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Floodplain Study.pdfParcel # 27032400214600 Prepared by: EdMcCarthy, P.E.'P.S. 0Q57171 m Avenue SE Renton, VVA0O050 Tel. /425>271'5734 Fax (425)271-3432 Prepared for: EuhoKoarmgrHonmes &Lund 4001 198t7 St. 8VV#2 Lynnwood, WA 98036 November 11.2O14 1. Background Information............................................................................................. 1-1 2. Characteristics of Creek and Basin............................................................................. 2-1 3. Floodplain Assessment............................................................................................... 3-1 4. Limitations.................................................................................................................. 4-1 5. References...................................................................................................................5-1 Figure1. Vicinity Map.................................................................................................... 1-2 Figure2. Soils Map......................................................................................................... 2-4 Figure3. Basin Map........................................................................................................ 2-5 Figure 4A. Floodplain/Floodway Map — Existing Site Conditions ................................ 3-3 Figure 4B. Floodplain/Floodway Map — Proposed Site Conditions ............................... 3-4 Appendix A. Photographs of the Creek System Appendix B. WWHM2012 Modeling Appendix B.I WWHM2012 Input Data Appendix B.2 WWHM2012 Peak Flow Rates Appendix C. Basin Information Appendix C.1 Land Use Zoning for Contributing Basin Appendix C.2 Basin Cover Types and Areas Appendix D. HEC -RAS Modeling N 1. BACKGROUND INFORMATION The Caspers Short Plat property is located at 307 Caspers Street in Edmonds (Figure 1). The subject property is located within a catchment of the Shell Creels basin. Shell Creek is adjacent to the east property line of the project site. A FEMA floodplain map identifies a Zone A flood hazard area along the site east property boundary associated with Shell Creels (Appendix C.3). This report was prepared in response to a City of Edmonds information request. Plans for a 4 -lot short plat on the site have been submitted to the City for review. The City has asked for a floodplain study to evaluate the floodplain associated with Shell Creek on the subject site. The purpose of this report is to document the flood study conducted at the city's request and has been prepared in accordance with City of Edmonds ECDC 23.70.020.B -02.C. This report addresses the following topics: ■ Summary of basin contributing to the stream channel ® Summary of hydrologic modeling ■ Floodplain mapping ■ Description of proposed development and potential impacts on the floodplain The hydraulic evaluations presented in this report are intended to provide the following flood - related information for the project: ■ Delineate the 100 -year floodplain/floodway under along Shell Creels adjacent to the subject property. ■ Assess any impacts from the proposed project on the floodplain. ■ Describe any proposed changes in the drainage course and mitigations to accommodate those changes. ■ Calculate flood elevations for the 10 -year and 50 -year return periods on the subject property. 1-1 Caspers Shot Plat Flood Stud), Project Site Vicinity Map Gaspers Short Plat Flood Hazard Analysis Edmonds, Washington 3,000 Feet 9957 171 st Avenue SE Renton, Washington 98059 Phone: (425) 271-5734 Dale 11/11/14 2. CHARACTERISTICS OF CREEK AND BASIN 2.1 Description of Drainage Course in the Study Area The lower reach of Shell Creek flows along the east property boundary of the project site. The floodplain study area for the creek extends a distance of 264 feet from downstream of the subject property near the confluence with Hindley Creek to the property's upstream boundary. Based on surveyed data for the site, the reach the channel in the study area has a slope ranging from 0.7 to 2.8 percent. The average main channel width generally ranges from 4 to 8 feet with an ordinary high water depth of about one foot. Within the study area, the channel passes through a lightly forested area along the left bank and the backyards of single family residences along the right bank. The main channel has a gravel substrate. Overbank vegetation along the creek in the study area is predominately mature trees with scrub shrub cover types along the left bank and residential landscape along the right bank. A chain link fence spans the channel at the south boundary of the subject site. Two footbridges cross the channel on the residential properties along the study reach. A 2 -foot high earth flood protection berm has been constructed along the right bank of the channel at the downstream end of the study reach to protect the adjacent residential structure. 