltration rate when thoroughly wet. These consist chiefly of moderately deep or deep, moderately well drained or well drained soils that have moderately fine texture to moderately coarse texture. These soils have a moderate rate of water transmission. Group C. Soils having a slow infiltration rate when thoroughly wet. These consist chiefly of soils having a layer that impedes the downward movement of water or soils of moderately fine texture or fine texture. These soils have a slow rate of water transmission. Group D. Soils having a very slow infiltration rate (high runoff potential) when thoroughly wet. These consist chiefly of clays that have a high shrink-swell potential, soils that have a high water table, soils that have a claypan or clay layer at or near the surface, and soils that are shallow over nearly impervious material. These soils have a very slow rate of water transmission. If a soil is assigned to a dual hydrologic group (AID, B/D, or C/D), the first letter is for drained areas and the second is for undrained areas. Only the soils that in their natural condition are in group D are assigned to dual classes. USDA Natural Resources Web Soil Survey 4/4/2017 Conservation Service National Cooperative Soil Survey Page 3 of 4 APPENDIX B Hydrology Calculations Hydraulics Calculations Royal Jet Remodel Hydrology Calculations Precipitation P6 2.1 in P24 5.0 in P6/P24 0.54 P6,adj 2.7 in rre-ueveiojmepi i<a[ion' ivietno' uaicuiations DMA A sf A ac L ft S ft/ft a,i C Li ft Ti min Ii in/hr Ai sf Qi cfs El 46173 1.06 160 0.040 0.97 0.88 65 1.97 7,11 4895 0.11 DMA hi ft zi Axi ft2 Pi ft Ri ft n vi ft/s Qi cfs L2 ft v2 I Ills It mm El 0.08 50 0.29 1.7 0.04 0.014 2.4 0.71 95 4.7 0.44 DMA Tc min I in/hr Q cfs z2L z2R n2 h2 ft Ax2 ft2 1 v2 ft/s El 2.41 7.11 6.67 50 0.125 0.015 0.24 1 1.41 4.7 Ri in-nn Arpq Rf rnll Methnd (Thin iItinnc (fnr Hvdri ilinc ci7inn' DMA A sf A ac L ft S ft/ft a,i C Li ft Ti min Ii in/hr Rl 90785 2.08 192 0.020 1.00 0.90 70 2.39 7.11 R2 37613 0.86 156 0.020 1.00 0.90 70 2.39 7.11 DMA hi ft zi Axi ft2 P1 ft Ri ft n vi ft/s I Qi cfs L2 ft Rl 0.07 50 0.24 7.0 0.03 0.013 1.7 0.42 122 R2 0.05 50 0.10 4.5 0.02 0.013 1.3 0.13 86 DMA Ic min I in/hr Q cfs z2L z2R n2 h2 ft Ax2 1t2 v2 ft/s Rl 3.04 7.11 13.34 50 0.125 0.014 0.34 1 2.92 4.6 R2 3.02 1 7.11 5.53 1 50 50 0.013 0.18 1 1.68 3.3 Ai Qi sf cfs 2874 0.42 905 0.13 v2 It Ills mm 4.6 0.65 3.3 0.63 App B.l Hydrology Page 1 of 2 vos-ueveioIDmenr_auopi_iviernoa_aicuiauons DMA A sf A ac L ft S ft/ft a,i C Li ft Ti min Ii in/hr Ai si Qi cfs Ni 38960 0.89 192 0.035 0.996 0.898 60 1.86 7.11 2874 0.42 N2 5586 0.13 156 0.010 0.988 0.893 60 2.88 7.11 905 0.13 DMA hi ft zi Axi ft2 Pi ft Ri I ft n vi ftis Qi cfs [2 ft v2 ft/s It