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HomeMy WebLinkAboutWQ0000020_Report_20071026CWS] October 26, 2007 Ms. Loretta Beckwith U.S. Army Corps. of Engineers 151 Patton Avenue, Room 208 Asheville, NC 28801 Subject: Section 404 Individual Permit Application Asheville Regional Airport Expansion Fletcher, North Carolina CWS Project No. 2007-1889 The Asheville Regional Airport Expansion site is located adjacent to Interstate 26, on existing Airport Authority property in Fletcher, North Carolina (Sheets 1 and 2, enclosed). The purpose of this project is to develop approximately 33 acres into a mixed general aviation (GA) component for the airport which will include hanger space, offices and opportunity for the transfer and transport of goods and materials between groundside, at a four lane interstate highway, and airside, from the existing commercial grade airstrip, to serve Buncombe County and the Asheville region. Secondarily, the proposed fill at the facility will be fly ash produced as a byproduct from coal fired energy plants. The fly ash will be placed on geo-textile material and will be covered by 24" of natural soil cap. The current fly ash landfill is nearing capacity and it would need to expand or find a new facility in order to accommodate this fly ash. With the airport placing the material, the existing landfill will be able to gain approx. 8-10 years of storage capacity. Applicant Name: Asheville Regional Airport Authority, David N. Edwards, Jr. - Airport Director Mailing Address: 61 Terminal Dr., Suite 1, Fletcher, NC 28732 Phone Number of Owner/Applicant: 828-684-2226 Street Address of Project: Terminal Drive, Fletcher, NC Waterway: UT's to French Broad River Basin: French Broad (HU# 06010105) City: Asheville County: Buncombe Decimal Degree Coordinate Location of Project Site: N35.44612°, W82.54223° USGS Quadrangle Name: Skyland, North Carolina, 1991 Current Land Use The current land use for the project area is a commercial service airport. Dominant vegetation within the project area consists of red maple (Acer rubrum), ironwood (Carpinus caroliniana), tag alder Alnus serrulata), black gum (Nyssa sylvatica), black willow (Salix nigra), silky dogwood (Cornus amomum), soft stem rush (Juncus effusus), false nettle (Boehmeria cylindrica), jewel weed (Impatiens capensis), cinnamon fern (Osmunda cinnamomea), Christmas fern (Polystichum acrostichoides), and various sedges (Carex spp.) (Sheet 4, enclosed). According to the Soil Survey of Buncombe County', on-site soils consist of Tate Loam, 2-8% slopes (TaB), Hayesville Loam, 15-25 % slopes (HyE), Hayesville-Urban Land Complex, 2-15 % slopes and Braddock-Urban Land Complex, 2-15 % slopes Sheet 3, enclosed). 1 United States Department of Agriculture, Web Soil Survey. Soil Survey of Buncombe County, North Carolina. NORTH CAROLINA • SOUTH CAROLINA • NEW YORK 550 E WESTINGHOUSE BLVD. CHARLOTTE, NC 28273 704-527-1177 (v) 704-527-1133 (fax) z 07-1 X341 v?[Nwml OCT ?[ 96?? 2 9 2007 DENR - WATER QUALITY W RAIDS AND STOR IM.ATER BRANCH WWW.CWS-INC.NET October 26, 2007 Ms. Loretta Beckwith Page 2 of 9 National Wetlands Inventory The National Wetlands Inventory maps did not show any part of the project site mapped as wetlands Sheet 5, enclosed). FEMA Floodplain No portion of the project area or the proposed development is located within a FEMA regulated floodplain (Sheet 6, enclosed), therefore no FEMA floodplain will be impacted by the project activities. Buncombe County Zoning The existing site and proposed expansion are zoned for industrial use (Sheet 7, enclosed). No portion of the site will be rezoned for the purpose of this project. Jurisdictional Delineation On June 13, 2007 CWS's Ron Johnson, PWS, Matt Jenkins, WPIT, Paul Bright, and Anthony Nardo delineated (flagged in the field) and classified on-site jurisdictional waters of the U.S. using the U.S. Army Corps of Engineers (USACE) - Routine On-Site Determination Method. Jurisdictional waters of the U.S. were classified according to recent North Carolina Division of Water Quality (NCDWQ)2 and USACE guidance. NCDWQ Stream Classification Forms and USACE Stream Quality Assessment Worksheets representative of Streams A - C are enclosed (SCP 1 - SCP5). On-Site waters were determined to be jurisdictional according to the EPA/USACE Approved Jurisdictional Determination Forms. The results of the on-site field investigation indicate that there are three jurisdictional stream channels Streams A - C) and three jurisdictional wetland areas (Wetlands AA - CC) located within the project area (Sheet 8, enclosed). Routine On-Site Data Forms representative of Wetlands AA - CC as well as non jurisdictional upland areas have been enclosed (DP 1 - DP4). On-Site jurisdictional waters of the U.S. include unnamed tributaries to French Broad River. French Broad River is within the Upper French Broad basin (HU# 06010105) 3 and is classified as "B;Tr" waters by the NCDWQ. On-Site jurisdictional waters of the U.S. were surveyed by CWS using a sub-meter GPS unit and total approximately 0.465 acre (20,255 square feet). Linear footage and acreage of on-site jurisdictional waters are summarized in Table 1. Table 1. Summary of On-Site Jurisdictional Waters Jurisdiction Classification Approximate Length (1f)Approximate Acreage Stream A Perennial 1540 0.243 Stream B Unimportant Intermittent 92 0.005 Stream C Perennial 114 0.008 Stream Subtotal:1746 0.256 Wetland AA Herbaceous 0.028 Wetland BB Forested 0.009 Wetland CC Forested 0.172 Wetland Subtotal:0.209 On-Site Total:1746 0.465 2 North Carolina Division of Water Quality, 1999. Stream Classification Method. Version 2.0. 3 "HU#" is the Hydrologic Unit Code. U.S. Geological Survey, 1974. Hydrologic Unit Map, State of North Carolina. October 26, 2007 Ms. Loretta Beckwith Page 3 of 9 Perennial Streams Stream A flows through the middle portion of the property and is approximately 1,540 linear feet in length (Sheet 8, enclosed). This channel exhibited average ordinary high water widths of 4-5 feet, perennial flow, moderate sinuosity, and substrate consisting of fine sand to small cobbles. Biological sampling of Stream A resulted in a weak presence of crayfish and amphibians, and a weak presence of benthic macroinvertebrates. USACE Stream Quality Assessment scores for Perennial Stream A ranged from 49 to 53 out of a possible 100 points and ranged from 33.5 to 36.5 out of 71 possible points on the NCDWQ Stream Classification Form, indicating perennial status (SCP1 through SCP3, enclosed). Photographs of Perennial Stream A are enclosed as Photographs A and B. Stream C flows east for approximately 114 linear feet until its confluence with Perennial Stream A Sheet 8, enclosed). This channel exhibited an average ordinary high water width of 1-2 feet, perennial flow, weak sinuosity, and substrate consisting of silt to large gravel. Perennial Stream C scored 55 out of a possible 100 points on the USACE Stream Quality Assessment Form and 30 out of 71 possible points on the NCDWQ Stream Classification Form, indicating intermittent status (SCP5, enclosed). A Photograph of Stream C is enclosed as Photograph F. Intermittent Streams Stream B flows north and is approximately 92 linear feet in length (Sheet 8, enclosed). This channel exhibited average ordinary high water widths of 3-4 feet, weak ground water flow, and substrate consisting of silt to large gravel. Unimportant Intermittent Stream B scored 27 out of a possible 100 points on the USACE Stream Quality Assessment Form and 23.5 out of 71 possible points on the NCDWQ Stream Classification Form, indicating intermittent status (SCP4, enclosed). A photograph of Unimportant Intermittent Stream B is enclosed as Photograph G. Wetlands Wetland AA is located in the central portion of the property, adjacent to Stream A and is approximately 0.028 acre in size (Sheet 8, enclosed). Dominant vegetation within this area includes silky dogwood (Cornus amomum), Christmas fern (Polystichum acrostichoides), cinnamon fern Osmunda cinnamomea), common rush (Juncus effuses), and jewelweed (Impatiens capensis). This area exhibited low chroma soils (2.5Y 4/1), few prominent mottles (5YR 4/6), drainage patterns, and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland AA is enclosed (DP2). Wetland BB is located is located downstream of Perennial Stream A and Unimportant Intermittent Stream B (Sheet 8, enclosed). This forested linear wetland is approximately 0.009 acre is size. Dominant vegetation within this area includes red maple (Acer rubrum), ironwood (Carpinus caroliniana), hazel alder (Alms serrulata), common rush (Juncus effuses), and various sedges (Carex spp.). This area exhibited low chroma soils (2.5Y 4/1), few distinct mottles (5YR 4/6), drainage patterns, and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland BB is enclosed (DP3). A Photograph of Wetland BB is enclosed as Photographs E. Wetland CC is located at the downstream portion of Perennial Stream A (Sheet 8, enclosed). This forested wetland area is approximately 0.172 acre is size. Dominant vegetation within this area includes black gum (Nyssa sylvatica), black willow (Salix nigra), ironwood (Carpinus caroliniana), silky dogwood (Cornus amomum), false nettle (Boehmeria cylindrical), common rush (Juncus effuses), jewelweed (Impatiens capensis), and various sedges (Carex spp.). This area exhibited low chroma soils (IOYR 4/1), inundation to 2 inches, drainage patterns, and saturation within the upper 12 October 26, 2007 Ms. Loretta Beckwith Page 4 of 9 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland CC is enclosed (DP4). Photographs of Wetland CC are enclosed as Photographs C and D. A Routine On- Site Determination Form representative of on-site non jurisdictional upland areas is also enclosed DP 1). Agency Correspondence Cultural Resources A letter was forwarded to the State Historic Preservation Office (SHPO) on June 5, 2007 to determine the presence of any areas of architectural, historic, or archaeological significance that would be affected by the project. In a letter dated July 13, 2007, the SHPO stated that there "are no known recorded archaeological sites within the project boundaries" (enclosed). Protected Species A letter was forwarded to the North Carolina Natural Heritage Program (NCNHP) on June 5, 2007 to determine the presence of any federally-listed, candidate endangered, threatened species or critical habitat located within the project area. In a letter dated June 13, 2007, the NCNHP stated there "is no record of rare species, significant natural communities, or significant natural heritage areas at the site, nor within 1/z mile of the project area" (enclosed). Protected Species A protected species survey was conducted to determine the potential for the occurrence of animal and plant species formally proposed or listed as endangered or threatened by current Federal regulations Federal Endangered Species Act of 1973 (16 U.S.C. 1531 et seq.)] within the proposed project area. The review consisted of a literature and records search, and a pedestrian survey performed by CWS's Matt Jenkins, WPIT, and Paul Bright. CWS consulted the North Carolina Natural Heritage Program's NCNHP) Natural Element Occurrence Search Page for Buncombe Countyl5l. The data contained in this database was last updated March 1, 2007. According to the NCNHP database, there are four Federally Endangered or Threatened species listed for Buncombe County. The Endangered species for Buncombe County are the Carolina northern flying squirrel (Glaucomys sabrinus coloratus), gray bat (Myotis grisescens), spreading avens (Geum radiatum) and the rock gnome lichen (Gymnoderma lineare). Plant species observed during the pedestrian survey were identified to species or to the lowest taxonomic level necessary to determine if the observed specimen was a protected species. Plant species identified in this report follow taxonomy described by Radford, et a1.161 The following section describes the potential on-site habitats. On-Site Habitat The proposed project area is comprised of cleared mixed hardwood forest and old successional field, Sheet 4, enclosed). Dominant vegetation within the mixed hardwood canopy includes red maple acer rubrum), black cherry (Prunus serotina), tuliptree (Liriodendron tulipifera), and white oak Quercus alba),. Understory vegetation within this area includes poison ivy (Toxicodendron radicans), American holly (Ilex opaca), cinnamon fern (Osmunda cinnamomea), green catbriar 5 The NCNHP Element Occurrence Search Page, found online at http://207.4.179.50/nhp/county.html, accessed on June 12, 2007. 6 Radford, et al. 1968. Manual of the Vascular Flora of the Carolinas. The University of North Carolina Press, Chapel Hill, North Carolina. 1183 pp. October 26, 2007 Ms. Loretta Beckwith Page 5 of 9 Smilax rotundifolia), and black raspberry (Rubus occidentalis). Dominant vegetation within the early successional fields includes tuliptree (Liriodendron tulipifera), white oak (Quercus alba), green catbriar (Smilax rotundifolia), black raspberry (Rubus occidentalis), Aster (Aster spp.) and various grasses (Festuca spp.). Table 1. Federally-Listed Species Observed in Buncombe Countv, North Carolina Major Group Scientific Name Common Name Federal Status Habitat Glaucomys sabrinus Carolina Northern The ecotone between coniferous and Vertebrate oloratus Flying Squirrel E northern hardwood forests. Vertebrate yotis grisescens Gray Bat E Caves High elevation cliffs, outcrops, and icot Geum radiatum Spreading Avens E steep slopes exposed to full sun On rocks in areas of high humidity at Lichen Gymnoderma lineare Rock Gnome Lichen E high elevations Federal Status Codes Code Status Definition A taxon in danger of extinction throughout all or a E Endangered significant onion of its range. A taxon likely to become an endangered species within the T Threatened foreseeable future throughout all or a significant portion of its range. A taxon that is formally proposed to be listed as P Proposed Endangered or Threatened. A taxon under consideration for which there is sufficient C Candidate information to support listing. PD Pro osed De-listed A taxon that is proposed for de-listing Federal Species of A species under consideration for listing, for which there is FSC Concern insufficient information to support listing at this time Carolina Northern Flying Squirrel (Glaucomys sabrinus coloratus) The Carolina northern flying squirrel is found primarily in the transition zone between coniferous and northern hardwood forests. Both forest types are used for food collection, while the northern hardwood forest is used for nesting. Individuals often occupy tree cavities and woodpecker holes, but will also construct nests. Carolina northern flying squirrels are very rare and occur in isolated communities in North Carolina and Tennessee. CWS did not observe any potential habitat during the pedestrian survey and no Carolina northern flying squirrels were observed on the day of the field investigation. Gray Bat (Myotis grisescens) The gray bat is a cave dweller found primarily in Arkansas, Missouri, Tennessee, and Alabama, with a few colonies in adjacent states. They rely on different types of caves for hibernating and maternity. The hibernation caves are generally cooler than the maternity caves. Male gray bats and non- reproductive females form bachelor colonies that aren't as restrictive on their nesting sites. CWS did not observe any potential habitat during the pedestrian survey and no gray bats were observed on the day of the field investigation. October 26, 2007 Ms. Loretta Beckwith Page 6 of 9 Spreading Avens (Geum radiatum) Spreading avens is an endemic in the rose family that occupies high elevation cliffs, outcrops and steep slopes that are exposed to full sun in western North Carolina and Tennessee. The habitat is usually found next to red spruce dominated coniferous forests. They are threatened by trampling, development and air pollution. CWS did not observe any potential habitat during the pedestrian survey and no spreading avens were observed on the day of the field investigation. Rock Gnome Lichen (Gymnoderma lineare) The rock gnome lichen is part of the reindeer moss family and is found on rocks in areas of high humidity. These sites can occur at either high elevation or in deep river gorges at lower elevations. Threats to rock gnome lichen are development, air pollution, collection, and coniferous forest decline. CWS did not observe any potential habitat during the pedestrian survey and no rock gnome lichens were observed on the day of the field investigation. Biological conclusion: Given the results of the literature search and initial field investigation, it is unlikely that the proposed project will impact the Carolina northern flying squirrel, gray bat, spreading avens or the rock gnome lichen or their potential habitats. Purpose and Need for the Project The north expansion of the Asheville Regional Airport will provide for the surface area improvements necessary to accommodate ground side and air side general aviation (GA) purposes which have been identified as essential to the growing economic demand of the region. The facility must have both direct access to commercial airstrip and ground side access to four lane interstate. Additionally, the project will provide an alternate disposal site for the placement of fly ash byproduct from energy producing coal fired power plants. The current fly ash landfill is nearing capacity and it would need to expand or find a new facility in order to accommodate this fly ash. With the airport placing the material, the existing landfill will be able to gain approx. 8-10 years of storage capacity. The Asheville Regional Airport has a need to expand its development to meet the increased demand in the aviation industry. Due to the limited real estate for aviation use with access to both taxiway and runway facilities, and the boundary of the French Broad River, Interstate 26, and NC Route 280, this area is the airports most economically feasible land to develop for aviation use. This project will satisfy a portion of the publicly approved 20 year master plan for the airport. It is the purpose of this project to provide service to economic development needs of Asheville Region and Buncombe County by providing airside access to airstrip and groundside access to four lane interstate with approximately 450,000 square feet of new ramp, apron and taxiway; approximately 200,000 new square feet of building and approximately 150,000 new square feet of roadway and parking. The project has been designed to satisfy the safety concerns of the FAA. This site is intended for disposal of fly ash as alternative to utilizing valuable landfill space. State permits have already been obtained for placement of fly ash. Avoidance and Minimization The expansion of the existing airport development to the north occurs on a site which is bisected by a perennial stream. Development to one side or the other of the stream would not yield sufficient development area to satisfy the project purpose and need. The stream cannot be relocated to the east due to shallow bedrock to the ground surface and topographic constraints. The stream cannot be October 26, 2007 Ms. Loretta Beckwith Page 7 of 9 relocated to the west due to FAA restrictions on open water and forested buffers adjacent to runways due to safety issues. Minimization of impacts to downstream aquatic resources will be accomplished by filling the area so that grade directs stormwater flows away from surface waters and into off-line stormwater BMP treatment measures. Alternatives Analysis The ARV has reviewed alternatives for the development of the expansion area including the following: Alternative 1 - No Build Alternative The No-Build Alternative will result in no impacts to jurisdictional streams or wetlands but does not satisfy project purpose and need to provide airside access to airstrip and groundside access to four lane interstate with approximately 450,000 square feet of new ramp, apron and taxiway; approximately 200,000 new square feet of building and approximately 150,000 new square feet of roadway and parking. This alternative does not provide for disposal of fly ash as alternative to utilizing valuable landfill space. Alternative 2 - Off-Site Development Alternative The Off-Site Development Alternative will result in no impacts to jurisdictional streams or wetlands on this site but does not satisfy project purpose and need to provide airside access to airstrip and groundside access to four lane interstate with approximately 450,000 square feet of new ramp, apron and taxiway; approximately 200,000 new square feet of building and approximately 150,000 new square feet of roadway and parking. This alternative does not provide for disposal of fly ash as alternative to utilizing valuable landfill space. Alternative 3 - West Side Development Alternative The West Side Development Alternative will result in no impacts to jurisdictional streams or wetlands but does not satisfy project purpose and need since it does not have direct access to four lane interstate and terminal. This alternative does not provide for disposal of fly ash as alternative to utilizing valuable landfill space. Alternative 4 - South Side Development Alternative The South Side Development Alternative will result in no impacts to jurisdictional streams or wetlands but does not satisfy project purpose and need since it does not enough land area adjacent to both airstrip and interstate to provide the necessary program elements. This alternative does not provide for disposal of fly ash as alternative to utilizing valuable landfill space. Alternative 5 - East Side Development Alternative The East Side Development Alternative will result in no impacts to jurisdictional streams or wetlands but does not satisfy project purpose and need since it is not adjacent to airstrip and does not enough land area to provide the necessary program elements. This alternative does not provide for disposal of fly ash as alternative to utilizing valuable landfill space. Alternative 6 - Reduced Scope and Scale Alternative The Reduced Scope and Scale Alternative will result in fewer impacts to jurisdictional streams or wetlands but does not satisfy project purpose and need to provide airside access to airstrip and groundside access to four lane interstate with approximately 450,000 square feet of new ramp, apron and taxiway; approximately 200,000 new square feet of building and approximately 150,000 new square feet of roadway and parking. Reducing the scope and scale would render the project not economically feasible. This alternative provides less area for disposal of fly ash as alternative to October 26, 2007 Ms. Loretta Beckwith Page 8 of 9 utilizing valuable landfill space. Alternative 7 - On-Site Northern Development Alternative (Preferred Alternative) The On-Site Northern Development Alternative will result in unavoidable impacts to jurisdictional streams or wetlands on this site but it does satisfy project purpose and need to provide airside access to airstrip and groundside access to four lane interstate with approximately 450,000 square feet of new ramp, apron and taxiway; approximately 200,000 new square feet of building and approximately 150,000 new square feet of roadway and parking. This alternative does provide for disposal of fly ash as alternative to utilizing valuable landfill space. Negative effects to downstream water quality and important aquatic functions and values will be prevented through appropriate erosion and sediment control