2.2 Contributing Basins The subject site is along the lower reach of Shell Creek. Tributary basins to the creek include Shell Creek basin, Good Hope Pond basin, and Westgate basin. Approximately 200 feet downstream from the subject site, Hindley Creek joins Shell Creek. A brief description of each of the tributary basins is provided below. Shell Creek Basin Shell Creels basin comprises a drainage area of 721 acres (City of Edmonds GIS, 2014), which includes the 172 -acre Hindley Creek subbasin. Hindley Creek empties into Shell Creek west of Brookmere Drive. In the winter months, the Goodhope Pond basin and Westgate basin overflow to the Shell Creek system. Shell Creel-, has a diversion structure that conveys high flows directly into Puget Sound via a pipe system. The Shell Creek diversion structure and fish ladder is located on Daley Street between 7th Avenue N and 8th Avenue N (Herrera Environmental Consultants, October 14, 2010). Good Hope Pond Basin Goodhope Pond basin is 446 acres (City of Edmonds GIS, 2014) and contributes flow to Shell Creel-, in the winter months. The surface area of Goodhope Pond ranges from approximately 1 2-1 Caspeis Shorl Mal Flood Sludv acre in late summer to 6 acres during the winter months (Herrera Environmental Consultants, October 14, 2010). Westgate Basin Westgate basin is 52 acres (City of Edmonds GIS, 2014) and contributes flow to Shell Creek in the winter months. The overflow outflow from the Westgate Pond was constructed as part of a capital improvement project in 1997 and drains to the Shell Creel-, system at 220th Street SW (Herrera Environmental Consultants, October 14, 2010). Hindley Creek Basin Hindley Creel-, drains a 172 -acre area (City of Edmonds GIS, 2014) that is predominately urban/residential. Hindley Creek discharges to Shell Creek 1,100 feet upstream from the mouth and is the primary tributary. Hindley Creek has a diversion structure that conveys high flows directly into Puget Sound via a pipe system. The Hindley Creel-, bypass begins at 9th Avenue N and Hindley Lane, where it enters the same pipe used for the Shell Creek bypass (Herrera Environmental Consultants, October 14, 2010). Basin Cover Types Soils in the basin are predominately mapped as the Alderwood Series and were modeled as glacial till (Hydrologic soil Group C) (Figure 2) (SCS, 1983). A small portion of the basin is mapped as Everett Series and was modeled as outwash (Hydrologic soil Group A/B). A summary of the soils series• in each of the contributing basins is provided in Table C.2.1. Cover types for contributing basin areas were based on the City's current land use zoning and aerial photographs (Figure C.1.1). The majority of the tributary basins areas are in residential zoning with varying densities. The amount of impervious area associated with each zoning land use was based on the density of the development using published values for commercial, multi- family residential, and different single-family residential densities (King County Department of Natural Resources, 2009). These calculated impervious values were then adjusted to determine the effective impervious area within each basin. Factors used to calculate effective impervious area are based on the level 'of density and are summarized in Table C.2.2. A detailed breakdown of the land cover type areas in each of the contributing basins, sorted by slope category and hydrologic soil group, is provided in Table C.2.3. These areas for cover types, broken out by slope and soil type, were used as input to the WWHM hydrologic model in determining the base flood flow to the study area. The flows from each of the contributing basins were modeled separately in WWHM2012 and routed through a representation of the channel reaches that convey the tributary flows to their junction points (Appendix B.1). Flows from the Shell Creek basin, Good Hope Pond basin, and Westgate Pond basin combine upstream of the subject site, whereas flows from Hindley Creek basin join Shell Creek shortly downstream from the subject site. 2-2 Caspers Short Plat Flood Sludy 2.3 Base Flood Flow Rate I developed a WWHM2012 (Western Washington Hydrologic Model) (Clear Creel', Solutions, 2012) routing model of the contributing basins to determine the base flood flow (100 -year peak flow rate) to the study area. The Everett rain gage was used applying a precipitation factor of 0.80. The WWHM2012 15 -minute