mm Ni 0.06 50 0.21 6.5 0.03 0.014 2.0 0,42 132 4.3 0.69 N2 0.05 50 0.14 5.3 0.03 0.014 0.9 0.13 96 1.7 1.23 DMA Tc min I in/hr Q cfs z2L z2R n2 h2 ft Ax2 ft2 v2 ft/s Ni 2.55 7.11 5.71 50 0.125 0.015 0.23 1.32 4.3 N2 4.11 7.11 0.82 50 0.125 0.015 0.14 0.49 1.] I Calculations vosi-ueveiopmen_ivioair'eai<auonai ivietno DMA Tc min I in/hr Q cfs QT cfs Ni 2.55 7.11 5.71 6.22 N2 4.11 7.11 0.82 6.53 Q 6.53 cfs Tc 4.11 mm 0100 Comparison Condition Tc min Q cfs Pre-Development 2.41 6.67 Post-Development 4.11 6.53 Change 1.69 1 -0.14 % Difference 170.1%1 -2.1% App B.i Hydrology Page 2 of 2 Mao - - IMM MM - - - - - - - M==M Royal Jet Remodel Hydraulics Calculations Hydraulics Calculations (Pioe Pipe Upstream DMAs Q100 cfs d in n a deg h in Ax ft2 P ft R ft S ft/ft v ft/s Grading Plan Tags P1 R2 5.53 18 0.013 189 9.7 0.98 2.48 0.39 0.85% 5.7 Li P2 R2 5.53 18 0.013 145 6.3 0.55 1.90 1 0.29 4.05% 10.1 L2 P3 Ni 5.71 12 0.013 181 6.0 0.40 1.58 0.25 10% 14.4 L12 P4 Ni 5.71 12 0.013 164 5.2 0.33 1.43 0.23 17.1% 17.6 L3 P5 Ni + R2 11.24 18 0.013 184 9.3 0.93 2.41 0.38 4.05% 12.1 L4+C1 + L5 + C2 + P6 N2 0.82 6 0.013 138 1.9 0.05 0.60 1 0.09 41.9% 14.9 L7 P7 Ri 13.34 24 0.013 219 16.0 2.22 3.81 0.58 0.57% 6.0 L8 + L9 + L10 P8 Ri 13.34 24 0.013 128 6.8 0.73 2.24 0.33 11.5% 18.3 Lii Determination ot Q1UiJ tor I-'ipe F (uontluenre Analysis) DMA Tc min I in/hr Q cfs QT cfs Ni 2.55 7.11 5.71 10.39 R2 3.02 7.11 5.53 11.24 Q 11.24 cfs Tc 3.02 mm I-IvdriiIirs (kiiItinns (ChnnI'i Channel Upstream DMAs Qioo cfs H ft W ft n h ft Fb ft Ax ft2 P ft R ft S ft/ft v ft/s Di Part of Ni 0.06 0.5 2.0 0.015 0.06 0.44 0.03 0.68 0.04 3.8% 2.2 D2 Part ofN2 1 0.47 1 0.5 2.0 0.015 0.18 0.32 0.15 1.27 0.12 1.9% 3.2 flfermintinn nf (1flfl ('.nntrihiitinri tn (hnnis DMA Tc min I in/hr A sf Q cfs Part ofNl <5min. 7.11 401 0.06 Part of N2 <5 min. 7.11 3220 0.47 App B.2 Hydraulics Page 1 of 1 Royal Jet Remodel Hydrology Calculations P6 2.7 in P24 5.0 in P6/P24 0.54 P6,adj 2.7 rue-ueveiopmeru i<auon2' ivietrioa ,alculaucls DMA A A L S a,i C Li Ti Ii Ai Qi sf ac ft ft/ft ft min in/hr sf cfs [1 46173 1.06 160 0.040 0.97 0.88 65 1.97 7.11 4895 0.71 DMA hi zi Axi Pi Ri n vi Qi L2 v2 TI ft ft2 ft ft ft/s I cfs ft I ft/s mm El 0.08 50 0.29 7.7 0.04 0.014 2.4 0.71 95 4.7 0.44 DMA Tc I Q z2L z2R n2 h2 Ax2 v2 min in/hr cfs ft ft2 ft/s El 5 7.11 6.67 50 0,125 0.015 0.24 1.41 1 4.7 Piinnn Anon PtInn2I Nliathnri ('2Ir'IIItirnc (fnr Pvtlmi dirc ci7inrl\ . ................................ DMA A A L S a,i C Li Ti Ii Ai Qi sf ac ft ft/ft ft min in/hr sf cfs Ri 90785 2.08 192 0.020 1.00 0.90 70 2.39 7.11 2874 0.42 R2 37613 0.86 156 0.020 1.00 0.90 70 2.39 7.11 905 0.13 DMA hi zi Axi Pm Ri n vi Qi L2 v2 TI ft ft2 ft ft ft/s cfs ft ft/s mm Ri 0.07 50 0.24 7.0 0.03 0.013 1.7 0.42 122 4.6 0.65 R2 0.05 50 0.10 4.5 0.02 0.013 1.3 0.13 86 3.3 0.63 DMA Tc I Q z2L z2R n2 h2 Ax2 v2 min in/hr cfs ft ft2 ft/s Ri 5 7.11 13.34 50 0.125 1 0.014 0.34 2.92 4.6 R2 5 1 7.11 5.53 50 50 1 0.013 0.18 1.68 3.3 in I I I I I App B.1 Hydrology Page 1 of 2 i-'osi-ueveiopmenii<auonai ivietnoa Laicuiations DMA A SI A ac L ft S ft/ft ai C Li ft Ti min Ii in/hr Ai SI 01 cfs Ni 38960 0.894 192 0.035 0.996 0.898 60 1.86 711 2874 0.42 N2 5586 0.128 156 0.010 0.988 0.893 60 1 2.88 7.11 905 0.13 DMA hi ft zi Axi ft2 P1 ft Ri ft n vi ft/s 01 cfs L2 ft v2 ft/s It mm Ni 0.06 50 0.21 6.5 0.03 0.014 2.0 0.42 132 4.3 0.69 N2 0.05 50 0.14 5.3 0.03 0.014 0.9 0.13 96 1.7 1.23 DMA Tc min I in/hr 0 cfs z2L z2R n2 h2 ft Ax2 ft2 v2 ft/s Ni 5 7.11 5.71 50 0.125 0.015 0.23 1.32 4.3 N2 5 7,11 0.82 50 0.125 0.015 0.14 0.49 1.7 DMA Tc min I in/hr 0 cfs QT cfs Ni 5 7.11 5.71 6.53 N2 5 7.11 0.82 6.53 0 6.53 cfs Tc 5.00 mm 0100 Comparison Condition A ac Q Tc min cfs Pie-Development 5.00 5.00 6.67 Post-Development 5.00 5.00 6.53 Change 0.00 0.00 -0. 14 % Difference 0.0% 0.0% J_-2.1% I I I I I I I App B.i Hydrology Page 2 of 2 1 I I LI LI fl H I I I I I H Pnct-flp,pInnmpnt Modified Rational Method Calculations Royal Jet Remodel Hydraulics Calculations Hydraulics Calculations (Pipe) Pipe Upstream DMAs 0100 cfs d in n a deg h in Ax ft2 P ft R ft S ft/ft v ft/s Grading Plan Tags P1 R2 5.53 18 0.013 189 9.7 0.98 2.48 0.39 0.85% 5.7 Li P2 R2 5.53 18 0.013 145 6.3 0.55 1.90 0.29 4.05% 10.1 L2 P3 Ni 5.71 12 0.013 181 6.0 0.40 1.58 0.25 10% 14.4 L12 P4 Ni 5.71 12 0.013 164 5.2 0.33 1.43 0.23 17.1% 17.6 L3 P5 Ni + R2 11.24 18 0.013 184 9.3 0.93 2.41 0.38 4.05% 12.1 L4 + Ci + L5 P6 N2 0.82 6 0.013 182 3.1 0.10 0.80 0.13 7.9% 8.1 L6 P7 Ni + N2 + R2 12.06 24 0.013 208 14.9 2.05 3.63 1 0.56 0.57% 1 5.9 1 L7 P8 Ri 1 13.34 1 24 1 0.013 219 1 16.0 1 2.22 3.81 0.58 0.57% 1 6.0 1 L8 + L9 + L10 P9 Ri 1 13.34 1 24 1 0.013 128 1 6.8 1 0.73 2.24 1 0.33 11.5% 1 18.3 1 L 1 flfrminit rn nf fli fill fnr Pino P (('nnfli wonrin Anhui DMA Tc min I in/hr 0 cfs 01 cfs Ni 5 7.11 5.71 11.24 R2 5 7.11 5.53 11.24 Q 11.24 cfs Tc 5 mm Hydraulics Calculations (Channel) Determinaton ot U10U tor IIre 11 ((ontluence Analysis DMA Tc min I in/hr Q cfs 01 cfs N1+R2 5 7.11 11.24 12.06 N2 5 7.11 0.82 12.06 Q 12.06 cfs Tc 5 mm Channel Upstream -QIOO DMAs cfs H ft W ft n h ft Fb ft Ax ft2 P ft R ft S ft/ft v ft/s Di Part of Ni 0.06 0.5 2.0 0.015 0.06 0.44 0.03 0.68 0.04 3.8% 2.2 D2 Part ofN2 0.47 0.5 1 2.0 1 0.015 0.18 1 0.32 1 0.15 1.27 0.12 1 1.9% 1 3.2 Determination of 0100 Contributinq to Channels DMA Tc min I in/hr A sf Q cfs Part of Ni <5min. 7.11 401 0.06 Part ofN2 <5min. 1 7.11 1 3220 0.47 App B.2 Hydraulics Page 1 of 1