methods during construction and the incorporation of permanent stormwater management measures designed to remove Total Suspended Solids (TSS) before they reach downstream receiving waters. Proposed Impacts to Jurisdictional Waters Unavoidable impacts to Perennial Streams will total approximately 1,640 linear feet and impacts to wetland areas will total 0.209 acre (Sheets 10-14, enclosed). Impacts are due to grading activities associated with the expansion of the Asheville Regional Airport North General Expansion Project. The main drainage will be piped with 1,175 liner feet of 60" Reinforced Concrete Pipe (RCP). Fly ash will be used to backfill the area. Progress Energy holds the non-site specific permit for the disposal of the fly ash. The fly ash will be capped with a 24 inch top soil cap. A Typical Cross Section has been included as Sheet 11. On behalf of The Asheville Regional Airport, CWS is submitting a Section 404 Individual Permit Application with attachments (enclosed). Compensatory Mitigation Applicant proposes a donation to the NC Ecosystem Enhancement Program as mitigation for all proposed impacts to streams and wetlands. The AVL is proposing a donation of $401,800 for impacts to 1,640 linear feet of perennial stream at a 1:1 ratio. The AVL is proposing a $7,737.75 for impacts to 0.25 acre of riparian wetland area at a 1:1 ratio. Total donation to the EEP will be $409,537.75. A request has been forwarded to NCEEP to ensure the credits will be available. Stormwater Management A Stormwater Management Plan has been designed to minimize impacts to downstream aquatic resources. The plan has been designed according to NC Division of Water Quality Standard. A copy of the Post-Development Drainage Plan has been included as Sheets 15-17. Stormwater calculations to justify the design have been included. October 26, 2007 Ms. Loretta Beckwith Page 9 of 9 Please do not hesitate to contact me at 704-527-1177 or through email at craig@cws-inc.net should you have any questions or comments regarding these findings. Ron G. nson, PWS Craig R. Wyant, RLA Senior cientist Senior Resource Analyst Enclosures: Sheet 1 of 17. Vicinity Map Sheet 2 of 17. USGS 7.5' Skyland, NC Topographic Quadrangle Sheet 3 of 17. Buncombe County Soil Survey Sheet 4 of 17. Aerial Photograph Sheet 5 of 17. National Wetlands Inventory Map Sheet 6 of 17. FEMA Floodplain Map Sheet 7 of 17. Buncombe County Zoning Map Sheet 8 of 17. Wetland Boundary Survey Sheet 9 of 17. Pre-Developed Drainage Map Sheet 10 of 17. Mass Grading Plan Sheet 11 of 17. Typical Cross Section Sheet 12 of 17. Final Development Plan Overview Sheet 13 of 17. Post-Developed Grading Plan A Sheet 14 of 17. Post-Developed Grading Plan B Sheet 15 of 17. Post-Developed Drainage Map - Overall Sheet 16 of 17. Post-Developed Drainage Map A Sheet 17 of 17. Post-Developed Drainage Map B Section 404 Individual Permit Application (ENG FORM 4345) Request for Jurisdictional Determination Form Agent Certification of Authorization Form USACE Routine Wetland Determination Data Forms (DP 1 - DP4) NCDWQ Stream Classification Forms (SCP1 - SCP5) USACE Stream Quality Assessment Worksheets (SCPI - SCP5) Approved Jurisdictional Determination Forms Representative Photographs (A - H) Agency Correspondence Letter from Asheville Chamber of Commerce Adjoining Property Owners NCDWQ Stormwater Calculations cc: Ms. Cyndi Karoly, NCDWQ Mr. Gary Bouthillier, WK Dickson Mr. David N. Edwards, Jr. - Airport Director, AVL Asheville Regional Airport Project Individual Permit Application Project No. 2007-1889 D IJ 1, 1 F+ Image Courtesy of the U.S. Geological Survey 7.5 Minute Topographic Map Series, Skyland Quadrangle, North Carolina, dated 1991 Approximate Scale 1" = 4,000' pf.N ?DSTOR?R?BR?N Sheet 1 of 17 Asheville Regional Airport Project Individual Permit Application Protect No. 2007-1889 O C T 2 J 2007 7.5 Minute Topographic Map Series, Skyland Quadrangle, North Carolina, dated 1991. Approximate Scale 1" = 2000' ? t tD - WATER GUALITY s eet 2 of 17 Image Courtesy of the U.S. Geological Survey pol Asheville Regional Airport Project Individual Permit Application Project No. 2007-1889 Soil Survey Courtesy of Buncombe County Online GIS Soil Survey of Buncombe County, North Carolina. Sheet 3 of 17 Asheville Regional Airport Project Individual Permit Application Proiect No. 2007-1889 BUNCOMBE COUNTY, NORTH CAROLINA 4 r ?? ? ? r ? ?.a spa w 3 ,.?'??+ :?±.• ? ?" i. ?; " #3371 9 330 40 7 ?, too ir", 9878 1 +) Fi dou, 846 4407 T! ?. tv YM 1' ? p5S^ F J P ,, y?' %S T S k?4r 7' K 67 ProleCt BoudarY f Aerial Map Image Courtesy of Buncombe County GIS, dated 2006. Sheet 4 of 17 f Asheville Regional Airport Project Individual Permit Application Protect No. 2007-1889 11 82-33-20 W 82-33-0 W 82-32-40 W 82-32-20 W 82-32-0 W z 0 M N 6 Cl) z 0 04 N A M z M N Lh Cl) z u5 u5 M z M 6 N M A' ! 111 rin O z Y' 0 z W N 0 z Cl) N W O z 82-33-20 W 82-33-0 W 82-32-40 W 82-32-20 W 82-32-0 W N Scale: 1:23,950 Map center: 35° 26'33" N, 82° 321 3511 W This map is a user generated static output from an Internet mapping site and is for general reference only. Data layers that appear on this map may or may not be accurate, current, or otherwise reliable. THIS MAP IS NOT TO BE USED FOR NAVIGATION. NWI Map Image Courtesy of the National Wetlands Inventory. Legend CONUS wet_scan o O t M Out of range Interstate Major Roads Other Road rJ Interstate State highway US highway Roads Cities USGS Quad' Index 24K Lover 48 Wetland Polygons Estuarine and Marine Deepwater Estuarine and Marine wetland Freshwater Emergent tHetiand Freshwater Fores€edtShrub Wettand Freshwater Pond Lake Other Riverhre Lower 48 Available Wettand' Data Mon-Digitai Dighal N'o Data Scan NHD Streams r- Counties 100K E:3 States 160K South Armerica North America Sheet 5 of 17 Asheville Regional Airport Project Individual Permit Application Project No. 2007-1889 370031 APPROXIMATE SCALE 500 0 500 FEET NATIONAL FLOOD INSURANCE PROGRAM FIRM FLOOD INSURANCE RATE MAP BUNCOMBE COUNTY, NORTH CAROLINA AND INCORPORATED AREAS I PANEL 458 OF 550 j SEE MAP INDEX FOR PANELS NOT PRINTED) i' l2 9 CONTAINS: 2 ?COm"",O NUMBER PANEL SUFFIX ASHEVILLE. 3]0031 0959 CC' OF OOQ I UNINCORPORATED AREAS 370031 0468 C n7 O 1 City of III j III Nolica 1. Usb: The MAP NUMBER hdwe belay slaaM be used wM1en Placing ma orders: the COMMUN- NUMBER above show sh-d ba used on msurenc applications I., the a.bya amm 1. Asheville z6 I MA P NUMBER 370032 37021CO458 C EFFECTIVE DATE: MAY 6,1996 r III Federal Emergency Management Agency is is an official copy of a portion of the above referenced flood map. It is extracted using F-MIT On-Line. This map does not reflect changes amendments which may have been made subsequent to the date on the e block. For the latest product information about National Flood Insurance Dgram flood maps check the FEMA Flood Map Store at www.msc.fema.aov FEMA Flood Map Image Courtesy of the Federal Emergency Management Agency, dated 1996. Sheet 6 of 17 Asheville Regional Airport Project Individual Permit Application Project No. 2007-1889 Zoning Map Image Courtesy of the City of Asheville GIS, dated 2007. Sheet 7 of 17 c NOTE: JURISDICTIONAL WATERS OF THE U.S. WERE DELINEATED AND SURVEYED WITH CPS BY C WS, INC. (CWS) ON NNE 13, 2007. JURISDICTIONAL FEATURES HAVE NOT BEEN VERIFIED BY THE USACE. T7 T7 \Y\ _ _. _ _. \ 1 ,1 , s 11! ` i I V Av ?" ?fv ?? ??? fi, I ? '?? t3 p \Av? y \A?Vw?A y Perennial Stream C- \ \ ?? w\\ cane aw;,; 11 Linear Feet \ \` t? \ Existing Culvert- \ \\, v? ?\ww id4 Linear Fee DP4 - A _ A Ao Wetland CC- A? 0.172 acre 1 \??\ tx SCP5 V? ?\ \ \ \ + a a, I n \? \ V vw\?rAIY FUJAGE \ \' DP2 Wetland 88- 0.009 acre \ \\ Wetland Mme" . r.?. 0.028 ocre \ `? \ d aO:,.vwc SCP3 DP s-,J \ r\ o CP2 rz,eva \ G \ o erennlal Stream A- \\ g SCP4 538 Linear Feet e c Y LFNSE FZ1?o CP1 o \ Unimportant Intermittent earn mua maun?92 Linear Feet ' "- I n., n 000a 104E F111,14F a O / \ \ LEGEND PROPERTY BOUNDARY JURISDICTIONAL STREAM CHANNEL JURISDICTIONAL WETLAND PHOTO LOCATION AND DIRECTION APPROXIMATE SCALE: V = 400' Carolina Wetland Services 550 East Westinghouse Blvd. Charlotte, North Carolina 28273 Wetland Boundary Survey Asheville Regional Airport Expansion Fletcher, North Carolina CW S Project No. 2007-1889 Sheet 8 of 17 i I I a 1 1II11 ( o uJ _ c 1 � J¢1 z 175 >o zLi It LLJ Lj \ IIy I o f a, -71 J I it �.I �l. r � f�l ��/ �i �/,��..��—'•�_���/z//� /� � 4s\ � J \ 'if 1 43, Jf�l 1 � •fll ���#. /Jf ©4'� �:k iz/as �\`� ��i�, �s�i� i'.7 � "p ^e4 ',r� �M � r� � Z I I Y-��f' �/ � i r� r � �€A� Ip Fi �i�w.�,.'• .+yL ""'C rf�-- /� E /t�q fy X/ YY J \1 i I� ItE�HII`rlf� ` I' ll, It I' �r 1 o a � � �l. ✓T-d '� /' � ( i p' rt �a/ Hlt i II I;ki�ili�tki.,(i ,�il�IlilrfiC`IIIIItl1 {, 3, I t1+ �. 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I VI I I Ill- ' I 1 ''I IIIIf � Il;lilll.l I a \\ I \ !!III-I!III' U N I cN wN Q IV F II I II I IILI�' U! l�I!I — .\� irm 1 2 Sheet 17 of 17 APPLICATION FOR DEPARTMENT OF THE ARMY PERMIT OMB APPROVAL NO. 0710-0003 (33 CFR 3251 Expires December 31, 2004 The Public burden for this collection of information is sestimated to average 10 hours per response, although the majority of applications should requirr, 5 hours or less. This includes the time for reviewing instructions, searching existing data sources,gathering and maintaining the data needed, and completing and reviewing the collection of information. Send comments regarding this burden estimate or any other aspect of this collection of information, including suggestions for reducing this burden,to Department of Defense, Washington Headquarters Service Directorate of Information Operations and Reports, 1215 Jefferson Davis Highway, Suite 1204,Arlington, VA 22202-4302;and to the Office of Management and Budget, Paperwork Reduction Project(0710-0003), Washington, DC 20503. Respondents should be aware that notwithstanding any other provision of law, no person shall be subject to any penalty for failing to comply with a collection of information if it does not display a currently valid OMB control number. Please DO NOT RETURN your form to either of those addresses. Completed applications must be submitted to the District Engineer having jurisdiction over the location of the proposed activity. PRIVACY ACT STATEMENT Authorities: Rivers and Harbors Act, Section 10, 33 USC 403; Clean Water Act, Section 404, 33 USC 1344; Marine Protection , Research and Sanctuaries Act, 33 USC 1413,Section 103. Principal Purpose: Information provided on this form will be used in evaluating the application for a permit. Routine Uses: This information may be shared with the Department of Justice and other federal, state, and local government agencies. Submission of requested information is voluntary, however, if information is not provided the permit application cannot be evaluated nor can a permit be issued. One set of original drawings or good reproducible copies which show the location and character of the proposed activity must be attached to this application (see sample drawings and instructions) and be submitted to the District Engineer having jurisdiction over the location of the proposed activity. An application that is not completed in full will be returned. ITEMS 1 THRU 4 TO BE FILLED BY THE CORPS 1. APPLICATION NO. 2. FIELD OFFICE CODE 3. DATE RECEIVED 4. DATE APPLICATION COMPLETE (ITEMS BELOW TO BE FILLED BY APPLICAAM 5. APPLICANT'S NAME Asheville Regional Airport Authority 8. AUTHORIZED AGENT'S NAME AND TITLE(an agent is not required) Attn: Mr. David N. Edwards, Jr. Carolina Wetland Services, Attn: Craig R. Wyant 6. APPLICANT'S ADDRESS 9. AGENT'S ADDRESS 61 Terminal Drive, Suite 1 550 East Westinghouse Boulevard Fletcher, NC 28732 Charlotte NC 28273 7.. APPLICANT'S PHONE NOS. W/AREA CODE 10 AGENT'S PHONE NOS W/AREA CODE a. Residence a. Residence b. Business (828) 684-2226 ' b. Business (704) 527-1177 cell: (704) 496-1696 11, STATEMENT OF AUTHORIZATION I hereby authorize, to act in my behalf as my agent in the processing of this application and to furnish, upon request, supplemental information in support of this permit application. Signed Agent Authorization Form Attached APPLICANT'S SIGNATURE DATE NAME, LOCATION AND DESCRIPTION OF PROJECT OR ACTIVITY 12. PROJECT NAME OR TITLE(seeirwrucrions. Asheville Regional Airport Northern Expansion t3. NAME OF WATERBODY, IF KNOWN a,,applicable) 14. PROJECT STREET ADDRESS plap#icable) UT to French Broad River 61 Terminal Drive, Suite 1 15. LOCATION OF PROJECT Fletcher, NC 28732 Buncombe NC � ti COUNTY STATE 16. OTHER LOCATION DESCRIPTIONS, IF KNOWN, (seeinstrucrions) (*1�� 17. DIRECTIONS TO THE SITE From Asheville,-Take Interstate 26 South to the NC 280 Exit(New Airport Road).Turn right(southwest)and follow signage into airport parking.Project site is located on the north side of existing hangars behind security fencing. FAA requires permission to enter this area from the Airport Director. 18. Nature of Activity (Description of project, include ail features) The Asheville Regional Airport has a need to expand its development to meet the increased demand in the aviation industry. Due to the limited real estate for aviation use with access to both taxiway and runway facilities, and the boundary of the French Broad River, Interstate 26, and NC Route 280, this is the airports only remaining devel- opable land for aviation use. This project will satisfy a portion of the publicly approved 20 year master plan for the airport. It is the purpose of this project to provide service to economic development needs of Asheville Region and Buncombe County by providing airside access to airstrip and groundside access to four lane interstate with approximately 450,000 square feet of new ramp, apron and taxiway; approximately 200,000 new square feet of building and approximately 150,000 new square feet of roadway and parking. The project has been designed to satisfy the safety concerns of the FAA. This site is intended for disposal of fly ash as alternative to utilizing valuable landfill space. State permits have already been obtained for placement of fly ash. 19. Project Purpose (Describe the reason or purpose of the project, see instructions) The north expansion of the Asheville Regional Airport will provide for the surface area improvements necessary to accommodate ground side and air side general aviation. GA) purposes which have been identified as essential to the growing economic demand of the region. The facility must have both direct access to commercial airstrip and ground side access to four lane interstate. Additionally, the project will provide an alternate disposal site for the placement of fly ash byproduct from energy produc- ing coal fired power plants. The fly ash is presently being disposed of in surface landfill facilities which are in short supply due to the limited availability of suitable land in the region. State approved offsite disposal areas for fly ash will greatly extend the life of the landfill. USE BLOCKS 20-22 IF DREDGED AND/OR FILL MATERIAL IS TO BE DISCHARGED 20. Reason(s) for Discharge In order provide for the surface area improvements necessary to the northern expansion of the airport facility there will need to be fill placed to bring the development area up to grade. A pipe in the vicinity of the fill will be placed in order to carry the flow of an existing perennial stream and its side stream tributaries and wetlands 21. Type(s) of Material Being Discharged and the Amount of Each Type in Cubic Yards Fly ash (one of several coal combustion products, or CCPs) is the finely divided mineral residue resulting from the combustion of coal in electric generating plants. Fly ash consists of inorganic, incombustible matter present in the coal that has been fused during combustion into a glassy, amorphous structure. A geotextile liner will be placed beneath the fly ahs and a 24" soil cap will be placed above. 22. Surface Area in Acres of Wetlands or Other Waters Filled (see instructions) Impacts to Perennial Streams will total approximately 1,640 linear feet and impacts to wetland areas will total 0.209 acre (Sheets 10-14, enclosed) 23. Is Any Portion of the Work Already Complete? Yes No IF YES, DESCRIBE THE COMPLETED WORK Yes, wetland delineation has been completed and clearing and grubbing of the site outside of jurisdictional areas has been completed. 24. Addresses of Adjoining Property Owners, Lessees, Etc., Whose Property Adjoins the Waterbody (If more than can be entered here, please attach a supplemental list). List of Adjacent Property Owners Attached. 25. List of Other Certifications or Approvals/Denials Received from other Federal, State or Local Agencies for Work Described in This Application. AGENCY TYPE APPROVAL' IDENTIFICATION NUMBER DATE APPLIED DATE APPROVED DATE DENIED NCDENR Erosion and BUNCO-2007-013 N/A N/A N/A Sediment Control Would include but is not restricted to zoning, building and flood plain permits 26. Application is hereby made for a permit or permits to authorize the work described in this application. I certify that the information in this appiication is complete and accurate. I further certify that I possess the authority to undertake the work described herein or am acting as the duly authorized agent of the applicant. SIGNATURE OF APPLICANT DATE SIGNATURE OF AGENT DATE The application must be signed by the person who desires to undertake the proposed activity (applicant) or it may be signed by a duly authorized agent if the statement in block 11 has been filled out and signed. 18 U.S.C. Section 1001 provides that: Whoever, in any manner within the jurisdiction of any department or agency of the United States knowingly and willfully falsifies, conceals, or covers up any trick, scheme, or disguises a material fact or makes any false, fictitious or fraudulent statements or representations or makes or uses any false writing or document knowing same to contain any false, fictitious or fraudulent statements or entry, shall be fined not more than $10,000 or imprisoned not more than five years or both. Oct-22-2007 04:22pm From—ASHEVILLE REGIONAL AIRPORT AUTH, +8286843404 T-865 P.002/002 F-582 AGENT CERTIFICATION OF AUTHORIZATION I, David N. Edwards, Jr., A.A.E. Airport Director for the Asheville Regional Airport Authority certify that I have authorized Craig R. Wyant of Carolina Wetland Services, Inc.to act on my behalf and take all actions necessary to the processing, issuance, and acceptance of the Section 404/401 Individual Permit and any and all standard and special conditions attached for the Asheville Regional Airport Authority—North General Aviation Expansion Project. We hereby certify that the above information submitted in this application is true and accurate to the best of our knowledge. Applicant's signature Agent's signature /QZ/2 Z� > 10/22/07 Date Date Completion of this form will allow the agent to sign all future application correspondence. REQUEST FOR JURISDICTIONAL DETERMINATION DATE: October 22,2007 COUNTY Buncombe Count',North Carolina TOTAL ACREAGE OF TRACT —33 acres PROJECT NAME(if applicable) Asheville Regional Airport Project PROPERTY OWNER/APPLICANT(name,address and phone): Asheville Regional Airport Authority POC:Mr.David N.Edwards,Jr.,at(828)684-2226 61 Terminal Drive,Suite 1 Fletcher,NC 28732 NAME OF CONSULTANT,ENGINEER,DEVELOPER(if applicable): Carolina Wetland Services,Inc. POC:Mr.CraigR.Wyant,at(704)527-1177 550 East Westinghouse Blvd. Charlotte,NC 28273 STATUS OF PROJECT(check one): ( ) On-going site work for development purposes (X) Project in planning stages (Type of project: airport expansion ) ( ) No specific development planned at present ( ) Project already completed (Type of project: ) ADDITIONAL INFORMATION REQUIRED: Check items submitted - forward as much information as is available. At a minimum, the following first two items must be forwarded. (X) Vicinity Map (X) USGS 7.5' Skyland,NC Topographic Quadrangle (X) Buncombe County Soil Survey (X) Aerial Photograph (X) National Wetlands Inventory Map (X) FEMA Floodplain Map (X) Buncombe County Zoning Map (X) Wetland Boundary Survey (X) Pre-Developed Drainage Map (X) Mass Grading Plan (X) Typical Cross Section (X) Final Development Plan(Sheets 12-14) (X) Post-Developed Drainage Map(Sheets 15-17) (X)Section 404 Individual Permit Application(ENG FORM 4345) (X)Request for Jurisdictional Determination Form (X)Agent Certification of Authorization Form (X)USACE Routine Wetland Determination Data Forms(DP1 —DP4) (X)NCDWQ Stream Classification Forms(SCP1—SCP5) (X)USACE Stream Quality Assessment Worksheets(SCP1 —SCP5) (X)Approved Jurisdictional Determination Forms (X)Representative Photographs(A—H) (X)Agency Correspondence (X)Letter from Asheville Chamber of Commerce (X)Adjoining Property Owners (X)NCDWQ Stormwater Calculations C--, Signature of Property Owner or Authorized Agent Mr.Craig R.Wyant DATA FORM ROUTINE WETLAND DETERMINATION (1987 COE Wetlands Delineation Manual) Project/Site: Asheville Regional Airport Project Date: 06/12/07 Applicant/Owner: Asheville Regional Airport Authority County: Buncombe Investigator(s): Matt Jenkins, WPIT and Paul Bright State: NC Do Normal Circumstances exist on the site? Yes No Community ID: upland Is the site significantly disturbed (Atypical Situation)? Yes No Transect ID: Is ti":e area 3 cctentiai cbiem l:rea'� 'r.s 1 Rci C: D l ' (If needed, -explain reverse.' VEGETATION Dominant Plant Species Stratum Indicator Dominant Plant Species Stratum Indicator 1 Polystichum acrostichoides herb FAC 9 2 Osmunda cinnamomea herb FACW+ 10 3 Juncus effusus herb FACW+ 11 4 Impatiens capensis herb FACW 12 5 13 6 14 7 15 8 16 Percent of Dominant Species that are OBL,FACW or FAC 100% Remarks: All of the dominant plant species are FAC or wetter. HYDROLOGY Recorded Data(Describe in remarks): Wetland Hydrology Indicators: Stream, Lake or Tide Gauge Primary Indicators: Aerial Photographs Inundated Other Saturated in Upper 12 Inches X No Recorded Data Available Water Marks Drift Lines Field Observations: Sediment Deposits(on leaves) Drainage Patterns in Wetlands Depth of Surface Water: N/A (in.) Secondary Indicators(2 or more required): Oxidized Root Channels in Upper 12 Inches Depth to Free Water in Pit: N/A (in.) Water-Stained Leaves Local Soil Survey Data Depth to Saturated Soil: N/A (in.) —FAC-Neutral Test Other(Explain in Remarks) Remarks: No indicators of wetland hydrology are present. Routine On-Site Data Forms Page I Of 2 10/22/2007 SOILS Map Unit Name (Series and Phase): Tate loam,2 to 8 percent slopes (TaB) Drainage Class well-drained Field Observations Taxonomy(Subgroup): mesic Typic Ha ludults Confirm Mapped Type? Yes No Profile Descriotion: Depth .,Aam.,,Ccicr `Mottle Colors "Vlottle e xture, Cona�e,icns. (inches) Horizon (Munsell Moist) 'Munsell Moist) abundance/Contrast Structure, etc. 0-12 B 2.5Y 4/2 N/A N/A silt loam Histosol Concretions Histic Epipedon High Organic Content in Surface Layer in Sandy Soils Sulfidic Odor Organic Streaking in Sandy Soils Aquic Moisture Regime Listed on Local Hydric Soils List(Inclusions) Reducing Conditions Listed on National Hydric Soils List Gleyed or Low-Chroma Colors Other(Explain in Remarks) Remarks: No indicators of h dric soils are present. WETLAND DETERMINATION Hydrophytic Vegetation Present? QYe No (Circle) Wetland Hydrology Present? Yes No (Circle) Hydric Soils Present? Yes No Is this Sampling Point Within a Wetland? Yes No Remarks: Data point is representative of a non-'urisdictional upland area. Approved by HQUSACE 2/92 Routine On-Site Data Forms Page 2 of 2 10/22/2007 DATA FORM ROUTINE WETLAND DETERMINATION (1987 COE Wetlands Delineation Manual) Project/Site: Asheville Regional Airport Project Date: 06/12/07 Applicant/Owner: Asheville Regional Airport Authority County: Buncombe Investigator(s): Matt Jenkins,WPIT and Paul Bright State: NC Do Normal Circumstances exist on the site? Yes No Community ID: wetland Is the site significantly disturbed (Atypical Situation)? Yes No Transect ID: Is :fie area a potential "Morn, ?.rea \�� k-ICt ic: i df needed, explain on reverse.) VEGETATION Dominant Plant S ecies Stratum Indicator Dominant Plant Species Stratum Indicator 1 Cornus amomum shrub FACW+ 9 2 Poiystichum acrostichoides herb FAC 10 3 Osmunda cinnamomea herb FACW+ 11 4 Juncus effusus herb FACW+ 12 5 Impatiens capensis herb FACW 13 6 14 7 15 8 16 Percent of Dominant Species that are OBL,FACW or FAC 100% Remarks: All of the dominant plant species are FAC or wetter. HYDROLOGY Recorded Data(Describe in remarks): Wetland Hydrology Indicators: Stream, Lake or Tide Gauge Primary Indicators: Aerial Photographs Inundated Other -Saturated in Upper 12 Inches X No Recorded Data Available Water Marks Drift Lines Field Observations: Sediment Deposits(on leaves) �-Drainage Patterns in Wetlands Depth of Surface Water: N/A (in.) Secondary Indicators(2 or more required): Oxidized Root Channels in Upper 12 Inches Depth to Free Water in Pit: N/A (in.) Water-Stained Leaves Local Soil Survey Data Depth to Saturated Soil: <12 (in.) —�FAC-Neutral Test Other(Explain in Remarks) Remarks: Indicators of wetland hydrolowy are present. Routine On-Site Data Forms Page 1 of 2 10/22/2007 SOILS Map Unit Name (Series and Phase): Tate loam,2 to 8 percent slopes (TaB) Drainage Class well-drained Field Observations Taxonomy(Subgroup): mesic Typic Ha ludults Confirm Mapped Type? Yes No Profile Descriotion: I Depth 'viairl "Ictile _,�lcr s .''vlottle iL!fe. nc eticns. (inches) Horizon (Munsell Moist l (Munsell Moist) Abundance/Contrast Structure, etc 0-12 B 2.5Y 4/1 5YR 4/6 few/distinct silt loam Histosol Concretions Histic Epipedon High Organic Content in Surface Layer in Sandy Soils Sulfidic Odor Organic Streaking in Sandy Soils Aquic Moisture Regime Listed on Local Hydric Soils List(Inclusions) Reducing Conditions Listed on National Hydric Soils List Gleyed or Low-Chroma Colors Other(Explain in Remarks) Remarks: Indicators of h dric soils are present. WETLAND DETERMINATION Hydrophytic Vegetation Present? I No (Circle Wetland Hydrology Present? No (Circle) Hydric Soils Present? No Ils this Sampling Point Within a Wetland? Ye No Remarks: Data point is representative of a 'urisdictional wetland area. Approved by HQUSACE 2192 Routine On-Site Data Forms Page 2 of 2 10/22/2007 DATA FORM ROUTINE WETLAND DETERMINATION (1987 COE Wetlands Delineation Manual) Project/Site: Asheville Regional Airport Project Date: 06/12/07 Applicant/Owner: Asheville Regional Airport Authority County: Buncombe Investigator(s): Matt Jenkins, WPIT and Paul Bright State: NC Do Normal Circumstances exist on the site? Yes No Community ID: wedan Is the site significantly disturbed (Atypical Situation)? Yes No Transect ID: Is the area a potential Problem Area? Yes No Plot ID: DP3 If needed, explain on reverse.) VEGETATION Dominant Plant S ecies Stratum Indicator Dominant Plant Species Stratum Indicator 1 Acer rubrum tree FAC 9 2 Carpinus caroliniana tree FAC 10 3 Alnusserrulata tree FACW 11 4 Juncus effusus herb FACW+ 12 5 Carex spp. herb * 13 6 14 7 15 8 16 Percent of Dominant Species that are OBL, FACW or FAC 100% Remarks: 'Please note this species was not identified to species and was therefore excluded from the FAC-Neutral test. All of the dominant plant species are FAC or wetter. HYDROLOGY Recorded Data(Describe in remarks): Wetland Hydrology Indicators: Stream, Lake or Tide Gauge Primary Indicators: Aerial Photographs Inundated Other Saturated in Upper 12 Inches X No Recorded Data Available Water Marks Drift Lines Field Observations: Sediment Deposits(on leaves) Drainage Patterns in Wetlands Depth of Surface Water: N/A (in.) Secondary Indicators(2 or more required): Oxidized Root Channels in Upper 12 Inches Depth to Free Water in Pit: N/A (in.) Water-Stained Leaves Local Soil Survey Data Depth to Saturated Soil: <12 (in.) FAC-Neutral Test Other(Explain in Remarks) Remarks: Indicators of wetland hydrology are present. Routine On-Site Data Forms Page 1 of 2 10/22/2007 SOILS Map Unit Name (Series and Phase): Tate loam,2 to 8 percent slopes (TaB) Drainage Class well-drained Field Observations Taxonomy(Subgroup): mesic Typic Ha ludults Confirm Mapped Type? Yes No Profile Descri tion: Depth Matrix Color Mottle Colors Mottle Texture,Concretions, (inches) Horizon (Munsell Moist) (Munsell Moist) Abundance/Contrast Structure,etc. 0-12 B 2.5Y 4/1 5YR 4/6 few/distinct silt loam Histosol Concretions Histic Epipedon High Organic Content in Surface Layer in Sandy Soils Sulfidic Odor Organic Streaking in Sandy Soils Aquic Moisture Regime Listed on Local Hydric Soils List(Inclusions) Reducing Conditions Listed on National Hydric Soils List Gleyed or Low-Chroma Colors Other(Explain in Remarks) Remarks: Indicators of h dric soils are present. WETLAND DETERMINATION Hydrophytic Vegetation Present? Yes No (Circle) Wetland Hydrology Present? Yes No (Circle) Hydric Soils Present? Yes No Is this Sampling Point Within a Wetland? Ye No Remarks: Data point is representative of a 'urisdictional wetland area. Approved by HQUSACE 2192 Routine On-Site Data Forms Page 2 of 2 10/22/2007 DATA FORM ROUTINE WETLAND DETERMINATION (1987 COE Wetlands Delineation Manual) Project/Site: Asheville Regional Airport Project Date: 06/12/07 Applicant/Owner: Asheville Regional Airport Authority County: Buncombe Investigator(s): _Matt Jenkins, WPIT and Paul Bright State: NC Do Normal Circumstances exist on the site? Yes No Community ID: wetlan Is the site significantly disturbed (Atypical Situation)? Yes No Transect ID: Is the area a potential Problem Area? Yes No Plot ID: DP4 If needed, explain on reverse.) VEGETATION Dominant Plant Species Stratum Indicator Dominant Plant Species Stratum Indicator 1 Nyssa sylvatica tree FAC 9 2 Salix nigra tree OBL 10 3 Carpinus caroliniana tree FAC 11 4 Cornus amomum shrub FACW+ 12 5 Boehmeria cylindrica herb FACW+ 13 6 Carex spp. herb * 14 7 Juncus effusus herb FACW+ 15 8 Impatiens capensis herb FACW 16 Percent of Dominant Species that are OBL,FACW or FAC 100% Remarks: *Please note this species was not identified to species and was therefore excluded from the FAC-Neutral test. All of the dominant plant species are FAC or wetter. HYDROLOGY Recorded Data(Describe in remarks): Wetland Hydrology Indicators: Stream, Lake or Tide Gauge Primary Indicators: Aerial Photographs X Inundated Other ��Saturated in Upper 12 Inches X No Recorded Data Available Water Marks Drift Lines Field Observations: Sediment Deposits(on leaves) Drainage Patterns in Wetlands Depth of Surface Water: 0-2 (in.) Secondary Indicators(2 or more required): Oxidized Root Channels in Upper 12 Inches Depth to Free Water in Pit: N/A (in.) Water-Stained Leaves Local Soil Survey Data Depth to Saturated Soil: >12 (in.) FAC-Neutral Test Other(Explain in Remarks) Remarks: Indicators of wetland hydrolo2y are vresent. Routine On-Site Data Forms Page 1 of 2 10/22/2007 SOILS Map Unit Name (Series and Phase): Tate loam,2 to 8 percent slopes (TaB) Drainage Class well-drained Field Observations Taxonomy(Subgroup): mesic Typic Ha ludults Confirm Mapped Type? Yes No Profile Description: Depth Matrix Color Mottle Colors Mottle Texture,Concretions, (inches) Horizon (Munsell Moist) (Munseil Moist) Abundance/Contrast Structure,etc. 0-12 B 10YR 4/1 N/A N/A silt loam Histosol Concretions Histic Epipedon High Organic Content in Surface Layer in Sandy Soils Sulfidic Odor Organic Streaking in Sandy Soils Aquic Moisture Regime Listed on Local Hydric Soils List(Inclusions) Reducing Conditions Listed on National Hydric Soils List —�Gleyed or Low-Chroma Colors Other(Explain in Remarks) Remarks: Indicators of h dric soils are present. WETLAND DETERMINATION Hydrophytic Vegetation Present? Yes No (Circle) Wetland Hydrology Present? Yes No (Circle) Hydric Soils Present? Yes No Is this Sampling Point Within a Wetland? Ye No Remarks: Data oint is representative of a jurisdictional wetland area. Approved by HQUSACE 2/92 Routine On-Site Data'Forms Page 2 of 2 10/22/2007 North Carolina Division of Water Quality -Stream Identification Form; Version 3.1 Date: 06/12/2007 Prolec thevilleRegionalAirportProject Latitude: N35.445430 Evaluator:NMJ&PAB site: SCP1 Longitude: W82,540940 Total Points; Perennial Stream A Stream is at least intermittent County' Other if'a: 19 or perenniat if>_30 SO Buncombe e.g. Quad Name: A. Geomorphology (Subtotal = 15.5 ) Absent: Weak Moderate Strong 1'. Continuous bed and bank 2.0 0 1 2 3 2. Sinuosity 2.0 0 1 2 3 3. In-channel structure: riffle-pool sequence 2.0 0 1 2 3 4. Soil texture or stream substrate sorting 2.0 0 1 2 3 5_ Active/relic floodplain 1.0 0 1 2 3 6. Depositional bars or benches 1.0 0 1 2 3 7. Braided channel 0.0 0 1 2 3 8. Recent alluvial deposits 1.0 0 1 2 3 9 a Natural levees 1.0 0 1 2 3 10. Headcuts 2.0 0 1 2 3 11. Grade controls 1.5 0 0.5 1 1.5 12. Natural valley or drainageway 0.0 0 0.5 1 1.5 13. Second or greater order channel on existing USGS or NRCS map or other documented No= 0 Yes= 3 evidence. 0.0 Man-made ditches are not rated,see discussions in manual B. Hydrology (Subtotal = 9.0 14. Groundwater flow/discharge 2.0 0 1 2 3 15.Water in channel and > 48 hrs since rain, or 0 1 2 3 Water in channel--dry or growing season 2.0 16. Leaflitter 1.5 1.5 1 0.5 0 17. Sediment on plants or debris 1.0 0 0.5 1 1.5 18. Organic debris lines or piles(Wrack lines) 1.0 0 0.5 1 1.5 19, Hydric soils (redoximorphic features) present?1.5 No= 0 Yes= 1.5 C. Biology (Subtotal = 9.00 ) 20". Fibrous roots in channel 3.0 3 2 1 0 21". Rooted plants in channel 3.0 3 2 1 0 22. Crayfish 0.0 0 0.5 1 1.5 23_ Bivalves 0.0 0 1 2 3 24. Fish 0.0 0 0.5 1 1.5 25. Amphibians 1.5 0 0.6 1 1.5 26. Macrobenthos(note diversity and abundance) 0.5 0 0.5 1 1.5 27. Filamentous algae: periphyton 1.0 0 1 2 3 28. Iron oxidizing bacteriatfungus. 0.0 0 0.5 1 1.5 29°. Wetland plants in streambed 0.00 FAC= 0.5; FACW=0.75; OBL= 1.5 SAV=2.0; Other=0 Items 20 and 21 focus on the presence of upland plants, Item 29 focuses on the presence of aquatic or wetland plants. Notes: (use back side of this form for additional notes.) Sketch: North Carolina Division of Water Quality -Stream Identification Form; Version 3.1 Bate: 06/12/2007 Prolecthev,11e Regional Airport Project Latitude: W82.54094N35.44543 Evaluator:Nffij&PAB Site: SCP2 Longitude: o Total Points: Perennial Stream:A Stream is at least interrnitfenf L County' Other ifz 19 or ererrnialif>_30 yJ •SO 'Buncombe e.g. Quad Name: A. Geomor holo (subtotal = 17.5 Absent Weak Moderate Strong 13_ Continuous bed and bank 2.0 0 1 2 2. Sinuosity. 3 3.0 0 1 2 3 3. In-channel structure: riffle-pool sequence 2.0 0 1 2 4. Soil texture or stream substrate sorting 2.0 0 3 1 2 3 5. Activelrelicfloodplain 2 0 0 1 2 6. Depositional bars or benches 3 1.0 0 1 2 3 7. Braided channel 0.0 0 1 2 8. Recent alluvial deposits 1.0 3 0 1 2 3 9 a Natural levees 1.0 0 1 2 10. Headcuts 2 3 .0 0 1 2 3 11. Grade controls 0.5 0 0.5 1 12. Natural valley or drainageway 1.0 0 1.5 0.5 1 1.5 13. Second or greater order channel on existina USGS or NRCS map or other documented No= 0 evidence. Yes= 3 - 0.0 Man-made ditches are not rated:see discussions in manual B. Hydrology (Subtotal = 9.5 } 14_ Groundwater flovidischarge 3.0 0 1 2 3 15.Water in channel and> 48 hrs since rain, or Water in channel--dr or growing season 2.0 0 1 2 3 16. Leaflitter 1.0 1.5 1 0.5 0 17. Sediment on plants or debris 1.0 0 0.5 1 18. Organic debris lines or piles ) 1.5 p (Wrack lines 1.0 0 0.5 1 1 5 19. Hydric soils (redoximorphic features) present?1.5 No= 0 Yes= 1.5 C. Biology (Subtotal = 9.50 ) 20'. Fibrous roots in channel 3.0 3 2 1 21b. Rooted plants in channel 0 3.0 3 2 1 0 22. Crayfish 0.0 0 0.5 1 23. Bivalves 1.5 0.0 0 1 2 3 24. Fish 25. Amphibians 0.0 0 0.5 1 1.5 1.0 0 0.5 1 26_ Mac robenthos(note diversity and abundance) 0.5 0 5 1 0 1.5 27_ Filamentou 1.5 s algae: periphyton 2.0 0 1 2 3 28. Iron oxidizing bacterialfungus. 0.0 0 0.5 29b. Wetland plants in streambed 1 1.5 0.00 FAC= 055; FACW=0.75; OBL= 1.5 SAV=2.0: Other=0 Items 20 and 21 focus on the presence of upland plants, Item 29 focuses on the presence of aquatic or wetland plants. Notes: (use back side of this form for additional notes.)' Sketch: North Carolina Division of Water Quality -Stream Identification Form; Version 3.1 Dare: 06/12/2007 ProjeC;Lheville Regional Airport Project Latitude: N35.445430 Evaluator:MLJ&PAIB Site: SCP3 Longitude: W82,540940 Total Points: Perennial Stream A Stream is at feast intermittent 35 50 County: Other if>_ 18 or erenniaiif>_30 Buncombe e.g.Quad Name: A. Geomorphology (Subtotal = 17.5 } Absent Weak Moderate Strong 1 3. Continuous bed and bank 2.0 0 1 2 3 2. Sinuosity 3.0 0 1 2 3 3. In-channel structure: riffle-pool sequence 2.0 0 1 2 3 _ 4. Soil texture or stream substrate sorting 2.0 0 1 2 3 S. Active/relic fIoodplain 2.0 0 1 2 3 6. Depositional bars or benches 1.0 0 1 2 3 7. Braided channel 0.0 0 1 2 3 8. Recent alluvial deposits 1.0 0 1 2 3 9 a Natural levees 1.0 0 1 2 3 10_ Headcuts 2.0 0 1 2 3 11_ Grade controls 0.5 0 0.5 1 1.5 12. Natural valley or drainageway 1.0 0 0.5 1 1.5 13. Second or greater order channel on existing USGS or NRCS map or other documented No= 0 Yes= 3 evidence. 0.0 Man-made ditches are not rated;see discussions in manual B. Hydrology {Subtotal = 14. Groundwater flow/discharge 3.0 0 1 2 3 15.Water in channel and > 48 hrs since rain, or 0 1 2 3 Water in channel--dry or growing season 2.0 16. Leaflitter 1.0 1.5 1 0.5 0 17. Sediment on plants or debris 1.0 0 0.5 1 1.5 1 S. Organic debris lines or piles(Wrack lines) 1.0 0 0.5 1 1.5 19. Hydric soils (redoximorphic features) present?1.5 No= 0 Yes= 1.5 C. Biology {Subtotal = 8.50 ) _ 20". Fibrous roots in channel 3.0 3 2 1 0 210. Rooted plants in channel 3.0 3 2 1 0 22. Crayfish 0.0 0 0.5 1 1.5 23. Bivalves 0.0 0 1 2 3 24. Fish 1.0 0 0.5 1 1.5 25. Amphibians 1.0 0 0.5 1 1.5 26. Mac robenthos(note diversity and abundance) 0.5 0 0.5 1 1.5 27_ Filamentous algae: periphyton 0.0 0 1 2 3 28. Iron oxidizing bacteria fungus. 0.0 0 0.5 1 1.5 29 b. Wetland plants in streambed 0.00 FAC= 0.5: FACW=0.75: OBL= 1.5 SAV=2.0; Other=0 'Items 20 and 21 focus on the presence of upland plants, Item 29 focuses on the presence of aquatic or wetland plants. Sketch: Notes: fuse back side of this form for additional notes.) North Carolina Division of Water Quality -Stream Identification Form; Version 3.1 Date: 06/12/2007 Prole Asheville Regional Airport Project Latitude: N35.445430 Evaluator:Mj,J&pAB Site: SCP4 Longitude: W82.540940 Total Points: Unimportant Intermittent Stream rs at least intennittent County' Other if>_ 19 or erennialif>_30 23.50 'Buncombe e.g.Quad Name: Stream B A. Geomorphology (Subtotal = 13.0 ) Absent Weak Moderalte Strong 13. Continuous bed and bank 2.0 0 1 2 3 2. Sinuosity 2.0 0 1 2 3 3. In-channel structure: riffle-pool sequence 1.0 0 1 2 3 4. Soil texture or stream substrate sorting 2.0 0 1 2 3 5. Activelrelic fIoodplain 1.0 0 1 2 3 6. Depositional bars or benches 1.0 0 1 2 3 7. Braided channel 0.0 0 1 2 3 8. Recent alluvial deposits 1.0 0 1 2 3 9 a Natural levees 0.0 0 1 2 3 10. Headcuts 2.0 0 1 2 3 11. Grade controls 0.5 0 0.5 1 1.5 12. Natural valley or drainageway 0.5 0 0.5 1 1.5 13. Second or greater order channel on existing USGS or MRCS map or other documented No=0 Yes= 3 evidence. 0.0 Man-made ditches are not rated;see discussions in manual B. Hydrology (Subtotal = 4.5 14_ Groundwater flov+Wdischarge 1.0 0 1 2 3 15.Water in channel and > 48 hrs since rain, or 0 1 2 3 Water in channel--dry or growing season 0.0 16. Leaflitter 1.0 1.5 1 0.5 0 17. Sediment on plants or debris 0.5 0 0.5 1 1.5 1 S. Organic debris lines or piles(Wrack lines) 0.5 0 0.5 1 1.5 19. Hydric soils (redoximorphic features) present?1.5 No=0 Yes= 1.5 C. Biology (Subtotal 20b. Fibrous roots in channel 3.0 3 2 1 0 21b. Rooted plants in channel 3.0 3 2 1 0 22. Crayfish 0.0 0 0.5 1 1.5 23. Bivalves 0.0 0 1 2 3 24. Fish 0.0 0 0.5 1 1.5 25. Amphibians 0.0 0 0.5 1 1.5 26. Macrobenthos(note diversity and abundance) 0.0 0 0.5 1 1.5 27. Filamentous algae: periphyton 0.0 0 1 2 3 28. Iron oxidizing bacteriatfungus. 0.0 0 0.5 1 1.5 29b. Wetland plants in streambed 0.00 FAC= 0.5: FACW=0.75; OBL= 1.5 SAV=2.0; Other=0 Items 20 and 21 focus on the presence of upland plants, Item 29 focuses on the presence of aquatic or wetland plants. Notes: fuse back side of this form for additional notes:) Sketch: L North Carolina Division of Water Quality -Stream Identification Form; Version 3.1 Date: 06/12/2007 Proieetneviue Regional Airport Project Latitude: N35.44543- Evaluator:NffiJ&pA.B site: SCP5 Longitude: W82,540940 Total Points: Perennial Stream C Stream is at feast intermittent 3 00 County' Other if>_ 19 or erenniaf if?30 a Buncombe e.g.Quad Name. A. Geomor holo (Subtotal = 14.0 1 Absent Weak Moderate:.:. ':' Strong 11 13. Continuous bed and bank 2.0 0 1 2 3 2. Sinuosity 1.0 0 1 2 3 3. In-channel structure: riffle-pool sequence 2.0 0 1 2 3 4. Soil texture or stream substrate sorting 2.0 0 1 2 3 5. Activelrelic floodplain 2.0 0 1 2 3 6. Depositional bars or benches 1.0 0 1 2 3 7. Braided channel 0.0 0 1 2 3 8. Recent alluvial deposits 1.0 0 1 2 3 9 a Natural levees 1.0 0 1 2 3 10. Headcuts 1.0 0 1 2 3 11. Grade controls 0.5 0 0.5 1 1.5 12. Natural valley or drainagewray 0.5 0 0.5 1 1.5 13. Second or greater order channel on existing USGS or NRCS map or other documented No= 0 Yes= 3 evidence. 0.0 Man-made ditches are not rated:see discussions in manual B. Hydrology (Subtotal = 8.5 14. Groundwater flowddischarge 2.0 0 1 2 3 15.Water in channel and > 48 hrs since rain, or 0 1 2 3 Water in channel--dry or grovving season 2.0 16. Leaf Iitter 1.5 1.5 1 0.5 0 17. Sediment on plants or debris 0.5 0 0.5 1 1.5 18. Organic debris lines or piles(Wrack lines) 1.0 0 0.5 1 1.5 19. Hydric soils (redoximorphic features) present?1.5 No= 0 Yes= 1.5 C. Biology (Subtotal = 7.50 ) 20b. Fibrous roots in channel 3.0 3 2 1 0 21b. Rooted plants in channel 3.0 3 2 1 0 22. Crayfish 0.0 0 0.5 1 1.5 23. Bivalves 0.0 0 1 2 3 24. Fish 0.0 0 0.5 1 1.5 25. Amphibians 0.5 0 0.5 1 1.5 26. Mac robenthos(n ote diversity and abundance) 0.5 0 0.5 1 1.5 27. Filamentous algae: periphyton 0.0 0 1 2 3 28. Iron oxidizing bacteriatfungus. 0.5 0 0.5 1 1.5 29 b. Wetland plants in streambed 0.00 FAC= 0.5: FACW=0.75; OBL 1.5 SAV=2.0; Other=0 'Items 20 and 21 focus on the presence of upland plants, Item 29 focuses on the presence of aquatic or wetland plants. Sketch: Notes: (use back side of this form for additional notes.) OFFICE USE ONLY: USACE AID# DWQ# SCP1 —Perennial Stream A STREAM QUALITY ASSESSMENT WORKSHEET M T ` 1.Applicant's Name: Asheville Regional Airport Authority 2.Evaluator's Name:-Matt Jenkins and Paul Bright 3. Date of Evaluation: 6/12/07 4.Time of Evaluation: 12:00 pm 5. Name of Stream: UT to Broad River 6.River Basin: Broad 7. Approximate Drainage Area: 65 acres S. Stream Order: First ll T �tcit c ,ivateC: `00 �:- .0 uuniy: Buncombe 11. Location of reach under evaluation (include nearby roads and landmarks):_ Travel south on Interstate 85 (1-85) and merge onto I-26 West via Exit 70 toward Asheville. Travel approxitnately 48.6 miles and take the NC-280 exit Exit 40 toward Asheville Regional Airport/Arden. Travel approximately 0 2 mile and turn left onto New Airport Road/NC 280 Travel approximately 0 2 mile and turn right onto General Aviation Drive. Travel aivroximately 0.3 mile and the site will be straight ahead. 12. Site Coordinates(if known): N35.445430 W82.540940 13.Proposed Channel Work(if any): N/A 14.Recent Weather Conditions: no rain within the past 48 hours 15. Site conditions at time of visit: sunny 80 degrees 16.Identify any special waterway classifications known: _Section 10 _Tidal Waters _Essential Fisheries Habitat _Trout Waters _Outstanding Resource Waters _Nutrient Sensitive Waters _Water Supply Watershed (I-IV) 17. Is there a pond or lake located upstream of the evaluation point? YES NO If yes,estimate the water surface area: 18.Does channel appear on USGS quad map?(a) NO 19.Does channel appear on USDA Soil Survey? YE NO 20.Estimated Watershed Land Use: _%Residential 40 %Commercial _%Industrial _%Agricultural 10 %Forested 50 %Cleared/Logged _%Other( ) 21.Bankfull Width: 4-5' 22.Bank Height(from bed to top of bank): 3-4' 23. Channel slope down center of stream: _Flat(0 to 2%) X Gentle(2 to 4%) _Moderate(4 to 10%) _Steep(>10%) 24. Channel Sinuosity: Straight _Occasional Bends X Frequent Meander _Very Sinuous _Braided Channel Instructions for completion of worksheet (located on page 2): Begin by determining the most appropriate ecoregion based on location, terrain, vegetation, stream classification, etc. Every characteristic must be scored using the same ecoregion. Assign points to each characteristic within the range shown for the ecoregion. Page 3 provides a brief description of how to review the characteristics identified in the worksheet. Scores should reflect an overall assessment of the stream reach under evaluation. If a characteristic cannot be evaluated due to site or weather conditions,enter 0 in the scoring box and provide an explanation in the comment section. Where there are obvious changes in the character of a stream under review (e.g., the stream flows from a pasture into a forest), the stream may be divided into smaller reaches that display more continuity,and a separate form used to evaluate each reach. The total score assigned to a stream reach must range between 0 and 100,with a score of 100 representing a stream of the highest quality. Total Score (from reverse): 49 Comments: Evaluator's Signature Date This channel evaluation form is intended to be used only as a guide to assist landowners and environmental professionals in gathering the data required by the United States Army Corps of Engineers in order to make a preliminary assessment of stream quality. The total score resulting from the completion of this form is subject to USACE approval and does not imply a particular mitigation ratio or requirement. Form subject to change—version 05/03. To Comment,please call 919-876-8441 x 26. 1 STREAM QUALITY ASSESSMENT WORKSHEET SCP1 — Perennial Stream A CEIAA+ �'ES 'lC5 .: _xVGE Cbastai Fiedt one 4kiauntain S ORE`, Presence of flow-`persistent pools in stream ! (no flow or saturation -0:strong flow=max points)_ j Evidence of past human alteration -( f; - 5 2 (extensive alteration, :-- o c� �tat��n- 0; a, alteration=max ncsint.) Riparian zone � � � ) 0 0 -o l-4 t ino h1ltier0-; i;Onti?UOtati. 11""Cicr Ilia.