time series was used in the hydrologic modeling. As a conservative measure, any stormwater detention associated with existing development in the basin was assumed be negligible. In addition, infiltration that occurs in the storage ponds located within Good Hope Pond basin and Westgate basin was not simulated, also providing a conservative estimate of flood flows. WWHM2012 model inputs for the basins are provided in Appendix B.1. Resulting 15 -minute peals flow rates from each basin and those for the study area are listed in Appendix 13.2. The 100 - year peak flow rate to the study area was estimated to be 397 cubic feet per second. Shortly downstream from the subject site, the 100 -year peak flow rate increases to 461 cubic feet per second with contributions from Hindley Creek. 2-3 Caspers Short Plat Flood Stun 1, Project Site Soils Map Pro No 9 ' Date Caspers Short Plat Flood Hazard 11/11/14 9957 171st Avenue SE Analysis 1,500 Renton, Washington 98059 Edmonds, Washington Feet Phone: (425)271-5734 Figure 2 Y Y It -Ft�. I l I �t� r ) 1 1 I Project tlewia _. i lt': �fz'1 Site C e s d'1 0 okz�te,{ r, i A r55.. � - r f _ ( u � Y" S tCt { E `St E fcesl§ Rd Jt , LI1 tfx t W! cz 1 05t� 6e c , _(_ek eY � E 1 ( �t, i_ Qntil t oil oa3 hel I l 0? I )is reek�r St 16th St Pro). No. Basin Map Dale Caspers Short Plat Flood Hazard 11/11/14 Analysis 9957 171 st Avenue SE 1,500 Renton, Washington 98059 Figure 3 Edmonds, Washington Feet Phone: (425) 271-5734 3. FLOODPLAIN ASSESSMENT 3.1 Flood Analysis Methods The hydraulic model HEC -RAS (Version 4.1.0) was used to evaluate the creek system in the study area. Flood Insuraiwe Study Guidelines and Specifications for Study Contractors (FEMA, 2007) were generally followed in conducting the floodplain analysis. A detailed field survey of the surrounding topography and creek was conducted by Pacific Coasts Surveyors, Inc. (November 2014). All elevation data used in developing the HEC -RAS cross sections are referenced to NAVD 88 vertical datum. Inputs for the main channel geometry were based on site specific cross section data. A visual inspection of the creek was conducted on November 4, 2014. Photographs of various portions of the creek within the study reach were taken during the field reconnaissance to document the channel's condition and character (Appendix A). The photographs, along with observations of channel substrate and vegetative cover, were also used to estimate the roughness coefficients for each reach of the channel (French, 1985). Based on observations of channel substrate and vegetative cover, a roughness coefficient of 0.035 was used for the main channel, representative of relatively clean channel bottoms with gravel and stones. A roughness coefficient ranging from 0.0.045 to 0.065 was used for forest and brush covered overbank areas along the left bank, representative of floodplains with light to medium -dense brush in winter months. A roughness coefficient of 0.035 was used to represent the residential landscape areas in the right overbank, which consisted of lawn. Residential structures in the overbank were observed to be largely outside the floodplain. Roughness coefficients and ineffective flow areas are identified in the channel cross sections provided in Appendix D. HEC -RAS was used to evaluate the backwater profiles in the channel for the 10 -year, 50 -year and 100 -year flow predicted rates. The zero -rise floodway limit was also calculated for the channel. The zero rise flood fringe is the portion of the floodplain that can be filled and still allow the floodway to convey the base flood flow without a measurable increase in flood height. A "measurable increase in flood height" is greater than or equal to 0.01 foot. Method 1 in HEC - RAS was used in conducting the encroachment analysis wherein an equal amount of encroachment from each bank was assumed until zero rise criteria had just been exceeded. 3-1 Casper s Short Plat Floor) Slu(ty 3.3 Flood Analysis Results Floodplain and FloodwaX HEC -RAS channel cross sections, channel profiles, and tabulated modeling results are presented in Appendix D. Appendix D also includes results for the zero -rise floodway modeling. Encroachments ranging from 2 to 5 feet from each bank define the flood fringe limits in the channel. The 100 -year floodplain was mapped for the project site for existing and proposed site conditions (Figures 4A and 4B). Water surface elevations for the 10 -year and 50 -year peak flow rates are also shown on Figures 4A and 4B. The 100 -year floodplain is within the creek's 100 - foot buffer. No encroachment into the floodplain will occur with development of the site. Floodplain Fill Neither Shell Creek nor its floodplain will be altered by the proposed project. Under the proposed development plan, no fill will be placed within the floodplain. 