\:)0i isi E idenc of nutrient or dhemical disch ar==es ----- - T i -* I O—� 0-4 j-4 I i (estensi-c discharues 0 no tischar,res=m i.,points roandlv rtur �fischar;;e wo dischar-e 0: ,prim-s sceps, vvr tlands-etc, nax pints) Presence of adjacent floodplain i 0 4 0--4 0-2 2 - (hotloodplain 0,extensive floodplam=nz nts) _ Entrenchment/tloodplain access O 5 0 4 () 2 ^^ (deeply entrenched_=01 #r eluerrt iloding=maxpoir,rs) i i Presence of adjjacent wetlands 0 d t 0 - j 0 ( (no wetlands 0, large adjacent.wetlands max p pints} ( i � i Channel sinuosit y ' 9 i ` 0 5 � 0 �� (extensive channelization=0:natural mcamier niax ponts) _ l0 Sediment input ( 0 4 t 0 4 3 (extensive de c>sitton=O, little or no sediment ma e «hits) Size&:diversity of channel bed substrate 3 { 1i Nam* 0-4 0- 5 j 3 (fine,homogenous=0 laz Vie, diverse sizes--inax points) ? Evidence of channel incision or widenin { _ I 0 5 U l 0- ; 2 ,`� ; l` � (deeply incised 0;_stable bed&.banks =maw rots; � � I Presence of major bank failures � z 5 J � _j_(severe erosion 0,no erosion- stable banks-= tnax points) 0 0 5 Ck 5 3 Root depth and density on bank dL 14 1 n - ^ 0 4 0 5 2 (no visible roots C; dense roots throughout= max ants) ' Impact by a-riculture or livestock production 15 (substantial impact :,no evidence ,max points) I �} S r) � � 0 D 1 4 Presence of riffle-pool/ripple-pool complexes �y C ib 0 3 f 0 -5 0 t 4 (no rz(fes ripples ur�0; well-developed' ma<x points) Habitat complexity 17 I (little or no habitat 0: fi etdu_en gal r ed habitats max oInts} � 0 �' i 0 0 � � 5 � 3 ! Canopy coverage over streambed es I , 0 5 r 0 -; 0 5 W (no shading vegetation 0, Continuous canopy max points) � � � 10 Substrate embeddedness 1 0 4 4 2 —L (deeply embedded 0 loose structure=max) 0 Presence of stream invertebrates i 0 -4 (} 0 ti 2 ( no evidence 0;common_numerous types=nz tx points} i Presence of`amphibians 0 4 () 4 ) 4 �. - �(no evidence=0. common,numerous types-max DOurts) 1 Presence offish f 4' (no evidence=0: common,numerous t pes max point>} � 0 4 0 4 i 0 4 F _-__i f" Evidence of wildlife use 1 ,3 _il. 6 0-5 : 5 (1 (no evidence -0: abundazit evidence max n inis) I I 'Total Points Possible 00 100 I00 uv k? TOTAL SCORE (also ent(z on first page) these charac[ens tics are not �n coastal streams_ OFFICE USE ONLY: USACE AID# DW!# i SCP2 -Perennial Stream A �F LEI:] STREAM QUALITY ASSESSMENT WORKSHEET 1.Applicant's Name: Asheville Regional Airport Authority 2.Evaluator's Name: Matt Jenkins and Paul Bright J.Date of Evaluation: 6/12/07 4.Time of Evaluation: 12:30 pm 5.Name of Stream: UT to Broad River 6.River Basin: Broad 7. Approximate Drainage Area: 65 acres 8. Stream Order: First 9.Length of Reach Evaluated: 200 if 10. County: Buncombe 11. Location of reach under evaluation (include nearby roads and landmarks): Travel south on Interstate 85 (I-85) and merge onto I-26 West via Exit 70 toward Asheville. Travel approximately 48.6 miles and take the NC-280 exit (Exit 40) toward Asheville Regional Airport/Arden. Travel approximately 0.2 mile and turn left onto New Airport Road/NC-280. Travel approximately 0.2 mile and turn right onto General Aviation Drive. Travel approximately 0.3 mile and the site will be straight ahead. 12. Site Coordinates(if known): N35.445430, W82.540940 13.Proposed Channel Work(if any): N/A 14.Recent Weather Conditions:no rain within the past 48 hours 15. Site conditions at time of visit: sunny 80 degrees 16. Identify any special waterway classifications known: _Section 10 _Tidal Waters _Essential Fisheries Habitat _Trout Waters _Outstanding Resource Waters _Nutrient Sensitive Waters _Water Supply Watershed (I-IV) 17. Is there a pond or lake located upstream of the evaluation point? YES NO If yes, estimate the water surface area: 18.Does channel appear on USGS quad map? YE NO 19. Does channel appear on USDA Soil Survey?(D NO 20.Estimated Watershed Land Use: _%Residential 40 %Commercial _%Industrial _%Agricultural 10 %Forested 50 %Cleared/Logged _%Other( ) 21.Bankfull Width: 4-5' 22.Bank Height(from bed to top of bank): 4-5' 23. Channel slope down center of stream: _Flat(0 to 2%) X Gentle(2 to 4%) _Moderate(4 to 10%) _Steep(>10%) 24. Channel Sinuosity: Straight _Occasional Bends X Frequent Meander _Very Sinuous _Braided Channel Instructions for completion of worksheet (located on page 2): Begin by determining the most appropriate ecoregion based on location, terrain, vegetation, stream classification, etc. Every characteristic must be scored using the same ecoregion. Assign points to each characteristic within the range shown for the ecoregion. Page 3 provides a brief description of how to review the characteristics identified in the worksheet. Scores should reflect an overall assessment of the stream reach under evaluation. If a characteristic cannot be evaluated due to site or weather conditions, enter 0 in the scoring box and provide an explanation in the comment section. Where there are obvious changes in the character of a stream under review (e.g., the stream flows from a pasture into a forest), the stream may be divided into smaller reaches that display more continuity, and a separate form used to evaluate each reach. The total score assigned to a stream reach must range between 0 and 100,with a score of 100 representing a stream of the highest quality. Total Score (from reverse): 51 Comments: Evaluator's Signature Date This channel evaluation form is intended to be used only as a guide to assist landowners and environmental professionals in gathering the data required by the United States Army Corps of Engineers in order to make a preliminary assessment of stream quality. The total score resulting from the completion of this form is subject to USACE approval and does not imply a particular mitigation ratio or requirement. Form subject to change-version 05/03. To Comment,please call 919-876-8441 x 26. 1 STREAM QUALITY ASSESSMENT WORKSHEET SCP2 — Perennial Stream A 1,1 2 MIN s� 3 r IN - R 3 2 2 0 3 3 3 2 3 3 4 - - 4 3 0 3 2 2 0 0 51 *These characteristics are not assessed in coastal streams. 2 OFFICE USE ONLY: USACE AID# DWQ# SCP3—Perennial Stream A o ; STREAM QUALITY ASSESSMENT WORKSHEET 1.Applicant's Name: Asheville Regional Airport Authority 2.Evaluator's Name:Matt Jenkins and Paul Bright 3. Date of Evaluation: 6/12/07 4. Time of Evaluation: 1:00 pm 5.Name of Stream: UT to Broad River 6. River Basin: Broad I Approximate Drainage Area: 65 acres S. Stream Order: First G, L inL)IIi oC Re,`C 1 E';',IiLillca: 0G) l ). _JL;1lL'.' �iunc'ombe I I. Location of reach under evaluation (include nearby roads and landmarks): Travel south on Interstate 85 (1-85) and merge onto I-26 West via Exit 70 toward Asheville. Travel approximately 48.6 miles and take the NC-280 exit (Exit 40) toward Asheville Regional Airport/Arden. Travel approximately 0.2 mile and turn left onto New Airport Road/NC-280 Travel approximately 0 2 mile and turn right onto General Aviation Drive. Travel approximately 0.3 mile and the site will be straight ahead. 12. Site Coordinates(if known): N35.445430 W82.540940 13. Proposed Channel Work(if any): N/A 14. Recent Weather Conditions:no rain within the past 48 hours 15. Site conditions at time of visit: sunny 80 degrees 16.Identify any special waterway classifications known: _Section 10 _Tidal Waters _Essential Fisheries Habitat _Trout Waters _Outstanding Resource Waters _Nutrient Sensitive Waters _Water Supply Watershed (I-IV) 17.Is there a pond or lake located upstream of the evaluation point? YES NO If yes,estimate the water surface area: 18. Does channel appear on USGS quad map?Q NO 19. Does channel appear on USDA Soil Survey? YE NO 20.Estimated Watershed Land Use: _%Residential 40%Commercial _%Industrial _%Agricultural 10 %Forested 50 %Cleared/Logged _%Other( ) 21.Bankfull Width: 4-5' 22. Bank Height(from bed to top of bank): 4-5' 23. Channel slope down center of stream: _Flat(0 to 2%) X Gentle(2 to 4%) _Moderate(4 to 10%) _Steep(,-10%) 24. Channel Sinuosity: Straight _Occasional Bends X Frequent Meander _Very Sinuous _Braided Channel Instructions for completion of worksheet (located on page 2): Begin by determining the most appropriate ecoregion based on location, terrain, vegetation, stream classification, etc. Every characteristic must be scored using the same ecoregion. Assign points to each characteristic within the range shown for the ecoregion. Page 3 provides a brief description of how to review the characteristics identified in the worksheet. Scores should reflect an overall assessment of the stream reach under evaluation. If a characteristic cannot be evaluated due to site or weather conditions, enter 0 in the scoring box and provide an explanation in the comment section. Where there are obvious changes in the character of a stream under review (e.g., the stream flows from a pasture into a forest), the stream may be divided into smaller reaches that display more continuity,and a separate form used to evaluate each reach. The total score assigned to a stream reach must range between 0 and 100,with a score of 100 representing a stream of the highest quality. Total Score (from reverse): 53 Comments: Evaluator's Signature Date This channel evaluation form is intended to be used only as a guide to assist landowners and environmental professionals in gathering the data required by the United States Army Corps of Engineers in order to make a preliminary assessment of stream quality. The total score resulting from the completion of this form is subject to USACE approval and does not imply a particular mitigation ratio or requirement. Form subject to change—version 05/03. To Comment,please call 919-876-8441 x 26. 1 STREAM QUALITY ASSESSMENT WORKSHEET SCP3 — Perennial Stream A 4 fill Fm 0 Evidence of nutrient or chemreal discharges. (extensive discharges—0;no discharges-max points) 0 � � � Ca�awtdrvatg disehu�!{T�e i 2 2 0 3 3 3 2 3 3 4 4 3 0 3 2 2 _ 2 0 53 *These characteristics are not assessed in coastal streams. 2 OFFICE USE ONLY: USACE AID# DWQ# SCP4—Unimportant Intermittent Stream B STREAM QUALITY ASSESSMENT WORKSHEET 1.Applicant's Name: Asheville Regional Airport Authority 2.Evaluator's Name: Matt Jenkins and Paul Bright 3.Date of Evaluation: 6/12/07 4.Time of Evaluation: 1:30 pm 5.Name of Stream: UT to Broad River 6.River Basin: Broad 7.Approximate Drainage Area: 5 acres 8. Stream Order: First L-ngth or Reach L Valuated: 100 If !0. : .-,univ: Buncombe 11. Location of reach under evaluation (include nearby roads and landmarks): Travel south on Interstate 85 (I-85) and merge onto I-26 West via Exit 70 toward Asheville. Travel approximately 48.6 miles and take the NC-280 exit (Exit 40) toward Asheville Regional Airport/Arden. Travel approximately 0.2 mile and turn left onto New Airport Road/NC-280. Travel approximately 0.2 mile and turn right onto General Aviation Drive. Travel approximately 0.3 mile and the site will be straight ahead. 12. Site Coordinates(if known): N35.445430 W82.540940 13.Proposed Channel Work(if any): N/A 14.Recent Weather Conditions:no rain within the past 48 hours 15. Site conditions at time of visit: sunny 80 degrees 16. Identify any special waterway classifications known: _Section 10 _Tidal Waters _Essential Fisheries Habitat _Trout Waters _Outstanding Resource Waters _Nutrient Sensitive Waters _Water Supply Watershed (I-IV) 17.Is there a pond or lake located upstream of the evaluation point? YES NO If yes, estimate the water surface area: 18.Does channel appear on USGS quad map? YEN 19. Does channel appear on USDA Soil Survey? YES 20. Estimated Watershed Land Use: _%Residential _%Commercial _%Industrial _%Agricultural _%Forested 100%Cleared/Logged _%Other( ) 21.Bankfull Width: 34' 22.Bank Height(from bed to top of bank): 34' 23. Channel slope down center of stream: _Flat(0 to 2%) X Gentle(2 to 4%) _Moderate(4 to 10%) _Steep (>10%) 24. Channel Sinuosity: Straight _Occasional Bends X Frequent Meander _Very Sinuous _Braided Channel Instructions for completion of worksheet (located on page 2): Begin by determining the most appropriate ecoregion based on location, terrain, vegetation, stream classification, etc. Every characteristic must be scored using the same ecoregion. Assign points to each characteristic within the range shown for the ecoregion. Page 3 provides a brief description of how to review the characteristics identified in the worksheet. Scores should reflect an overall assessment of the stream reach under evaluation. If a characteristic cannot be evaluated due to site or weather conditions,enter 0 in the scoring box and provide an explanation in the comment section. Where there are obvious changes in the character of a stream under review (e.g., the stream flows from a pasture into a forest), the stream may be divided into smaller reaches that display more continuity, and a separate form used to evaluate each reach. The total score assigned to a stream reach must range between 0 and 100,with a score of 100 representing a stream of the highest quality. Total Score (from reverse): 27 Comments: Evaluator's Signature Date This channel evaluation form is intended to be used only as a guide to assist landowners and environmental professionals in gathering the data required by the United States Army Corps of Engineers in order to make a preliminary assessment of stream quality. The total score resulting from the completion of this form is subject to USACE approval and does not imply a particular mitigation ratio or requirement. Form subject to change—version 05/03. To Comment,please call 919-876-8441 x 26. 1 STREAM QUALITY ASSESSMENT WORKSHEET SCP4 — Unimportant Intermittent Stream B . o OP x sc, 1 Kvidence of nutrient or chew cat disehar"es' 0 5 0-4 0 4, (extensive discharges—0,no discharges=maxipoints) <.�,s C�rou�dwater d��ehar� � 4 1 0 2 2 3 2 2 3 4 1 0 0 2 0 0 0 0 27 *These characteristics are not assessed in coastal streams. 2 OFFICE USE ONLY: USACE AID# DWQ# SCP5—Perennial Stream C STREAM QUALITY ASSESSMENT WORKSHEET M T 1.Applicant's Name: Asheville Regional Airnort Authority 2.Evaluator's Name: Matt Jenkins and Paul Bright 3. Date of Evaluation: 6/12/07 4.Time of Evaluation: 2:30 pm 5.Name of Stream: UT to Broad River 6. River Basin: Broad Approximate Drainage Area: 5 acres 8. Stream Order: First 1 T.i. t: t�� ;LP `i:1-tC mC 11. Location of reach under evaluation (include nearby roads and landmarks): Travel south on Interstate 85 (1-85) and merge onto I-26 West via Exit 70 toward Asheville. Travel approximately 48.6 miles and take the NC-280 exit (Exit 40) toward Asheville Regional Airport/Arden. Travel approximately 0.2 mile and turn left onto New Airport Road/NC-280. Travel approximately 0.2 mile and turn right onto General Aviation Drive. Travel approximately 0.3 mile and the site will be straight ahead. 12. Site Coordinates(if known): N35.445430 W82.540940 13.Proposed Channel Work(if any): N/A 14. Recent Weather Conditions:no rain within the past 48 hours 15. Site conditions at time of visit: sunny 80 degrees 16. Identify any special waterway classifications known: _Section 10 _Tidal Waters _Essential Fisheries Habitat _Trout Waters _Outstanding Resource Waters Nutrient Sensitive Waters _Water Supply Watershed (I-IV) 17. Is there a pond or lake located upstream of the evaluation point? YES(NO) If yes, estimate the water surface area: 18. Does channel appear on USGS quad map? YES NO 19.Does channel appear on USDA Soil Survey? YES NO 20.Estimated Watershed Land Use: %Residential _%Commercial _%Industrial _%Agricultural 60 %Forested 40 %Cleared/Logged %Other( ) 21.Bankfull Width: 1-2' 22.Bank Height(from bed to top of bank): 0-2' 23. Channel slope down center of stream: X Flat(0 to 2%) _Gentle(2 to 4%) _Moderate(4 to 10%) _Steep(>10%) 24. Channel Sinuosity: Straight X Occasional Bends _Frequent Meander _Very Sinuous _Braided Channel Instructions for completion of worksheet (located on page 2): Begin by determining the most appropriate ecoregion based on location, terrain, vegetation, stream classification, etc. Every characteristic must be scored using the same ecoregion. Assign points to each characteristic within the range shown for the ecoregion. Page 3 provides a brief description of how to review the characteristics identified in the worksheet. Scores should reflect an overall assessment of the stream reach under evaluation. If a characteristic cannot be evaluated due to site or weather conditions,enter 0 in the scoring box and provide an explanation in the comment section. Where there are obvious changes in the character of a stream under review (e.g., the stream flows from a pasture into a forest), the stream may be divided into smaller reaches that display more continuity, and a separate form used to evaluate each reach. The total score assigned to a stream reach must range between 0 and 100,with a score of 100 representing a stream of the highest quality. Total Score (from reverse): 55 Comments: Evaluator's Signature Date This channel evaluation form is intended to be used only as a guide to assist landowners and environmental professionals in gathering the data required by the United States Army Corps of Engineers in order to make a preliminary assessment of stream quality. The total score resulting from the completion of this form is subject to USACE approval and does not imply a particular mitigation ratio or requirement. Form subject to change—version 05/03. To Comment,please call 919-876-8441 x 26. 1 STREAM QUALITY ASSESSMENT WORKSHEET SCP5 — Perennial Stream C 4 y >y ( auffe _eorgzaus;;`wtcesre r `ins ot } .; Evidence of nutrient or chemical discharges �' 0-5 f I estensille dischar,2es=0_no discharges—�nax points) M oundwater discharge w ate' 2 2 2 2 3 4 4 3 4 3 3 4 2 1 1 0 0 55 *These characteristics are not assessed in coastal streams. 2 APPROVED JURISDICTIONAL DETERMINATION FORM U.S.Army Corps of Engineers This form should be completed by following the instructions provided in Section IV of the JD Form Instructional Guidebook. SECTION I: BACKGROUND INFORMATION A. REPORT COMPLETION DATE FOR APPROVED JURISDICTIONAL DETERMINATION(JD):July 16,2007 B. DISTRICT OFFICE,FILE NAME,AND NUMBER:Asheville Regional Office C. PROJECT LOCATION AND BACKGROUND INFORMATION:The Asheville Regional Airport Expansion site is located adjacent to Highway 26,on existing Airport Authority property in Fletcher,North Carolina,Perennial Stream A-Upper Reach State:NC County/parish/borough: Buncombe City: Fletcher .,CIlt� ...)�-1 Cil<<at�; _�I ,��„ !lii,��t1�i❑UC22 Ce PLC ('lL .Gi„1d1.;: ._�l C. �_ .-�t.l_� ��, �tl�. J�..:°�_��° ;V. �ni•,,.rs-al Truax ...-,.`vi:.._aia-: Name of nearest waterbody: French Broad River Name of nearest Traditional Navigable Water(TNW)into which the aquatic resource flows:French Broad River Name of watershed or Hydrologic Unit Code(HUC):06010105 Check if map/diagram of review area and/or potential jurisdictional areas is/are available upon request. Check if other sites(e.g.,offsite mitigation sites,disposal sites,etc...)are associated with this action and are recorded on a different JD form. D. REVIEW PERFORMED FOR SITE EVALUATION(CHECK ALL THAT APPLY): Office(Desk)Determination. Date:June 19,2007 Field Determination. Date(s):June 13,2007 SECTION II: SUMMARY OF FINDINGS A. RHA SECTION 10 DETERMINATION OF JURISDICTION. There' ,navigable waters of the U.S."within Rivers and Harbors Act(RHA)jurisdiction(as defined by 33 CFR part 329)in the review area.[Required] Waters subject to the ebb and flow of the ride. Waters are presently used,or have been used in the past,or may be susceptible for use to transport interstate or foreign commerce. Explain: B. CWA SECTION 404 DETERMINATION OF JURISDICTION. "There ,waters of the U.S."within Clean Water Act(CWA)jurisdiction(as defined by 33 CFR part 328)in the review area.[Required] 1. Waters of the U.S. a. Indicate presence of waters of U.S.in review area(check all that apply): 1 TNWs,including territorial seas Wetlands adjacent to TNWs Relatively permanent watersz(RPWs)that flow directly or indirectly into TNWs Non-RPWs that flow directly or indirectly into TNWs Wetlands directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to but not directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs Impoundments of jurisdictional waters Isolated(interstate or intrastate)waters,including isolated wetlands b. Identify(estimate)size of waters of the U.S.in the review area: Non-wetland waters: 17461inear feet: width(ft)and/or 0.256 acres. Wetlands: 0.209 acres. c.Limits(boundaries)of jurisdiction based on: Elevation of established OHWM(if known): 2. Non-regulated waters/wetlands(check if applicable):3 Potentially jurisdictional waters and/or wetlands were assessed within the review area and determined to be not jurisdictional. Explain: v Boxes checked below shall be supported by completing the appropriate sections in Section III below. Z For purposes of this form,an RPW is defined as a tributary that is not a TNW and that typically flows year-round or has continuous flow at least"seasonally" (e.g.,typically 3 months). 3 Supporting documentation is presented in Section III.F. • SECTION III: CWA ANALYSIS A. TNWs AND WETLANDS ADJACENT TO TNWs The agencies will assert jurisdiction over TNWs and wetlands adjacent to TNWs. If the aquatic resource is a TNW,complete Section III.A.1 and Section III.D.1.only;if the aquatic resource is a wetland adjacent to a TNW,complete Sections III.A.1 and 2 and Section III.D.1.;otherwise,see Section IH.B below. 1. TNW Identify TNW: Summarize rationale supporting detenmination: _. Wetland adjacent to Tel»% j Ui111118rIYJ T'fttl Ull Dill:SIRJ�iI 1 Ih CURC1Ll�K>li ila ':��CLllili l� .11J iiti�;l i. ; B. CHARACTERISTICS OF TRIBUTARY(THAT IS NOT A TNW)AND ITS ADJACENT WETLANDS(IF ANY): This section summarizes information regarding characteristics of the tributary and its adjacent wetlands,if any,and it helps determine whether or not the standards for jurisdiction established under Rapanos have been met. The agencies will assert jurisdiction over non-navigable tributaries of TNWs where the tributaries are"relatively permanent waters"(RPWs),i.e.tributaries that typically flow year-round or have continuous flow at least seasonally(e.g.,typically 3 months).A wetland that directly abuts an RPW is also jurisdictional.If the aquatic resource is not a TNW,but has year-round (perennial)flow,skip to Section HI.D.2.If the aquatic resource is a wetland directly abutting a tributary with perennial flow, skip to Section HI.D.4. A wetland that is adjacent to but that does not directly abut an RPW requires a significant nexus evaluation.Corps districts and EPA regions will include in the record any available information that documents the existence of a significant nexus between a relatively permanent tributary that is not perennial(and its adjacent wetlands if any)and a traditional navigable water,even though a significant nexus finding is not required as a matter of law. If the waterbody°is not an RPW,or a wetland directly abutting an RPW,a JD will require additional data to determine if the waterbody has a significant nexus with a TNW.If the tributary has adjacent wetlands,the significant nexus evaluation must consider the tributary in combination with all of its adjacent wetlands.This significant nexus evaluation that combines,for analytical purposes,the tributary and all of its adjacent wetlands is used whether the review area identified in the JD request is the tributary,or its adjacent wetlands,or both.If the JD covers a tributary with adjacent wetlands,complete Section III.B.1 for the tributary,Section HI.B.2 for any onsite wetlands,and Section HI.B.3 for all wetlands adjacent to that tributary,both onsite and offsite.The determination whether a significant nexus exists is determined in Section IH.0 below. 1. Characteristics of non-TNWs that flow directly or indirectly into TNW (i) General Area Conditions: Watershed size: 1,196,80 Drainage area: 1.68 Average annual rainfall:38.1 inches Average annual snowfall: 15.6 inches (ii) Physical Characteristics: (a) Relationship with TNW: ❑Tributary flows directly into TNW. ®Tributary flows through tributaries before entering TNW. Project waters are river miles from TNW. Project waters are river miles from RPW. Project waters are aerial(straight)miles from TNW. Project waters are aerial(straight)miles from RPW. Project waters cross or serve as state boundaries.Explain:N/A. Identify flow route to TNW5:Perennial Stream A and is met by Unimportant Intermittent Stream B,then flows through project area to French Broad River. "Note that the Instructional Guidebook contains additional information regarding swales,ditches,washes,and erosional features generally and in the and West. 5 Flow route can be described by identifying,e.g.,tributary a,which flows through the review area,to flow into tributary b,which then flows into TNW. v Tributary stream order,if known: 1. (b) General Tributary Characteristics(check all that apply): Tributary is: ®Natural ❑Artificial(man-made). Explain: ❑ Manipulated (man-altered). Explain: Tributary properties with respect to top of bank(estimate): Average width:4-5 feet Average depth:3-4 feet Average side slopes Primary tributary substrate composition(check all that apply): n Silts ❑ Sands Concrc'e ❑ Bcdrock ❑ `. egetaticai. ;pe;'°'o cove;: ❑ Other.Explain: Tributary condition/stability[e.g.,highly eroding,sloughing banks]. Explain:moderate erosion and an incised channel. Presence of run/riffle/ ool com lexes. Explain:moderate riffle/pool complexes. Tributary geometry: Tributary gradient(approximate average slope):2-4% (c) Flow: Tributary provides for: Estimate average number of flow events in review area/year: Describe flow regime: Other information on duration and volume: Surface flow is:' . Characteristics: Subsurface flow: . Explain findings: Groundwater present in channel,no rain within last 48 hours. ❑ Dye(or other)test performed: Tributary has(check all that apply): ® Bed and banks ® OHWM6(check all indicators that apply): ❑ clear,natural line impressed on the bank ❑ the presence of litter and debris ® changes in the character of soil ❑ destruction of terrestrial vegetation ❑ shelving ❑ the presence of wrack line ® vegetation matted down,bent,or absent ❑ sediment sorting ® leaf litter disturbed or washed away ® scour ® sediment deposition ❑ multiple observed or predicted flow events ❑ water staining ❑ abrupt change in plant community ❑ other(list): ❑ Discontinuous OHWM.7 Explain: If factors other than the OHWM were used to determine lateral extent of CWA jurisdiction(check all that apply): High Tide Line indicated by: 1M Mean High Water Mark indicated by: ❑ oil or scum line along shore objects ❑ survey to available datum; ❑ fine shell or debris deposits(foreshore) ❑physical markings; ❑ physical markings/characteristics ❑ vegetation lines/changes in vegetation types. ❑ tidal gauges ❑ other(list): (iii) Chemical Characteristics: Characterize tributary(e.g.,water color is clear,discolored,oily film;water quality;general watershed characteristics,etc.). Explain:clear water. Identify specific pollutants,if known: 6A natural or man-made discontinuity in the OHWM does not necessarily sever jurisdiction(e.g.,where the stream temporarily flows underground,or where the OHWM has been removed by development or agricultural practices). Where there is a break in the OHWM that is unrelated to the waterbody's flow regime(e.g.,flow over a rock outcrop or through a culvert),the agencies will look for indicators of flow above and below the break. 'Ibid. (iv) Biological Characteristics. Channel supports(check all that apply): ® Riparian corridor. Characteristics(type,average width): ❑ Wetland fringe. Characteristics: ❑ Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑Aquatic/wildlife diversity. Explain findings: 2. Characteristics of wetlands adjacent to non-TNW that flow directly or indirectly into TNW (i) Physical Characteristics: (a) General Wetland Characteristics: °r�mertics: Nctland type. c:plain: Wetland quality. Explain: Project wetlands cross or serve as state boundaries.Explain: (b) General Flow Relationship with Non-TNW: Flow is: . Explain: Surface flow MIM Characteristics: Subsurface flow:' ,,,_} . Explain findings: ❑ Dye(or other)test performed: (c) Wetland Adjacency Determination with Non-TNW: ❑ Directly abutting ❑Not directly abutting ❑ Discrete wetland hydrologic connection. Explain: ❑ Ecological connection. Explain: ❑ Separated by berm/barrier. Explain: (d) Proximity(Relationship)to TNW Project wetlands are^ river miles from TNW. Project waters are '` aerial(straight)miles from TNW. Flow is from: Estimate approximate location of wetland as within the floodplain. (ii) Chemical Characteristics: Characterize wetland system(e.g.,water color is clear,brown,oil film on surface;water quality;general watershed characteristics;etc.). Explain: Identify specific pollutants,if known: (iii)Biological Characteristics. Wetland supports(check all that apply): ❑ Riparian buffer. Characteristics(type,average width): ❑ Vegetation type/percent cover. Explain: ❑ Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑Aquatic/wildlife diversity. Explain findings: 3. Characteristics of all wetlands adjacent to the tributary(if any) All wetland(s)being considered in the cumulative analysis:Mum Approximately( )acres in total are being considered in the cumulative analysis. For each wetland,specify the following: Directly abuts?(Y/N) Size(in acres) Directly abuts?(Y/N) Size(in acres) Summarize overall biological,chemical and physical functions being performed: C. SIGNIFICANT NEXUS DETERMINATION A Significant nexus aaaivsis�Y iii assess �Ae ilo%v c}iaracteristics and 1nnctions of the Eributar-; itself aim -he i'uacdons performed by any wetlands adjacent to the tributary to determine if they significantly affect the chemical,physical,and biological integrity of a TNW. For each of the following situations,a significant nexus exists if the tributary,in combination with all of its adjacent wetlands,has more than a speculative or insubstantial effect on the chemical,physical and/or biological integrity of a TNW. Considerations when evaluating significant nexus include,but are not limited to the volume,duration,and frequency of the flow of water in the tributary and its proximity to a TNW,and the functions performed by the tributary and all its adjacent wetlands. It is not appropriate to determine significant nexus based solely on any specific threshold of distance(e.g.between a tributary and its adjacent wetland or between a tributary and the TNW).Similarly,the fact an adjacent wetland lies within or outside of a floodplain is not solely determinative of significant nexus. Draw connections between the features documented and the effects on the TNW,as identified in the Rapanos Guidance and discussed in the Instructional Guidebook.Factors to consider include,for example: • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to carry pollutants or flood waters to TNWs,or to reduce the amount of pollutants or flood waters reaching a TNW? • Does the tributary,in combination with its adjacent wetlands(if any),provide habitat and lifecycle support functions for fish and other species,such as feeding,nesting,spawning,or rearing young for species that are present in the TNW? • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to transfer nutrients and organic carbon that support downstream foodwebs? • Does the tributary,in combination with its adjacent wetlands(if any),have other relationships to the physical,chemical,or biological integrity of the TNW? Note:the above list of considerations is not inclusive and other functions observed or known to occur should be documented below: 1. Significant nexus findings for non-RPW that has no adjacent wetlands and flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary itself,then go to Section III.D: 2. Significant nexus findings for non-RPW and its adjacent wetlands,where the non-RPW flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: 3. Significant nexus findings for wetlands adjacent to an RPW but that do not directly abut the RPW.Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: D. DETERMINATIONS OF JURISDICTIONAL FINDINGS.THE SUBJECT WATERS/WETLANDS ARE(CHECK ALL THAT APPLY): 1. TNWs and Adjacent Wetlands. Check all that apply and provide size estimates in review area: TNWs: linear feet width(ft),Or, acres. Wetlands adjacent to TNWs: acres. 2. RPWs that flow directly or indirectly into TNWs. Tributaries of TNWs where tributaries typically flow year-round are jurisdictional.Provide data and rationale indicating that tributary is perennial:Perennial Stream A-Upper Reach flows through the middle of the project site and is 243 linear feet with widths of 4-5 feet. Stream A exhibited groundwater flow,riffle/pool sequences,moderate sinuosity,and a strong presence of amphibians Stream A-Upper Reach scored 49 out of a possible 100 points on the USACE Stream Quality Assesment form and 33.5 out of 70 points on the NC DWQ Stream ID form . Tributaries of TNW where tributaries have continuous flow"seasonally"(e.g.,typically three months each year)are jurisdictional. Data supporting this conclusion is provided at Section III.B. Provide rationale indicating that tributary flows seasonally: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters:243 linear feet4-5width(ft). El Other non-wetland waters: acres. Identify type(s)of waters: 3. Non-RPWss that flow directly or indirectly into TNWs. Waterbody that is not a TNW or an RPW,but flows directly or indirectly into a TNW,and it has a significant nexus with a TNW is jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional waters within the review area(check all that apply): Wither non ,n-etlanc aicris: ,�,__-. identify typc(sj of vaLcrs: 4. Wetlands directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands directly abut RPW and thus are jurisdictional as adjacent wetlands. Wetlands directly abutting an RPW where tributaries typically flow year-round. Provide data and rationale indicating that tributary is perennial in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Wetlands directly abutting an RPW where tributaries typically flow"seasonally." Provide data indicating that tributary is seasonal in Section III.13 and rationale in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Provide acreage estimates for jurisdictional wetlands in the review area: acres. 5. Wetlands adjacent to but not directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands that do not directly abut an RPW,but when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisidictional.Data supporting this conclusion is provided at Section III.C. Provide acreage estimates for jurisdictional wetlands in the review area: acres. 6. Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs. Wetlands adjacent to such waters,and have when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional wetlands in the review area: acres. 7. Impoundments of jurisdictional waters.9 As a general rule,the impoundment of a jurisdictional tributary remains jurisdictional. Demonstrate that impoundment was created from"waters of the U.S.,"or Demonstrate that water meets the criteria for one of the categories presented above(1-6),or Demonstrate that water is isolated with a nexus to commerce(see E below). E. ISOLATED[INTERSTATE OR INTRA-STATE]WATERS,INCLUDING ISOLATED WETLANDS,THE USE, DEGRADATION OR DESTRUCTION OF WHICH COULD AFFECT INTERSTATE COMMERCE,INCLUDING ANY SUCH WATERS(CHECK ALL THAT APPLY):lo which are or could be used by interstate or foreign travelers for recreational or other purposes. from which fish or shellfish are or could be taken and sold in interstate or foreign commerce. which are or could be used for industrial purposes by industries in interstate commerce. Interstate isolated waters. Explain: Nee Footnote#3. 9 To complete the analysis refer to the key in Section III.13.6 of the Instructional Guidebook. 10 Prior to asserting or declining CWA jurisdiction based solely on this category,Corps Districts will elevate the action to Corps and EPA HQ for review consistent with the process described in the Corps/EPA Memorandum Regarding CWA Act Jurisdiction Following Rapanos. Other factors. Explain: Identify water body and summarize rationale supporting determination: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: Wetlands: acres. 'Jd °I-.11'RISDICT':(l _'.L WATERS, INCLUDING AVF?'L.-NDS(CHECK ALL THATAP?1_Y?: it:x>tenr.'1i I ,within -a, tneee a slid eot meet :n the '),_ '017 , t '_n ,Netland Delineation Manual andior appropriate Regional Supplements. Review area included isolated waters with no substantial nexus to interstate(or foreign)commerce. ❑ Prior to the Jan 2001 Supreme Court decision in"SWANCC,"the review area would have been regulated based solely on the "Migratory Bird Rule"(MBR). Waters do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction. Explain: Other:(explain,if not covered above): Provide acreage estimates for non jurisdictional waters in the review area,where the sole potential basis of jurisdiction is the MBR factors(i.e.,presence of migratory birds,presence of endangered species,use of water for irrigated agriculture),using best professional judgment(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet width(ft). Lakes/ponds: acres. Other non-wetland waters: acres.List type of aquatic resource: Wetlands: acres. Provide acreage estimates for non jurisdictional waters in the review area that do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet, width(ft). Lakes/ponds: acres. Other non-wetland waters: acres. List type of aquatic resource: Wetlands: acres. SECTION IV: DATA SOURCES. A. SUPPORTING DATA. Data reviewed for JD(check all that apply-checked items shall be included in case file and,where checked and requested,appropriately reference sources below): Maps,plans,plots or plat submitted by or on behalf of the applicant/consultant: Data sheets prepared/submitted by or on behalf of the applicant/consultant. ® Office concurs with data sheets/delineation report. ❑ Office does not concur with data sheets/delineation report. Data sheets prepared by the Corps: Corps navigable waters' study: U.S.Geological Survey Hydrologic Atlas: ❑USGS NHD data. ❑ USGS 8 and 12 digit HUC maps. U.S.Geological Survey map(s).Cite scale&quad name:Skyland,North Carolina, 1991. USDA Natural Resources Conservation Service Soil Survey.Citation: National wetlands inventory map(s). Cite name: State/Local wetland inventory map(s): FEMA/FIRM maps: 100-year Floodplain Elevation is: (National Geodectic Vertical Datum of 1929) Photographs:❑Aerial(Name&Date): or® Other(Name&Date):See attached report. Previous deternunation(s). File no.and date of response letter: Applicable/supporting case law: Applicable/supporting scientific literature: Other information(please specify): B. ADDITIONAL COMMENTS TO SUPPORT JD: APPROVED.JURISDICTIONAL DETERMINATION FORM U.S.Army Corps of Engineers This form should be completed by following the instructions provided in Section W of the JD Form Instructional Guidebook SECTION I: BACKGROUND INFORMATION A. REPORT COMPLETION DATE FOR APPROVED JURISDICTIONAL DETERMINATION(JD):July 16,2007 B. DISTRICT OFFICE,FILE NAME,AND NUMBER:Asheville Regional Office C. PROJECT LOCATION AND BACKGROUND INFORMATION:The Asheville Regional Airport Expansion site is located adjacent to Highway 26,on existing Airport Authority property in Fletcher,North Carolina,Perennial Stream A,Wetland AA and BB State:NC County/parish/borough: Buncombe City:Fletcher nt�t coclydii,ar,�. !Lit.!on_ n �ieg--decimal format. _ai. 35.41-16i— 'i. ` <n,. ,N. _:nivcr ai Trans ersc 'vlercator: Name of nearest waterbody: French Broad River Name of nearest Traditional Navigable Water(TNW)into which the aquatic resource flows:French Broad River Name of watershed or Hydrologic Unit Code(HUC):06010105 Check if map/diagram of review area and/or potential jurisdictional areas is/are available upon request. Check if other sites(e.g.,offsite mitigation sites,disposal sites,etc...)are associated with this action and are recorded on a different JD form. D. REVIEW PERFORMED FOR SITE EVALUATION(CHECK ALL THAT APPLY): Office(Desk)Determination. Date:June 19,2007 Field Determination. Date(s):June 13,2007 SECTION H: SUMMARY OF FINDINGS A. RHA SECTION 10 DETERMINATION OF JURISDICTION. There! ,navigable waters of the U.S."within Rivers and Harbors Act(RHA)jurisdiction(as defined by 33 CFR part 329)in the review area.[Required] Waters subject to the ebb and flow of the tide. Waters are presently used,or have been used in the past,or may be susceptible for use to transport interstate or foreign commerce. Explain: B. CWA SECTION 404 DETERMINATION OF JURISDICTION. There is"waters of the U.S."within Clean Water Act(CWA)jurisdiction(as defined by 33 CFR part 328)in the review area.[Required] 1. Waters of the U.S. a. Indicate presence of waters of U.S.in review area(check all that apply):t TNWs,including territorial seas Wetlands adjacent to TNWs Relatively permanent waters (RPWs)that flow directly or indirectly into TNWs Non-RPWs that flow directly or indirectly into TNWs Wetlands directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to but not directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs Impoundments of jurisdictional waters Isolated(interstate or intrastate)waters,including isolated wetlands b. Identify(estimate)size of waters of the U.S.in the review area: Non-wetland waters: 17461inear feet: width(ft)and/or 0.256 acres. Wetlands:0.209 acres. c. Limits(boundaries)of jurisdiction based on: Elevation of established OHWM(if known): 2. Non-regulated waters/wetlands(check if applicable):3 19 Potentially jurisdictional waters and/or wetlands were assessed within the review area and determined to be not jurisdictional. Explain: r Boxes checked below shall be supported by completing the appropriate sections in Section III below. 2 For purposes of this form,an RPW is defined as a tributary that is not a TNW and that typically flows year-round or has continuous flow at least"seasonally" (e.g.,typically 3 months). 3 Supporting documentation is presented in Section III.F. SECTION III: CWA ANALYSIS A. TNWs AND WETLANDS ADJACENT TO TNWs The agencies will assert jurisdiction over TNWs and wetlands adjacent to TNWs. If the aquatic resource is a TNW,complete Section III.A.1 and Section III.D.1.only;if the aquatic resource is a wetland adjacent to a TNW,complete Sections III.A.1 and 2 and Section III.D.1.;otherwise,see Section III.B below. 1. TNW Identify TNW: Summarize rationale supporting determination: '_. �Verland adjacent to-F ti v �uunnar��e_�iiion uc ;uDrt iU1i _ hat IS _dLgaccnf­: B. CHARACTERISTICS OF TRIBUTARY(THAT IS NOT A TNW)AND ITS ADJACENT WETLANDS(IF ANY): This section summarizes information regarding characteristics of the tributary and its adjacent wetlands,if any,and it helps determine whether or not the standards for jurisdiction established under Rapanos have been met. The agencies will assert jurisdiction over non-navigable tributaries of TNWs where the tributaries are"relatively permanent waters"(RPWs),i.e.tributaries that typically flow year-round or have continuous flow at least seasonally(e.g.,typically 3 months).A wetland that directly abuts an RPW is also jurisdictional.If the aquatic resource is not a TNW,but has year-round (perennial)flow,skip to Section IH.D.2.If the aquatic resource is a wetland directly abutting a tributary with perennial flow, skip to Section IH.D.4. A wetland that is adjacent to but that does not directly abut an RPW requires a significant nexus evaluation.Corps districts and EPA regions will include in the record any available information that documents the existence of a significant nexus between a relatively permanent tributary that is not perennial(and its adjacent wetlands if any)and a traditional navigable water,even though a significant nexus fmding is not required as a matter of law. If the waterbody4 is not an RPW,or a wetland directly abutting an RPW,a JD will require additional data to determine if the waterbody has a significant nexus with a TNW.If the tributary has adjacent wetlands,the significant nexus evaluation must consider the tributary in combination with all of its adjacent wetlands.This significant nexus evaluation that combines,for analytical purposes,the tributary and all of its adjacent wetlands is used whether the review area identified in the JD request is the tributary,or its adjacent wetlands,or both.If the JD covers a tributary with adjacent wetlands,complete Section HLBA for the tributary,Section III.B.2 for any onsite wetlands,and Section HI.B.3 for all wetlands adjacent to that tributary,both onsite and offsite.The determination whether a significant nexus exists is determined in Section I LC below. 1. Characteristics of non-TNWs that flow directly or indirectly into TNW (i) General Area Conditions: Watershed size: 1,196,80 Drainage area:65 SM Average annual rainfall:38.1 inches Average annual snowfall: 15.6 inches (ii) Physical Characteristics: (a) Relationship with TNW: ❑Tributary flows directly into TNW. ®Tributary flows through]tributaries before entering TNW. Project waters are river miles from TNW. Project waters are river miles from RPW. Project waters are ' aerial(straight)miles from TNW. Project waters are aerial(straight)miles from RPW. Project waters cross or serve as state boundaries.Explain:N/A. Identify flow route to TNW5:Perennial Stream A and is met by Unimportant Intermittent Stream B,then flows through project area to French Broad River. "Note that the Instructional Guidebook contains additional information regarding swales,ditches,washes,and erosional features generally and in the and West. 5 Flow route can be described by identifying,e.g.,tributary a,which flows through the review area,to flow into tributary b,which then flows into TNW. Tributary stream order,if known: 1. (b) General Tributary Characteristics(check all that apply): Tributary is: ® Natural ❑ Artificial(man-made). Explain: ❑ Manipulated (man-altered). Explain: Tributary properties with respect to top of bank(estimate): Average width:4-5 feet Average depth: 3-4 feet Average side slopes: Primary tributary substrate composition(check all that apply): n Silts ❑ Sands ❑ Concrete �.�>i)>Ic;S J 'ardYcl J ,`iluClt i ❑ Bedrock ❑ Vegetation. Type,,0o ewer: ❑ Other.Explain: Tributary condition/stability[e.g.,highly eroding,sloughing banks]. Explain:moderate erosion and an incised channel. Presence of run/riffle/ ool com lexes. Explain:moderate riffle/pool complexes. Tributary geometry: Tributary gradient(approximate average slope):2-4% (c) Flow: Tributary provides for:MENEM Estimate average number of flow events in review area/year: Describe flow regime: Other information on duration and volume: Surface flow is: . Characteristics: Subsurface flow:07 . Explain findings:Groundwater present in channel,no rain within last 48 hours. ❑ Dye(or other)test performed: Tributary has(check all that apply): ® Bed and banks ® OHWM6(check all indicators that apply): ❑ clear,natural line impressed on the bank ❑ the presence of litter and debris ❑ changes in the character of soil ❑ destruction of terrestrial vegetation ❑ shelving ❑ the presence of wrack line ® vegetation matted down,bent,or absent ❑ sediment sorting ® leaf litter disturbed or washed away ® scour ® sediment deposition ❑ multiple observed or predicted flow events ❑ water staining ❑ abrupt change in plant community ❑ other(list): ❑ Discontinuous OHWM Explain: If factors other than the OHWM were used to determine lateral extent of CWA jurisdiction(check all that apply): High Tide Line indicated by: in Mean High Water Mark indicated by: ❑ oil or scum line along shore objects ❑ survey to available datum; ❑ fine shell or debris deposits(foreshore) ❑ physical markings; ❑ physical markings/characteristics ❑ vegetation lines/changes in vegetation types. ❑ tidal gauges ❑ other(list): (iii) Chemical Characteristics: Characterize tributary(e.g.,water color is clear,discolored,oily film;water quality;general watershed characteristics,etc.). Explain:clear water. Identify specific pollutants;if known: 6A natural or man-made discontinuity in the OHWM does not necessarily sever jurisdiction(e.g.,where the stream temporarily flows underground,or where the OHWM has been removed by development or agricultural practices). Where there is a break in the OHWM that is unrelated to the waterbody's flow regime(e.g.,flow over a rock outcrop or through a culvert),the agencies will look for indicators of flow above and below the break. 