3-2 Caspers Short Plat Flood Study I z Q'7 32 f 1", 31— DO L'03 !-W LWII ca r 21 Ql) iE, "r Lq CN Al I z Q'7 32 f 1", 31— 1-W L'03 !-W r 1-W L'03 !-W C) C) CE) + C) Q') O Q) Lu wl, C3 i al 6 LO gi lk Y/ LLJ N� OD t.", LLJ O;r C) C) CE) + C) rL C) O Q) Q) 6 LO LO lk \j, it I V) _1_3� 3 N SV_ 3 . LIMITATIONS This report was prepared for use by Echelbarger Homes & Land. This report is not intended for use by others, except as authorized by Echelbarger Homes & Land. Floodplain elevations presented in this report are based on surveyed data for the study area. These data reflect the condition of the channel and hydraulic structures at the time of the survey. Other data were collected and analyzed using published methods according to generally accepted practices. If the conditions upon which our analysis is based change in the future, we reserve the right to modify our conclusions or recommendations. Within the limitations of scope, schedule and budget, our services have been executed in accordance with the generally accepted practices in this area at the time this report was prepared. No warranty or other conditions, express or implied, should be understood. 4-1 Caspers Short Plat Flood Study . REFERENCES City of Edmonds GIS, 2014. GIS shape files for city watersheds. Areas determined using ArcView. Edmonds, Wash. Clear Creek Solutions, 2012. Western Washington Hydrology Model Version 2014/5/28. Olympia, Wash. FEMA, January, 2007. Flood Insurance Study Guidelines and Specifications for Study Contractors. French, Richard, H., 1985. Open. -Channel Hydraulics. McGraw-Hill Book Company. New York. Herrera Environmental Consultants, October 14, 2010. Storm and Surface Water Management Comprehensive Plan — City of Edmonds. Seattle. King County Department of Development and Environmental Services, December 2003. DDES Bulletin 38 — Flood Insurance and FEMA. Seattle. King County Department of Natural Resources, 2009. King County Surface Vater Design Manual. Seattle. Pacific Coast Surveyors, Inc., November 2014. Topographic Suli,ey of Caspers Slzort Plat Property, Edmonds, Wash. Mill Creek, Wash. U.S. Department of Agriculture, Soil Conservation Service, 1983. Soil Survey of Snohomish Couno) Area, Washington. 5-1 Capers Short Plat Flood Study Appendices Appendix A. Photographs of the Creek System Appendix B. WWHM2012 Modeling Appendix B.1 WWHM2012 Input Data Appendix B.2 WWHM2012 Peak Flow Rates Appendix C. Basin Information Appendix C.1 Land Use Zoning for Contributing Basins Appendix C.2 Basin Cover Types and Areas Appendix C.3. FEMA FIS Map Appendix D. HEC -RAS Modeling Caspers Short Plat Flood Studd, Appendix A. Photographs of the Creek System Caspers Short Plat Flood Studi, Appendix B. WWHM2012'Modeling Casper s Short Plat Flood Sludv Appendix B.I. WWHM2012 Input Data Routing Reaches Reach Contributing Basin Downstream Connection Length FT Width FT Slope FT/FT R1 Hindley R2A 2,681 4 0.036 R2 Shell R2A 4,327 8 0.040 R2A 200 8 0.020 R3 R2 3,112 6 0.042 R4 Good Hope Pond R3 2,208 3 0.007 R5 Westgate R3 621 3 0.155 Caspers Short Plat Flood Stwil, Cas/vers Short Plat Flood Studd, Cashers Short Plat Flood StudV Caspes Short Plat Flood Study Casper s Short Plat Flood Studi, Caspeis Short Plat Flood Shaft, Appendix B.2. WWHM2012 Peak Flow Rates Peak Flow Rates 0501 = study reach through project site 0502 =junction at Hindley Creek Flow Frequency Curves 1000.0 100.0 0 LL 10.0 1.0 Cumulative Probability { 0.5 1 2 5 10 20 30 50 70 00 90 95 Caspeis Short Plat Flood Saida, 1000.0 100.0 + 501 x 542 1.0 9° 9999:51 Appendix C. Basin Information Caspers Short Plat flood Studv Appendix C.I. Land Use Zoning for Contributing Basins Caspow Short Plat Flood Study Project Site BD1I ±- -, �-- - --- J �J -j- BD2 J BN OS L P "T' --J RM -1,5 - I L I 'd, 1 711 5, J", RS -10 1J N� RS,1 2 J- -1_ 4- TIR v-1-- ili-d RS -6 —I —I —T�'f F VIA IRS -8 J Nq N. Land Use Map Caspers Short Plat Flood Hazard 1/14 9957 171 st Avenue SE Analysis 1,500 Renton, Washington 98059 Edmonds, Washington ---J Feet Phone: (425) 271-5734 Figure C.1.1 L --T - I L I 'd, 1 711 5, J", RS -10 1J N� RS,1 2 J- -1_ 4- TIR v-1-- ili-d RS -6 —I —I —T�'f F VIA IRS -8 J Nq N. Land Use Map Caspers Short Plat Flood Hazard 1/14 9957 171 st Avenue SE Analysis 1,500 Renton, Washington 98059 Edmonds, Washington ---J Feet Phone: (425) 271-5734 Figure C.1.1 Appendix C.2. Basin Cover Types and Areas Caspers Short Plat Flood Studv (13 I—Id Ic Lf)ININ Od•t—ctLOr - CY) IO � I O I C:) 0) l'O'O X1911! 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