'Ibid. (iv) Biological Characteristics. Channel supports(check all that apply): ® Riparian corridor. Characteristics(type,average width): ❑ Wetland fringe. Characteristics: ❑ Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑Aquatic/wildlife diversity. Explain findings: 2. Characteristics of wetlands adjacent to non-TNW that flow directly or indirectly into TNW (i) Physical Characteristics: (a) General Wetland Characteristics: Prouerties: -ved 'N_[land 6.0 <acres a1w'dv c ;u.i BB J.009acrv's Wetland type. c:cpiain:WVetland AA-herbaceous, 'vVetiand BB-forested. Wetland quality. Explainmatural wetlands,cleared forest area upstream. Project wetlands cross or serve as state boundaries.Explain: (b) General Flow Relationship with Non-TNW: Flow is:111MAMM.Explain:Wetland AA and BB directly abut Stream A. Surface flow is:'low Characteristics: Subsurface flow:M, . Explain findings:Stream A is perennial with groundwater present in channel,ground saturated to 12". ❑Dye(or other)test performed: (c) Wetland Adjacency Determination with Non-TNW: ® Directly abutting ❑Not directly abutting ❑ Discrete wetland hydrologic connection. Explain: ❑ Ecological connection. Explain: ❑ Separated by berm/barrier. Explain: (d) Proximity(Relationship)to TNW Project wetlanjare , "``"' ''"` river miles from TNW. Project waters < aerial(straight)miles from TNW. Flow is from: Estimate approximate location of wetland as within the JVJJ�floodplain. (ii) Chemical Characteristics: Characterize wetland system(e.g.,water color is clear,brown,oil film on surface;water quality;general watershed characteristics;etc.). Explain:Wetland AA is located in the central portion of the property,adjacent to Stream A and is approximately 0.028 acre in size(Figure 1,enclosed). Dominant vegetation within this area includes silky dogwood (Corpus amomum),Christmas fern(Polystichum acrostichoides),cinnamon fern(Osmunda cinnamomea),common rush (Juncus effuses),and jewelweed(Impatiens capensis). This area exhibited low chroma soils(2.5Y 4/1),few prominent mottles(5YR 4/6),drainage patterns,and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland AA is enclosed(DP2). Wetland BB is located is located downstream of Perennial Stream A and Unimportant Intermittent Stream B(Figure 1, enclosed). This forested linear wetland is approximately 0.009 acre is size. Dominant vegetation within this area includes red maple(Acer rubrum),ironwood(Carpinus caroliniana),hazel alder(Alnus serrulata),common rush(Juncus effuses),and various sedges(Carex spp.). This area exhibited low chroma soils(2.5Y 4/1),few distinct mottles(5YR 4/6),drainage patterns,and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland BB is enclosed(DP3).A Photograph of Wetland BB is enclosed as Photographs E. Identify specific pollutants,if known: (iii)Biological Characteristics. Wetland supports(check all that apply): ❑ Riparian buffer. Characteristics(type,average width): ® Vegetation type/percent cover. Explain:All plant species are FAC or wetter. ❑ Habitat for: ❑Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑Aquatic/wildlife diversity. Explain findings: 3. Characteristics of all wetlands adjacent to the tributary(if any) All wetland(s)being considered in the cumulative analysis: Approximately(0.037)acres in total are being considered in the cumulative analysis. For each wetland,specify the following: Directly abuts?(Y/N) Size(in acres) Directly abuts?(Y/N) Size(in acres) Wetland AA Y 0.028 Wetland BB 0.009 Summarize overall biological,chemical and physical functions being performed:Wetland AA is located in the central portion of the property,adjacent to Stream A and is approximately 0.028 acre in size(Figure 1,enclosed). Dominant vegetation within this area includes silky dogwood(Cornus amomum),Christmas fern(Polystichum acrostichoides),cinnamon fern(Osmunda cinnamomea),common rush(Juncus effuses),and jewelweed(Impatiens capensis). This area exhibited low chroma soils(2.5Y 1). re,,v prominent mottle 5`?R-1'<�)_ rainage pattcrns_and saturation .within the joper 12 inches of the soil»roflle. A Routine n-pit c,�nninuiiun �o,.n curs, [u«[i sc )i _::closed I DP2, Wetland BB is located is located downstream of Perennial Stream A and Unimportant Intermittent Stream B(Figure 1,enclosed). This forested linear wetland is approximately 0.009 acre is size. Dominant vegetation within this area includes red maple(Acer rubrum),ironwood(Carpinus caroliniana),hazel alder(Alnus serrulata),common rush(Juncus effuses),and various sedges(Carex spp.). This area exhibited low chroma soils(2.5Y 4/1),few distinct mottles(5YR 4/6),drainage patterns,and,satiation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland BB is enclosed(DP3).A Photograph of Wetland BB is enclosed as Photographs E.. C. SIGNIFICANT NEXUS DETERMINATION A significant nexus analysis will assess the flow characteristics and functions of the tributary itself and the functions performed by any wetlands adjacent to the tributary to determine if they significantly affect the chemical,physical,and biological integrity of a TNW. For each of the following situations,a significant nexus exists if the tributary,in combination with all of its adjacent wetlands,has more than a speculative or insubstantial effect on the chemical,physical and/or biological integrity of a TNW. Considerations when evaluating significant nexus include,but are not limited to the volume,duration,and frequency of the flow of water in the tributary and its proximity to a TNW,and the functions performed by the tributary and all its adjacent wetlands. It is not appropriate to determine significant nexus based solely on any specific threshold of distance(e.g.between a tributary and its adjacent wetland or between a tributary and the TNW).Similarly,the fact an adjacent wetland lies within or outside of a floodplain is not solely determinative of significant nexus. Draw connections between the features documented and the effects on the TNW,as identified in the Rapanos Guidance and discussed in the Instructional Guidebook.Factors to consider include,for example: • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to carry pollutants or flood waters to TNWs,or to reduce the amount of pollutants or flood waters reaching a TNW? • Does the tributary,in combination with its adjacent wetlands(if any),provide habitat and lifecycle support functions for fish and other species,such as feeding,nesting,spawning,or rearing young for species that are present in the TNW? • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to transfer nutrients and organic carbon that support downstream foodwebs? • Does the tributary,in combination with its adjacent wetlands(if any),have other relationships to the physical,chemical,or biological integrity of the TNW? Note:the above list of considerations is not inclusive and other functions observed or known to occur should be documented below: 1. Significant nexus findings for non-RPW that has no adjacent wetlands and flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary itself,then go to Section III.D: 2. Significant nexus findings for non-RPW and its adjacent wetlands,where the non-RPW flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section IILD: 3. Significant nexus findings for wetlands adjacent to an RPW but that do not directly abut the RPW.Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: D. DETERMINATIONS OF JURISDICTIONAL FINDINGS.THE SUBJECT WATERS/WETLANDS ARE(CHECK ALL THAT APPLY): 1. TNWs and Adjacent Wetlands. Check all that apply and provide size estimates in review area: TNWs: linear feet width(ft),Or, acres. Wetlands adjacent to TNWs: acres. 2. RPWs that flow directly or indirectly into TNWs. IN Tributaries of TNWs where tributaries typically flow year-round are jurisdictional.Provide data and rationale indicating that tributary is perennial:Stream A flows through the middle portion of the property and is approximately 1,540 linear feet in length(Figure 1,enclosed). This channel exhibited average ordinary high water widths of 4-5 feet,perennial flow,moderate sinuosity,and substrate consisting of fine sand to small cobbles. Biological sampling of Stream A resulted in a weak presence of crayfish and amphibians,and a weak presence of benthic macroinvertebrates. USACE Stream Quality Assessment scores for Perennial Stream A ranged from 49 to 53 out of a possible 100 points and ranged from 33.5 to 36.5 out of 71 possible points on the NCDWQ Stream Classification Form,indicating perennial status(SCP1 through SCP3,enclosed). Photographs of Perennial Stream A are enclosed as Photographs A and B. � TCibll t�l C.C.F .^,t T\1�,V ':vhe.t;R7bUIarleS 1i1:_ �011tl ll!tol1S 9UVt UCI_,CI(C1I01IIIL DUUi iLH-^oliill -hiS�UIIL I;US ot1 IS XOC iL1c4�1L 11.3. iUC `CiC1U,ILI ic: 'i_Clll. ui 411 C-.r O u, v. .. seasomilly: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters: 1221 linear feet4-5width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 3. Non-RPWs8 that flow directly or indirectly into TNWs. Waterbody that is not a TNW or an RPW,but flows directly or indirectly into a TNW,and it has a significant nexus with a TNW is jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional waters within the review area(check all that apply): Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 4. Wetlands directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands directly abut RPW and thus are jurisdictional as adjacent wetlands. Wetlands directly abutting an RPW where tributaries typically flow year-round. Provide data and rationale indicating that tributary is perennial in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW:Wetland AA is located in the central portion of the property,adjacent to Stream A and is approximately 0.028 acre in size(Figure 1,enclosed). Dominant vegetation within this area includes silky dogwood(Cornus amomum),Christmas fern(Polystichum acrostichoides),cinnamon fern(Osmunda cinnamomea),common rush(Juncus effuses),and jewelweed(Impatiens capensis). This area exhibited low chroma soils(2.5Y 4/1),few prominent mottles(5YR 4/6),drainage patterns,and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland AA is enclosed(DP2). Wetland BB is located is located downstream of Perennial Stream A and Unimportant Intermittent Stream B (Figure 1,enclosed). This forested linear wetland is approximately 0.009 acre is size. Dominant vegetation within this area includes red maple(Acer rubrum),ironwood(Carpinus caroliniana),hazel alder(Alnus serrulata), common rush(Juncus effuses),and various sedges(Carex spp.). This area exhibited low chroma soils(2.5Y 4/1), few distinct mottles(5YR 4/6),drainage patterns,and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland BB is enclosed(DP3).A Photograph of Wetland BB is enclosed as Photographs E. Wetlands directly abutting an RPW where tributaries typically flow"seasonally." Provide data indicating that tributary is seasonal in Section III.B and rationale in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Provide acreage estimates for jurisdictional wetlands in the review area:0.037acres. 5. Wetlands adjacent to but not directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands that do not directly abut an RPW,but when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisidictional.Data supporting this conclusion is provided at Section III.C. 8See Footnote#3. Provide acreage estimates for jurisdictional wetlands in the review area: acres. 6. Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs. Wetlands adjacent to such waters,and have when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional wetlands in the review area: acres. 7. Impoundments of jurisdictional waters. As a general rule,the impoundment of a jurisdictional tributary remains jurisdictional. El Demonstrate that troni"vaters of the L'-S.."=)r d ie P,lOn�n'Litd Ghat 'Vate uli.;:`.� .lic'.,mer iii. The atcgor,.s DrtSCIItcd aou�e ❑, Demonstrate that water is isolated with a nexus to commerce(see below). E. ISOLATED [INTERSTATE OR INTRA-STATE]WATERS,INCLUDING ISOLATED WETLANDS,THE USE, DEGRADATION OR DESTRUCTION OF WHICH COULD AFFECT INTERSTATE COMMERCE,INCLUDING ANY SUCH WATERS(CHECK ALL THAT APPLY):" which are or could be used by interstate or foreign travelers for recreational or other purposes. from which fish or shellfish are or could be taken and sold in interstate or foreign commerce. which are or could be used for industrial purposes by industries in interstate commerce. Interstate isolated waters. Explain: Other factors. Explain: Identify water body and summarize rationale supporting determination: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: Wetlands: acres. F. NON-JURISDICTIONAL WATERS,INCLUDING WETLANDS(CHECK ALL THAT APPLY): If potential wetlands were assessed within the review area,these areas did not meet the criteria in the 1987 Corps of Engineers Wetland Delineation Manual and/or appropriate Regional Supplements. Review area included isolated waters with no substantial nexus to interstate(or foreign)commerce. ❑ Prior to the Jan 2001 Supreme Court decision in"SWANCC,"the review area would have been regulated based solely on the "Migratory Bird Rule"(MBR). Waters do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction. Explain: Other:(explain,if not covered above): Provide acreage estimates for non jurisdictional waters in the review area,where the sole potential basis of jurisdiction is the MBR factors(i.e.,presence of migratory birds,presence of endangered species,use of water for irrigated agriculture),using best professional judgment(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet width(ft). Lakes/ponds: acres. Other non-wetland waters: acres.List type of aquatic resource: Wetlands: acres. Provide acreage estimates for non jurisdictional waters in the review area that do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet, width(ft). Lakes/ponds: acres. Other non-wetland waters: acres. List type of aquatic resource: Wetlands: acres. 9 To complete the analysis refer to the key in Section III.D.6 of the Instructional Guidebook to Prior to asserting or declining CWA jurisdiction based solely on this category,Corps Districts will elevate the action to Corps and EPA HQ for review consistent with the process described in the Corps/EPA Memorandum Regarding CWA Act Jurisdiction Following Rapanos. SECTION IV: DATA SOURCES. A. SUPPORTING DATA. Data reviewed for JD(check all that apply-checked items shall be included in case file and,where checked and requested,appropriately reference sources below): Maps,plans,plots or plat submitted by or on behalf of the applicant/consultant: Data sheets prepared/submitted by or on behalf of the applicant/consultant. ® Office concurs with data sheets/delineation report. ❑ Office does not concur with data sheets/delineation report. Data sheets prepared by the Corps: Corps navigable waters' study: ( U.S. Geological Survey Hydrologic Atlas: USGS uHD Plata. U.S. Geoiogicai survey mapls). Cite scale-quad❑anle:Skyland, North Carolina, 199 t. USDA Natural Resources Conservation Service Soil Survey.Citation: National wetlands inventory map(s). Cite name: State/Local wetland inventory map(s): FEMA/FIRM maps: 100-year Floodplain Elevation is: (National Geodectic Vertical Datum of 1929) Photographs:❑ Aerial(Name&Date): or® Other(Name&Date):See attached report. Previous determination(s). File no.and date of response letter: Applicable/supporting case law: Applicable/supporting scientific literature: Other information(please specify): B. ADDITIONAL COMMENTS TO SUPPORT JD: APPROVED JURISDICTIONAL DETERMINATION FORM U.S.Army Corps of Engineers This form should be completed by following the instructions provided in Section IV of the JD Form Instructional Guidebook. SECTION I: BACKGROUND INFORMATION A. REPORT COMPLETION DATE FOR APPROVED JURISDICTIONAL DETERMINATION(JD):July 16,2007 B. DISTRICT OFFICE,FILE NAME,AND NUMBER:Asheville Regional Office C. PROJECT LOCATION AND BACKGROUND INFORMATION:The Asheville Regional Airport Expansion site is located adjacent to Highway 26,on existing Airport Authority property in Fletcher,North Carolina,Perennial Stream A-Lower Reach S late:NC County!parish/borough: Buncombe City: Fletcher nC .I,UL din.iLC�_)I Ils«IUn`,iiI Je,IFt, jeCRnai ,br(,11C): LJt. __.-=i.I_' JIL. Name of nearest waterbody: French Broad River Name of nearest Traditional Navigable Water(TNW)into which the aquatic resource flows:French Broad River Name of watershed or Hydrologic Unit Code(HUC): 06010105 Check if map/diagram of review area and/or potential jurisdictional areas is/are available upon request. Check if other sites(e.g.,offsite mitigation sites,disposal sites,etc...)are associated with this action and are recorded on a different JD form. D. REVIEW PERFORMED FOR SITE EVALUATION(CHECK ALL THAT APPLY): Office(Desk)Determination. Date: June 19,2007 Field Determination. Date(s):June 13,2007 SECTION II: SUMMARY OF FINDINGS A. RHA SECTION 10 DETERMINATION OF JURISDICTION. There' "navigable waters of the U.S."within Rivers and Harbors Act(RHA)jurisdiction(as defined by 33 CFR part 329)in the review area.[Required] Waters subject to the ebb and flow of the tide. Waters are presently used,or have been used in the past,or may be susceptible for use to transport interstate or foreign commerce. Explain: B. CWA SECTION 404 DETERMINATION OF JURISDICTION. There>" ,waters of the U.S."within Clean Water Act(CWA)jurisdiction(as defined by 33 CFR part 328)in the review area [Required] 1. Waters of the U.S. a. Indicate presence of waters of U.S.in review area(check all that apply):t TNWs,including territorial seas Wetlands adjacent to TNWs Relatively permanent waters2(RPWs)that flow directly or indirectly into TNWs Non-RPWs that flow directly or indirectly into TNWs Wetlands directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to but not directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs Impoundments of jurisdictional waters Isolated(interstate or intrastate)waters,including isolated wetlands b. Identify(estimate)size of waters of the U.S.in the review area: Non-wetland waters: 17461inear feet: width(ft)and/or 0.256 acres. Wetlands:0.209 acres. c.Limits(boundaries)of jurisdiction based on Elevation of established OHWM(if known): 2. Non-regulated waters/wetlands(check if applicable):3 Potentially jurisdictional waters and/or wetlands were assessed within the review area and determined to be not jurisdictional. Explain: Boxes checked below shall be supported by completing the appropriate sections in Section III below. Z For purposes of this form,an RPW is defined as a tributary that is not a TNW and that typically flows year-round or has continuous flow at least"seasonally" (e.g.,typically 3 months). 3 Supporting documentation is presented in Section III.F. SECTION III: CWA ANALYSIS A. TNWs AND WETLANDS ADJACENT TO TNWs The agencies will assert jurisdiction over TNWs and wetlands adjacent to TNWs. If the aquatic resource is a TNW,complete Section III.A.1 and Section HI.D.1.only;if the aquatic resource is a wetland adjacent to a TNW,complete Sections I LA.1 and 2 and Section III.D.1.;otherwise,see Section III.B below. 1. TNW Identify TNW: Summarize rationale supporting determination: Z. Wetland adjacent to TN* N' JLlRlI UI,-C LElllOil lt�,ilt oti(�LZi._.�U?.,:U;liii _i1..ii W,.LittU i> ill)cLGCiC B. CHARACTERISTICS OF TRIBUTARY(THAT IS NOT A TNW)AND ITS ADJACENT WETLANDS(IF ANY): This section summarizes information regarding characteristics of the tributary and its adjacent wetlands,if any,and it helps determine whether or not the standards for jurisdiction established under Rapanos have been met. The agencies will assert jurisdiction over non-navigable tributaries of TNWs where the tributaries are"relatively permanent waters"(RPWs),i.e.tributaries that typically flow year-round or have continuous flow at least seasonally(e.g.,typically 3 months).A wetland that directly abuts an RPW is also jurisdictional.If the aquatic resource is not a TNW,but has year-round (perennial)flow,skip to Section IH.D.2.If the aquatic resource is a wetland directly abutting a tributary with perennial flow, skip to Section III.D.4. A wetland that is adjacent to but that does not directly abut an RPW requires a significant nexus evaluation.Corps districts and EPA regions will include in the record any available information that documents the existence of a significant nexus between a relatively permanent tributary that is not perennial(and its adjacent wetlands if any)and a traditional navigable water,even though a significant nexus finding is not required as a matter of law. If the waterbody°is not an RPW,or a wetland directly abutting an RPW,a JD will require additional data to determine if the waterbody has a significant nexus with a TNW.If the tributary has adjacent wetlands,the significant nexus evaluation must consider the tributary in combination with all of its adjacent wetlands.This significant nexus evaluation that combines,for analytical purposes,the tributary and all of its adjacent wetlands is used whether the review area identified in the JD request is the tributary,or its adjacent wetlands,or both.If the JD covers a tributary with adjacent wetlands,complete Section III.B.1 for the tributary,Section III.B.2 for any onsite wetlands,and Section III.B.3 for all wetlands adjacent to that tributary,both onsite and offsite.The determination whether a significant nexus exists is determined in Section HLC below. 1. Characteristics of non-TNWs that flow directly or indirectly into TNW (i) General Area Conditions: Watershed size: 1,196,80 Drainage area: 1.68' Average annual rainfall:38.1 inches Average annual snowfall: 15.6 inches (ii) Physical Characteristics: (a) Relationship with TNW: ❑ Tributary flows directly into TNW. ® Tributary flows through tributaries before entering TNW. Project waters are s river miles from TNW. Project waters are river miles from RPW. Project waters are aerial(straight)miles from TNW. Project waters are aerial(straight)miles from RPW. Project waters cross or serve as state boundaries.Explain:N/A. Identify flow route to TNW5:Perennial Stream A and is met by Unimportant Intermittent Stream B,then flows through project area to French Broad River. Note that the Instructional Guidebook contains additional information regarding swales,ditches,washes,and erosional features generally and in the and West. 5 Flow route can be described by identifying,e.g.,tributary a,which flows through the review area,to flow into tributary b,which then flows into TNW. Tributary stream order,if known:2. (b) General Tributary Characteristics(check all that apply): Tributary is: ®Natural ❑ Artificial(man-made). Explain: ❑ Manipulated (man-altered). Explain: Tributary properties with respect to top of bank(estimate): Average width:4-5 feet Average depth: 3-4 feet Average side slopes O. Primary tributary substrate composition(check all that apply): ❑ Silts Sands ❑ Concrete ura%c'l :�IUCk Bedrock i egetation. Type; ,cover: ❑ Other. Explain: Tributary condition/stability[e.g.,highly eroding,sloughing banks]. Explain:moderate erosion and an incised channel. Presence of run/riffle/ 001 com lexes. Explain:moderate riffle/pool complexes. Tributary geometry: RJ Tributary gradient(approximate average slope):2-4% (c) Flow: Tributary provides for: Estimate average number of flow events in review area/year- Describe flow regime: Other information on duration and volume: Surface flow is: . Characteristics: Subsurface flow:JM. Explain findings:Groundwater present in channel,no rain within last 48 hours. ❑ Dye(or other)test performed: Tributary has(check all that apply): ® Bed and banks ® OHWM6(check all indicators that apply): ❑ clear,natural line impressed on the bank ❑ the presence of litter and debris ❑ changes in the character of soil ❑ destruction of terrestrial vegetation ❑ shelving ❑ the presence of wrack line ® vegetation matted down,bent,or absent ❑ sediment sorting ® leaf litter disturbed or washed away ® scour ® sediment deposition ❑ multiple observed or predicted flow events ❑ water staining ❑ abrupt change in plant community ❑ other(list): ❑ Discontinuous OHWM.7 Explain: If factors other than the OHWM were used to determine lateral extent of CWA jurisdiction(check all that apply): High Tide Line indicated by: in Mean High Water Mark indicated by: ❑ oil or scum line along shore objects ❑ survey to available datum; ❑ fine shell or debris deposits(foreshore) ❑physical markings; ❑ physical markings/characteristics ❑ vegetation lines/changes in vegetation types. ❑ tidal gauges ❑ other(list): (iii) Chemical Characteristics: Characterize tributary(e.g.,water color is clear,discolored,oily film;water quality;general watershed characteristics,etc.). Explain: clear water. Identify specific pollutants,if known: 6A natural or man-made discontinuity in the OHWM does not necessarily sever jurisdiction(e.g.,where the stream temporarily flows underground,or where the OHWM has been removed by development or agricultural practices). Where there is a break in the OHWM that is unrelated to the waterbody's flow regime(e.g.,flow over a rock outcrop or through a culvert),the agencies will look for indicators of flow above and below the break. 'Ibid. (iv) Biological Characteristics. Channel supports(check all that apply): ® Riparian corridor. Characteristics(type,average width): ❑ Wetland fringe. Characteristics: ® Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ® Aquatic/wildlife diversity. Explain findings:weak presence of crayfish and amphibians,and a weak presence of benthic macroinvertebrates. 2. Characteristics of wetlands adjacent to non-TNW that flow directly or indirectly into TNW (i) Physical Characteristics: I) General\tietland Characteristics: properties: Wedancl size: acres Wetland type. Explain: Wetland quality. Explain: Project wetlands cross or serve as state boundaries.Explain: (b) General Flow Relationship with Non-TNW: Flow is:j% .Explain: Surface flow is: Characteristics: Subsurface flow:-' aiM. Explain findings: ❑ Dye(or other)test performed: (c) Wetland Adiacency Determination with Non-TNW: ❑Directly abutting ❑Not directly abutting ❑ Discrete wetland hydrologic connection. Explain: ❑ Ecological connection. Explain: ❑ Separated by berm/barrier. Explain: (d) Proximity(Relationship)to TNW Project wetlands are � ' 'i,lli river miles from TNW. Project waters are aerial(straight)miles from TNW. Flow is from:'='. Estimate approximate location of wetland as within the,11M floodplain. (ii) Chemical Characteristics: Characterize wetland system(e.g.,water color is clear,brown,oil film on surface;water quality;general watershed characteristics;etc.). Explain: Identify specific pollutants,if known: (iii)Biological Characteristics. Wetland supports(check all that apply): ❑ Riparian buffer. Characteristics(type,average width): ❑ Vegetation type/percent cover. Explain: ❑ Habitat for: ❑Federally Listed species. Explain findings: ❑Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑Aquatic/wildlife diversity. Explain findings: 3. Characteristics of all wetlands adjacent to the tributary(if an All wetland(s)being considered in the cumulative analysis: Approximately( )acres in total are being considered in the cumulative analysis. For each wetland,specify the following: Directly abuts?(Y/N) Size(in acres) Directly abuts?(Y/N) Size(in acres) Summarize overall biological,chemical and physical functions being performed: C. SIGNIFICANT NEXUS DETERMINATION "nif'canr ne pus 3iiaivsis %oil assess ale ;low marac2enstics and functions of zhe tribmarV itself and :he functions performed by anv wetlands adjacent to the tributary to determine if they significantly affect the chemical,physical,and biological integrity of a TNW. For each of the following situations,a significant nexus exists if the tributary,in combination with all of its adjacent wetlands,has more than a speculative or insubstantial effect on the chemical,physical and/or biological integrity of a TNW. Considerations when evaluating significant nexus include,but are not limited to the volume,duration,and frequency of the flow of water in the tributary and its proximity to a TNW,and the functions performed by the tributary and all its adjacent wetlands. It is not appropriate to determine significant nexus based solely on any specific threshold of distance(e.g.between a tributary and its adjacent wetland or between a tributary and the TNW).Similarly,the fact an adjacent wetland lies within or outside of a floodplain is not solely determinative of significant nexus. Draw connections between the features documented and the effects on the TNW,as identified in the Rapanos Guidance and discussed in the Instructional Guidebook.Factors to consider include,for example: • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to carry pollutants or flood waters to TNWs,or to reduce the amount of pollutants or flood waters reaching a TNW? • Does the tributary,in combination with its adjacent wetlands(if any),provide habitat and lifecycle support functions for fish and other species,such as feeding,nesting,spawning,or rearing young for species that are present in the TNW? • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to transfer nutrients and organic carbon that support downstream foodwebs? • Does the tributary,in combination with its adjacent wetlands(if any),have other relationships to the physical,chemical,or biological integrity of the TNW? Note:the above list of considerations is not inclusive and other functions observed or known to occur should be documented below: 1. Significant nexus findings for non-RPW that has no adjacent wetlands and flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary itself,then go to Section III.D: 2. Significant nexus findings for non-RPW and its adjacent wetlands,where the non-RPW flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: 3. Significant nexus findings for wetlands adjacent to an RPW but that do not directly abut the RPW.Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: D. DETERMINATIONS OF JURISDICTIONAL FINDINGS.THE SUBJECT WATERS/WETLANDS ARE(CHECK ALL THAT APPLY): 1. TNWs and Adjacent Wetlands. Check all that apply and provide size estimates in review area: TNWs: linear feet width(ft),Or, acres. Wetlands adjacent to TNWs: acres. 2. RPWs that flow directly or indirectly into TNWs. Tributaries of TNWs where tributaries typically flow year-round are jurisdictional.Provide data and rationale indicating that tributary is perennial:Stream A flows through the middle portion of the property and is approximately 1,540 linear feet in length(Figure 1,enclosed). This channel exhibited average ordinary high water widths of 4-5 feet,perennial flow,moderate sinuosity,and substrate consisting of fine sand to small cobbles. Biological sampling of Stream A resulted in a weak presence of crayfish and amphibians,and a weak presence of benthic macroinvertebrates. USACE Stream Quality Assessment scores for Perennial Stream A ranged from 49 to 53 out of a possible 100 points and ranged from 33.5 to 36.5 out of 71 possible points on the NCDWQ Stream Classification Form,indicating perennial status(SCP1 through SCP3,enclosed). Photographs of Perennial Stream A are enclosed as Photographs A and B. Tributaries of TNW where tributaries have continuous flow"seasonally"(e.g.,typically three months each year)are jurisdictional. Data supporting this conclusion is provided at Section III.B. Provide rationale indicating that tributary flows seasonally: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters: 190 linear feet4-5width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 3. Non-RPWs8 that flow directly or indirectly into TNWs. Waterbody that is not a TNW or an RPW,but flows directly or indirectly into a TNW,and it has a significant nexus with a T\!Vu un,di��d:;nt(. DatL:-.uorortin._thc at 111.C. Provide estiniaws for jurisdictional waters within the review area(check all that apply): Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 4. Wetlands directly abutting an RPW that flow directly or indirectly into TNWs. 10 Wetlands directly abut RPW and thus are jurisdictional as adjacent wetlands. Wetlands directly abutting an RPW where tributaries typically flow year-round. Provide data and rationale indicating that tributary is perennial in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Wetlands directly abutting an RPW where tributaries typically flow"seasonally." Provide data indicating that tributary is seasonal in Section III.B and rationale in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Provide acreage estimates for jurisdictional wetlands in the review area: acres. 5. Wetlands adjacent to but not directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands that do not directly abut an RPW,but when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisidictional.Data supporting this conclusion is provided at Section III.C. Provide acreage estimates for jurisdictional wetlands in the review area: acres. 6. Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs. Wetlands adjacent to such waters,and have when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional wetlands in the review area: acres. 7. Impoundments of jurisdictional waters.9 As a general rule,the impoundment of a jurisdictional tributary remains jurisdictional. Demonstrate that impoundment was created from"waters of the U.S.,"or Demonstrate that water meets the criteria for one of the categories presented above(1-6),or Demonstrate that water is isolated with a nexus to commerce(see E below). E. ISOLATED [INTERSTATE OR INTRA-STATE]WATERS,INCLUDING ISOLATED WETLANDS,THE USE, DEGRADATION OR DESTRUCTION OF WHICH COULD AFFECT INTERSTATE COMMERCE,INCLUDING ANY SUCH WATERS(CHECK ALL THAT APPLY):10 JW which are or could be used by interstate or foreign travelers for recreational or other purposes. BSee Footnote It 3. 9 To complete the analysis refer to the key in Section III.D.6 of the Instructional.Guidebook. 10 Prior to asserting or declining CWA jurisdiction based solely on this category,Corps Districts will elevate the action to Corps and EPA HQ for review consistent with the process described in the Corps/EPA Memorandum Regarding CWA Act Jurisdiction Following Rapanos from which fish or shellfish are or could be taken and sold in interstate or foreign commerce. which are or could be used for industrial purposes by industries in interstate commerce. Interstate isolated waters. Explain: Other factors. Explain: Identify water body and summarize rationale supporting determination: Provide estimates for jurisdictional waters in the review area(check all that apply): El Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 1 Merlands .F. NON-JURISDICTIONAL WATERS,INCLUDING WETLANDS(CHECK ALL THAT APPLY): If potential wetlands were assessed within the review area,these areas did not meet the criteria in the 1987 Corps of Engineers Wetland Delineation Manual and/or appropriate Regional Supplements. Review area included isolated waters with no substantial nexus to interstate(or foreign)commerce. ❑ Prior to the Jan 2001 Supreme Court decision in"SWANCC,"the review area would have been regulated based solely on the "Migratory Bird Rule"(MBR). Waters do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction. Explain: Other:(explain,if not covered above): Provide acreage estimates for non jurisdictional waters in the review area,where the sole potential basis of jurisdiction is the MBR factors(i.e.,presence of migratory birds,presence of endangered species,use of water for irrigated agriculture),using best professional judgment(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet width(ft). Lakes/ponds: acres. Other non-wetland waters: acres.List type of aquatic resource: Wetlands: acres. Provide acreage estimates for non jurisdictional waters in the review area that do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet, width(ft). Lakes/ponds: acres. Other non-wetland waters: acres. List type of aquatic resource: Wetlands: acres. SECTION IV: DATA SOURCES. A. SUPPORTING DATA. Data reviewed for JD(check all that apply-checked items shall be included in case file and,where checked and requested,appropriately reference sources below): Maps,plans,plots or plat submitted by or on behalf of the applicant/consultant: Data sheets prepared/submitted by or on behalf of the applicant/consultant. ® Office concurs with data sheets/delineation report. ❑ Office does not concur with data sheets/delineation report. Data sheets prepared by the Corps: Corps navigable waters' study: U.S.Geological Survey Hydrologic Atlas: ❑ USGS NHD data. ❑ USGS 8 and 12 digit HUC maps. U.S.Geological Survey map(s). Cite scale&quad name:Skyland,North Carolina, 1991. USDA Natural Resources Conservation Service Soil Survey.Citation: National wetlands inventory map(s). Cite name: State/Local wetland inventory map(s): FEMA/FIRM maps: 100-year Floodplain Elevation is: (National Geodectic Vertical Datum of 1929) Photographs:❑Aerial(Name&'Date): or® Other(Name&Date):See attached report. Previous determination(s). File no.and date of response letter: Applicable/supporting case law: Applicable/supporting scientific literature: Other information(please specify): APPROVED JURISDICTIONAL DETERMINATION FORM U.S.Army Corps of Engineers This form should be completed by following the instructions provided in Section IV of the JD Form Instructional Guidebook. SECTION I: BACKGROUND INFORMATION A. REPORT COMPLETION DATE FOR APPROVED JURISDICTIONAL DETERMINATION(JD):July 16,2007 B. DISTRICT OFFICE,FILE NAME,AND NUMBER:Asheville Regional Office C. PROJECT LOCATION AND BACKGROUND INFORMATION:The Asheville Regional Airport Expansion site is located adjacent to Highway 26,on existing Airport Authority property in Fletcher,North Carolina,Unimportant Intermittent Stream B State:NC County/parish/borough: Buncombe City: Fletcher _a6. name of nearest waterbody: French Broad River Name of nearest Traditional Navigable Water(TNW)into which the aquatic resource flows:French Broad River Name of watershed or Hydrologic Unit Code(HUC):06010105 Check if map/diagram of review area and/or potential jurisdictional areas is/are available upon request. Check if other sites(e.g.,offsite mitigation sites,disposal sites,etc...)are associated with this action and are recorded on a different JD form. D. REVIEW PERFORMED FOR SITE EVALUATION(CHECK ALL THAT APPLY): Office(Desk)Determination. Date:June 19,2007 Field Determination. Date(s):June 13,2007 SECTION II: SUMMARY OF FINDINGS A. RHA SECTION 10 DETERMINATION OF JURISDICTION. There im "navigable waters of the U.S."within Rivers and Harbors Act(RHA)jurisdiction(as defined by 33 CFR part 329)in the review area. [Required] Waters subject to the ebb and flow of the tide. Waters are presently used,or have been used in the past,or may be susceptible for use to transport interstate or foreign commerce. Explain: B. CWA SECTION 404 DETERMINATION OF JURISDICTION. There 16,waters of the U.S."within Clean Water Act(CWA)jurisdiction(as defined by 33 CFR part 328)in the review area.[Required] 1. Waters of the U.S. a. Indicate presence of waters of U.S.in review area(check all that apply): t TNWs,including territorial seas Wetlands adjacent to TNWs Relatively permanent waters (RPWs)that flow directly or indirectly into TNWs Non-RPWs that flow directly or indirectly into TNWs Wetlands directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to but not directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs Impoundments of jurisdictional waters Isolated(interstate or intrastate)waters,including isolated wetlands b. Identify(estimate)size of waters of the U.S.in the review area: Non-wetland waters: 17461inear feet: width(ft)and/or 0.256 acres. Wetlands:0.209 acres. c.Limits(boundaries)of jurisdiction based on: Elevation of established OHWM(if known): 2. Non-regulated waters/wetlands(check if applicable):3 Potentially jurisdictional waters and/or wetlands were assessed within the review area and determined to be not jurisdictional. Explain: Boxes checked below shall be supported by completing the appropriate sections in Section III below. 2 For purposes of this form,an RPW is defined as a tributary that is not a TNW and that typically flows year-round or has continuous flow at least"seasonally" (e.g.,typically 3 months). 3 Supporting documentation is presented in Section HI.F. • SECTION III: CWA ANALYSIS A. TNWs AND WETLANDS ADJACENT TO TNWs The agencies will assert jurisdiction over TNWs and wetlands adjacent to TNWs. If the aquatic resource is a TNW,complete Section HI.A.1 and Section III.D.1.only;if the aquatic resource is a wetland adjacent to a TNW,complete Sections III.A.1 and 2 and Section III.D.1.;otherwise,see Section III.B below. 1. TNW Identify TNW: Summarize rationale supporting determination: ?. Wedand adjacent_o T W ,`,Il;lll�lgrl�2��l❑Ul1211:.'i i:Lp0�[lll�Ciif1G�lStGi1 iluL'w�Cl Phil i5 `:idl2l'Y.I]T B. CHARACTERISTICS OF TRIBUTARY(THAT IS NOT A TNW)AND ITS ADJACENT WETLANDS(IF ANY): This section summarizes information regarding characteristics of the tributary and its adjacent wetlands,if any,and it helps determine whether or not the standards for jurisdiction established under Rapanos have been met. The agencies will assert jurisdiction over non-navigable tributaries of TNWs where the tributaries are`relatively permanent waters"(RPWs),i.e.tributaries that typically flow year-round or have continuous flow at least seasonally(e.g.,typically 3 months).A wetland that directly abuts an RPW is also jurisdictional.If the aquatic resource is not a TNW,but has year-round (perennial)flow,skip to Section IH.D.2.If the aquatic resource is a wetland directly abutting a tributary with perennial flow, skip to Section III.D.4. A wetland that is adjacent to but that does not directly abut an RPW requires a significant nexus evaluation.Corps districts and EPA regions will include in the record any available information that documents the existence of a significant nexus between a relatively permanent tributary that is not perennial(and its adjacent wetlands if any)and a traditional navigable water,even though a significant nexus finding is not required as a matter of law. If the waterbody°is not an RPW,or a wetland directly abutting an RPW,a JD will require additional data to determine if the waterbody has a significant nexus with a TNW.If the tributary has adjacent wetlands,the significant nexus evaluation must consider the tributary in combination with all of its adjacent wetlands.This significant nexus evaluation that combines,for analytical purposes,the tributary and all of its adjacent wetlands is used whether the review area identified in the JD request is the tributary,or its adjacent wetlands,or both.If the JD covers a tributary with adjacent wetlands,complete Section IH.B.1 for the tributary,Section III.B.2 for any onsite wetlands,and Section III.13.3 for all wetlands adjacent to that tributary,both onsite and offsite.The determination whether a significant nexus exists is determined in Section IH.0 below. 1. Characteristics of non-TNWs that flow directly or indirectly into TNW (i) General Area Conditions: Watershed size: 1,196,80 Drainage area: 5 im Average annual rainfall:38.1 inches Average annual snowfall: 15.6 inches (ii) Physical Characteristics: (a) Relationship with TNW: ❑Tributary flows directly into TNW. ® Tributary flows through I tributaries before entering TNW. Project waters are river miles from TNW. Project waters are river miles from RPW. Project waters are '= aerial(straight)miles from TNW. Project waters are aerial(straight)miles from RPW. Project waters cross or serve as state boundaries.Explain:N/A. Identify flow route to TNW5:Unimportant Intermittent Stream B flows into Stream A then into French Broad River. Tributary stream order,if known: 1. Note that the Instructional Guidebook contains additional information regarding swales,ditches,washes,and erosional features generally and in the and West. 5 Flow route can be described by identifying,e.g.,tributary a,which flows through the review area,to flow into tributary b,which then flows into TNW. 4 (b) General Tributary Characteristics(check all that apply): Tributary is: ®Natural ❑Artificial(man-made). Explain: ❑ Manipulated (man-altered). Explain: Tributary properties with respect to top of bank(estimate): Average width:4-5 feet Average depth:3-4 feet Average side slopes:';=,, Primary tributary substrate composition(check all that apply): ® Silts ❑ Sands ❑ Concrete Cobbles Gr,,i e! ] Muck 7 Bedrock ❑ Other. E:cplain: Tributary condition/stability[e.g.,highly eroding,sloughing banks]. Explain:moderate erosion and an incised channel. Presence of run/riffle/pool complexes. Explain:weak riffle/pool complexes. Tributary geometry:MINE Tributary gradient(approximate average slope):2-4% (c) Flow: Tributary provides for: Estimate average number of flow events in review area/yean Describe flow regime: Other information on duration and volume: Surface flow is:JIM. Characteristics: Subsurface flow: . Explain findings:Weak presence of groundwater flow. ❑ Dye(or other)test performed: Tributary has(check all that apply): ® Bed and banks ❑ OHWM6(check all indicators that apply): ❑ clear,natural line impressed on the bank ® the presence of litter and debris ❑ changes in the character of soil ❑ destruction of terrestrial vegetation ❑ shelving ❑ the presence of wrack line ❑ vegetation matted down,bent,or absent ❑ sediment sorting ❑ leaf litter disturbed or washed away ❑ scour ❑ sediment deposition ❑ multiple observed or predicted flow events ❑ water staining ❑ abrupt change in plant community ❑ other(list): ❑ Discontinuous OHWM.' Explain: If factors other than the OHWM were used to determine lateral extent of CWA jurisdiction(check all that apply): NJ High Tide Line indicated by: la Mean High Water Mark indicated by: ❑ oil or scum line along shore objects ❑ survey to available datum; ❑ fine shell or debris deposits(foreshore) ❑ physical markings; ❑ physical markings/characteristics ❑ vegetation lines/changes in vegetation types. ❑ tidal gauges ❑ other(list): (iii) Chemical Characteristics: Characterize tributary(e.g.,water color is clear,discolored,oily film;water quality;general watershed characteristics,etc.). Explain:no water in channel. Identify specific pollutants;if known: 6A natural or man-made discontinuity in the OHWM does not necessarily sever jurisdiction(e.g.,where the stream temporarily flows underground,or where the OHWM has been removed by development or agricultural practices). Where there is a break in the OHWM that is unrelated to the waterbody's flow regime(e.g.,flow over a rock outcrop or through a culvert),the agencies will look for indicators of flow above and below the break. 'Ibid. t (iv) Biological Characteristics. Channel supports(check all that apply): ® Riparian corridor. Characteristics(type,average width): ❑ Wetland fringe. Characteristics: ❑ Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑Aquatic/wildlife diversity. Explain findings: 2. Characteristics of wetlands adjacent to non-TNW that flow directly or indirectly into TNW (i) Physical Characteristics: (a) Genera] Wetland Characteristics: n"n i�ei'[P3S: -.G„CI L;iIU SILiJ: 1C:..o ✓Y etlanU type. _EYpiain: Wetland quality. Explain: Project wetlands cross or serve as state boundaries.Explain: (b) General Flow Relationship with Non-TNW: Flow is:Ago.Explain: Surface flow is:MW Characteristics: Subsurface flow:_ . Explain findings: ❑ Dye(or other)test performed: (c) Wetland Adjacency Determination with Non-TNW: ❑ Directly abutting ❑Not directly abutting ❑ Discrete wetland hydrologic connection. Explain: ❑ Ecological connection. Explain: ❑ Separated by berm/barrier. Explain: (d) Proximity(Relationship)to TNW Project wetlands are' river miles from TNW. Project waters are ' aerial(straight)miles from TNW. Flow is from: Estimate approximate location of wetland as within the fiffin floodplain. (ii) Chemical Characteristics: Characterize wetland system(e.g.,water color is clear,brown,oil fihn on surface;water quality;general watershed characteristics;etc.). Explain: Identify specific pollutants,if known: (iii)Biological Characteristics. Wetland supports(check all that apply): ❑ Riparian buffer. Characteristics(type,average width): ❑ Vegetation type/percent cover. Explain: ❑ Habitat for: ❑Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ❑ Aquatic/wildlife diversity. Explain findings: 3. Characteristics of all wetlands adjacent to the tributary(if any) All wetland(s)being considered in the cumulative analysis:am Approximately( )acres in total are being considered in the cumulative analysis. For each wetland,specify the following: Directly abuts?(Y/N) Size(in acres) Directly abuts?(Y/N) Size(in acres) Summarize overall biological,chemical and physical functions being performed: C. SIGNIFICANT NEXUS DETERMINATION sigai#'icanr nexus aaa,vsis will assess the;low characterisdcs and functions W :he lribatar-. itself and the fuacdoas oeriormed by any wetlands adjacent to the tributary to determine if they significantly affect the chemical,physical,and biological integrity of a TNW. For each of the following situations,a significant nexus exists if the tributary,in combination with all of its adjacent wetlands,has more than a speculative or insubstantial effect on the chemical,physical and/or biological integrity of a TNW. Considerations when evaluating significant nexus include,but are not limited to the volume,duration,and frequency of the flow of water in the tributary and its proximity to a TNW,and the functions performed by the tributary and all its adjacent wetlands. It is not appropriate to determine significant nexus based solely on any specific threshold of distance(e.g.between a tributary and its adjacent wetland or between a tributary and the TNW).Similarly,the fact an adjacent wetland lies within or outside of a floodplain is not solely determinative of significant nexus. Draw connections between the features documented and the effects on the TNW,as identified in the Rapanos Guidance and discussed in the Instructional Guidebook.Factors to consider include,for example: • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to carry pollutants or flood waters to TNWs,or to reduce the amount of pollutants or flood waters reaching a TNW? • Does the tributary,in combination with its adjacent wetlands(if any),provide habitat and lifecycle support functions for fish and other species,such as feeding,nesting,spawning,or rearing young for species that are present in the TNW? • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to transfer nutrients and organic carbon that support downstream foodwebs? • Does the tributary,in combination with its adjacent wetlands(if any),have other relationships to the physical,chemical,or biological integrity of the TNW? Note:the above list of considerations is not inclusive and other functions observed or known to occur should be documented below: 1. Significant nexus findings for non-RPW that has no adjacent wetlands and flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary itself,then go to Section III.D: 2. Significant nexus findings for non-RPW and its adjacent wetlands,where the non-RPW flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: 3. Significant nexus findings for wetlands adjacent to an RPW but that do not directly abut the RPW.Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section 111.1): D. DETERMINATIONS OF JURISDICTIONAL FINDINGS.THE SUBJECT WATERS/WETLANDS ARE(CHECK ALL THAT APPLY): 1. TNWs and Adjacent Wetlands. Check all that apply and provide size estimates in review area: TNWs: linear feet width(ft),Or, acres. Wetlands adjacent to TNWs: acres. 2. RPWs that flow directly or indirectly into TNWs. El Tributaries of TNWs where tributaries typically flow year-round are jurisdictional.Provide data and rationale indicating that tributary is perennial: Tributaries of TNW where tributaries have continuous flow"seasonally"(e.g.,typically three months each year)are jurisdictional. Data supporting this conclusion is provided at Section 11L13. Provide rationale indicating that tributary flows seasonally: Stream B flows north and is approximately 92 linear feet in length(Figure 1,enclosed). This channel exhibited average ordinary high water widths of 3-4 feet,weak ground water flow,and substrate consisting of silt to large gravel. Unimportant Intermittent Stream B scored 27 out of a possible 100 points on the USACE Stream Quality Assessment Form and 23.5 out of 71 possible points on the NCDWQ Stream Classification Form,indicating intermittent status(SCP4,enclosed). A photograph of Unimportant Intermittent Stream B is enclosed as Photograph G. t Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters:92 linear feet3-4width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 3. Non-RPWss that flow directly or indirectly into TNWs. Waterbody that is not a TNW or an RPW,but flows directly or indirectly into a TNW,and it has a significant nexus with a TNW is jurisdictional.Data supporting this conclusion is provided at Section III.C. ide %ar,.._ (-ii a!! thy:, irrl,:): El Triuutur, ti,,tars: fffle I- __, t dall i Ct;. 17 Other non-wetiand waters: acres. Identify type(s)of waters: 4. Wetlands directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands directly abut RPW and thus are jurisdictional as adjacent wetlands. Wetlands directly abutting an RPW where tributaries typically flow year-round. Provide data and rationale indicating that tributary is perennial in Section IILD.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Wetlands directly abutting an RPW where tributaries typically flow"seasonally." Provide data indicating that tributary is seasonal in Section III.B and rationale in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Provide acreage estimates for jurisdictional wetlands in the review area: acres. 5. Wetlands adjacent to but not directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands that do not directly abut an RPW,but when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisidictional.Data supporting this conclusion is provided at Section III.C. Provide acreage estimates for jurisdictional wetlands in the review area: acres. 6. Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs. Wetlands adjacent to such waters,and have when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional wetlands in the review area: acres. 7. Impoundments of jurisdictional waters.9 As a general rule,the impoundment of a jurisdictional tributary remains jurisdictional. Demonstrate that impoundment was created from`.`waters of the U.S.,"or Demonstrate that water meets the criteria for one of the categories presented above(1-6),or Demonstrate that water is isolated with a nexus to commerce(see E below). E. ISOLATED [INTERSTATE OR INTRA-STATE]WATERS,INCLUDING ISOLATED WETLANDS,THE USE, DEGRADATION OR DESTRUCTION OF WHICH COULD AFFECT INTERSTATE COMMERCE,INCLUDING ANY SUCH WATERS(CHECK ALL THAT APPLY):" which are or could be used by interstate or foreign travelers for recreational or other purposes. from which fish or shellfish are or could be taken and sold in interstate or foreign commerce. which are or could be used for industrial purposes by industries in interstate commerce. aSee Footnote#3. 9 To complete the analysis refer to the key in Section III.D.6 of the Instructional Guidebook 10 Prior to asserting or declining CWA jurisdiction based solely on this category,Corps Districts will elevate the action to Corps and EPA HQ for review consistent with the process described in the Corps/EPA Memorandum Regarding CWA Act Jurisdiction Following Rapanos. 1 Interstate isolated waters. Explain: Other factors. Explain: Identify water body and summarize rationale supporting determination: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: Wetlands: acres. i?1S i 7 .J i =RS, .. i u syi T ^IvS s,CHECX .-'ii- 31AT.�P�L'f;; tf potential wetlands were assessed within the review area, these areas did not meet the criteria in the i)S 7 Corps of Engineers Wetland Delineation Manual and/or appropriate Regional Supplements. Review area included isolated waters with no substantial nexus to interstate(or foreign)commerce. ❑ Prior to the Jan 2001 Supreme Court decision in"SWANCC,"the review area would have been regulated based solely on the "Migratory Bird Rule"(MBR). Waters do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction. Explain: Other: (explain,if not covered above): Provide acreage estimates for non jurisdictional waters in the review area,where the sole potential basis of jurisdiction is the MBR factors(i.e.,presence of migratory birds,presence of endangered species,use of water for irrigated agriculture),using best professional judgment(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet width(ft). Lakes/ponds: acres. Other non-wetland waters: acres.List type of aquatic resource: Wetlands: acres. Provide acreage estimates for non jurisdictional waters in the review area that do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet, width(ft). Lakes/ponds: acres. Other non-wetland waters: acres. List type of aquatic resource: Wetlands: acres. SECTION IV: DATA SOURCES. A. SUPPORTING DATA. Data reviewed for JD(check all that apply-checked items shall be included in case file and,where checked and requested,appropriately reference sources below): Maps,plans,plots or plat submitted by or on behalf of the applicant/consultant: Data sheets prepared/submitted by or on behalf of the applicant/consultant. ® Office concurs with data sheets/delineation report. ❑ Office does not concur with data sheets/delineation report. Data sheets prepared by the Corps: Corps navigable waters'study: U.S.Geological Survey Hydrologic Atlas: ❑ USGS NHD data. ❑ USGS 8 and 12 digit HUC maps. U.S.Geological Survey map(s). Cite scale&quad name:Skyland,North Carolina, 1991. USDA Natural Resources Conservation Service Soil Survey.Citation: National wetlands inventory map(s). Cite name: State/Local wetland inventory map(s): FEMA/FIRM maps: 100-year Floodplain Elevation is: (National Geodectic Vertical Datum of 1929) Photographs:❑Aerial(Name&Date): or® Other(Name&Date):See attached report. Previous determination(s). File no. and date of response letter: Applicable/supporting case law: Applicable/supporting scientific literature: Other information(please specify): APPROVED JURISDICTIONAL DETERMINATION FORM U.S.Army Corps of Engineers This form should be completed by following the instructions provided in Section IV of the JD Form Instructional Guidebook. SECTION I: BACKGROUND INFORMATION A. REPORT COMPLETION DATE FOR APPROVED JURISDICTIONAL DETERMINATION(JD):July 16,2007 B. DISTRICT OFFICE,FILE NAME,AND NUMBER:Asheville Regional Office C. PROJECT LOCATION AND BACKGROUND INFORMATION:The Asheville Regional Airport Expansion site is located adjacent to Highway 26, on existing Airport Authority property in Fletcher,North Carolina,Perennial Stream C and Wetland CC State:NC County/parish/borough:Buncombe City: Fletcher --- �ni:��r�al�'_ans:-erne:�iera;tor: Name of nearest waterbody: French Broad River Name of nearest Traditional Navigable Water(TNW)into which the aquatic resource flows:French Broad River Name of watershed or Hydrologic Unit Code(HUC):06010105 Check if map/diagram of review area and/or potential jurisdictional areas is/are available upon request. Check if other sites(e.g.,offsite mitigation sites,disposal sites,etc...)are associated with this action and are recorded on a different JD form. D. REVIEW PERFORMED FOR SITE EVALUATION(CHECK ALL THAT APPLY): Office(Desk)Determination. Date:June 19,2007 Field Determination. Date(s):June 13,2007 SECTION H: SUMMARY OF FINDINGS A. RHA SECTION 10 DETERMINATION OF JURISDICTION. There` "navigable waters of the U.S."within Rivers and Harbors Act(RHA)jurisdiction(as defined by 33 CFR part 329)in the review area.[Required] Waters subject to the ebb and flow of the tide. Waters are presently used,or have been used in the past,or may be susceptible for use to transport interstate or foreign commerce. Explain: B. CWA SECTION 404 DETERMINATION OF JURISDICTION. There i "waters of the U.S."within Clean Water Act(CWA)jurisdiction(as defined by 33 CFR part 328)in the review area.[Required] 1. Waters of the U.S. a. Indicate presence of waters of U.S.in review area(check all that apply): t TNWs,including territorial seas Wetlands adjacent to TNWs Relatively permanent waters (RPWs)that flow directly or indirectly into TNWs Non-RPWs that flow directly or indirectly into TNWs Wetlands directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to but not directly abutting RPWs that flow directly or indirectly into TNWs Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs Impoundments of jurisdictional waters Isolated(interstate or intrastate)waters,including isolated wetlands b. Identify(estimate)size of waters of the U.S.in the review area: Non-wetland waters: 17461inear feet: width(ft)and/or 0.256 acres. Wetlands:0.209 acres. c.Limits(boundaries)of jurisdiction based on: Elevation of established OHWM(if known): 2. Non-regulated waters/wetlands(check if applicable):3 Potentially jurisdictional waters and/or wetlands were assessed within the review area and determined to be not jurisdictional. Explain: Boxes checked below shall be supported by completing the appropriate sections in Section III below. Z For purposes of this form,an RPW is defined as a tributary that is not a TNW and that typically flows year-round or has continuous flow at least"seasonally" (e.g.,typically 3 months). 3 Supporting documentation is presented in Section III.F. SECTION III: CWA ANALYSIS A. TNWs AND WETLANDS ADJACENT TO TNWs The agencies will assert jurisdiction over TNWs and wetlands adjacent to TNWs. If the aquatic resource is a TNW,complete Section HI.A.1 and Section III.D.1.only;if the aquatic resource is a wetland adjacent to a TNW,complete Sections III.A.1 and 2 and Section III.DA.; otherwise,see Section III.B below. 1. TNW Identify TNW: Summarize rationale supporting determination: 2. -I.Netland adjacent to TN IN �Ulll lllflLl�3 i1�lOC1 EItC:SLtiitJUitLL JU11CiU�l 011 .�liu \c�,.t Lt,l '� ict�dl''�tlC _ B. CHARACTERISTICS OF TRIBUTARY(THAT IS NOT A TNW)AND ITS ADJACENT WETLANDS(IF ANY): This section summarizes information regarding characteristics of the tributary and its adjacent wetlands,if any,and it helps determine whether or not the standards for jurisdiction established under Rapanos have been met. The agencies will assert jurisdiction over non-navigable tributaries of TNWs where the tributaries are"relatively permanent waters"(RPWs),i.e.tributaries that typically flow year-round or have continuous flow at least seasonally(e.g.,typically 3 months).A wetland that directly abuts an RPW is also jurisdictional.If the aquatic resource is not a TNW,but has year-round (perennial)flow,skip to Section IH.D.2.If the aquatic resource is a wetland directly abutting a tributary with perennial flow, skip to Section HI.D.4. A wetland that is adjacent to but that does not directly abut an RPW requires a significant nexus evaluation.Corps districts and EPA regions will include in the record any available information that documents the existence of a significant nexus between a relatively permanent tributary that is not perennial(and its adjacent wetlands if any)and a traditional navigable water,even though a significant nexus finding is not required as a matter of law. If the waterbody4 is not an RPW,or a wetland directly abutting an RPW,a JD will require additional data to determine if the waterbody has a significant nexus with a TNW.If the tributary has adjacent wetlands,the significant nexus evaluation must consider the tributary in combination with all of its adjacent wetlands.This significant nexus evaluation that combines,for analytical purposes,the tributary and all of its adjacent wetlands is used whether the review area identified in the JD request is the tributary,or its adjacent wetlands,or both.If the JD covers a tributary with adjacent wetlands,complete Section HLBA for the tributary,Section HI.B.2 for any onsite wetlands,and Section IH.B3 for all wetlands adjacent to that tributary,both onsite and offsite.The determination whether a significant nexus exists is determined in Section IH.0 below. 1. Characteristics of non-TNWs that flow directly or indirectly into TNW (i) General Area Conditions: Watershed size: 1,196,80 Drainage area: 1.68 IM Average annual rainfall:3 8.1 inches Average annual snowfall: 15.6 inches (ii) Physical Characteristics: (a) Relationship with TNW: ❑ Tributary flows directly into TNW. ® Tributary flows through I tributaries before entering TNW. Project waters are river miles from TNW. Project waters are river miles from RPW. Project waters are aerial(straight)miles from TNW. Project waters are aerial(straight)miles from RPW. Project waters cross or serve as state boundaries.Explain:N/A. Identify flow route to TNW5:Perennial Stream C meets Perennial Stream A and then flows into French Broad River. Tributary stream order,if known: 1. 4 Note that the Instructional Guidebook contains additional information regarding swales,ditches,washes,and erosional features generally and in the and West. 5 Flow route can be described by identifying,e.g.,tributary a,which flows through the review area,to flow into tributary b,which then flows into TNW. (b) General Tributary Characteristics(check all that apply): Tributary is: ®Natural ❑Artificial(man-made). Explain: ❑ Manipulated (man-altered). Explain: Tributary properties with respect to top of bank(estimate): Average width:4-5 feet Average depth:3-4 feet Average side slopes:0 Primary tributary substrate composition(check all that apply): ® Silts ❑ Sands ❑ Concrete 17 Cobbles ❑ Cra -c1 I-1 muck, I� 3e,,imck ❑ Other. Expiain: Tributary condition/stability[e.g.,highly eroding,sloughing banks]. Explain:moderate erosion and an incised channel. Presence of run/riffle/pool complexes. Explain:moderate riffle/pool complexes. Tributary geometry:Iffielomm Tributary gradient(approximate average slope): 0-2% (c) Flow: Tributary provides for:: Estimate average number of flow events in review area/year: Describe flow regime: Other information on duration and volume: Surface flow is: Characteristics: Subsurface flow:JS. Explain findings:Groundwater present in channel,no rain within last 48 hours. ❑ Dye(or other)test performed: Tributary has(check all that apply): ® Bed and banks ® OHWM6(check all indicators that apply): ❑ clear,natural line impressed on the bank ❑ the presence of litter and debris ❑ changes in the character of soil ❑ destruction of terrestrial vegetation ❑ shelving ❑ the presence of wrack line ® vegetation matted down,bent,or absent ❑ sediment sorting ® leaf litter disturbed or washed away ® scour ® sediment deposition ❑ multiple observed or predicted flow events ❑ water staining ❑ abrupt change in plant community ❑ other(list): ❑ Discontinuous OHWM.' Explain: If factors other than the OHWM were used to determine lateral extent of CWA jurisdiction(check all that apply): High Tide Line indicated by: a Mean High Water Mark indicated by: ❑ oil or scum line along shore objects ❑ survey to available datum; ❑ fine shell or debris deposits(foreshore) ❑ physical markings; ❑ physical markings/characteristics ❑ vegetation lines/changes in vegetation types. ❑ tidal gauges ❑ other(list): (iii) Chemical Characteristics: Characterize tributary(e.g.,water color is clear,discolored,oily film;water quality;general watershed characteristics,etc.). Explain: clear water. Identify specific pollutants,if known: 6A natural or man-made discontinuity in the OHWM does not necessarily sever jurisdiction(e.g.,where the stream temporarily flows underground,or where the OHWM has been removed by development or agricultural practices). Where there is a break in the OHWM that is unrelated to the waterbody's flow regime(e.g.,flow over a rock outcrop or through a culvert),the agencies will look for indicators of flow above and below the break. 'Ibid. (iv) Biological Characteristics. Channel supports(check all that apply): ❑ Riparian corridor. Characteristics(type,average width): ® Wetland fringe. Characteristics: ® Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ® Aquatic/wildlife diversity. Explain findings:weak presence of crayfish and amphibians,and a weak presence of benthic macroinvertebrates. 2. Characteristics of wetlands adjacent to non-TNW that flow directly or indirectly into TNW (i) Physical Characteristics: �il General Wedand Characteristics: i"i ol_nerti C�: W fttand size:0.t Zacres Wetland type. Explain:forested. Wetland quality. Explain: Project wetlands cross or serve as state boundaries.Explain: (b) General Flow Relationship with Non-TNW: Flow is:JW#QWM.Explain: Groundwater present in channel,no rain within last 48 hours. Surface flow is: ```"44r ' '& .;:9;.. Characteristics: Subsurface flow: Explain findings: Groundwater present in channel,no rain within last 48 hours,saturation within the upper 12 inches of the soil profile. ❑ Dye(or other)test performed: (c) Wetland Adjacency Determination with Non-TNW: ® Directly abutting ❑Not directly abutting ❑ Discrete wetland hydrologic connection. Explain: ❑ Ecological connection. Explain: ❑ Separated by berm/barrier. Explain: (d) Proximity(Relations In to TNW Project wetlands are '� ` +�' river miles from TNW. Project waters are aerial(straight)miles from TNW. Flow is from:' Estimate approximate location of wetland as within the-J11111fiM floodplain. (ii) Chemical Characteristics: Characterize wetland system(e.g.,water color is clear,brown,oil film on surface;water quality;general watershed characteristics;etc.). Explain:clear water. Identify specific pollutants,if known: (iii)Biological Characteristics. Wetland supports(check all that apply): ❑ Riparian buffer. Characteristics(type,average width): ® Vegetation type/percent cover. Explain:A11 of the dominant plant species are FAC or wetter. ® Habitat for: ❑ Federally Listed species. Explain findings: ❑ Fish/spawn areas.Explain findings: ❑ Other environmentally-sensitive species. Explain findings: ®Aquatic/wildlife diversity. Explain findings:weak presence of amphibians and macrobenthos. 3. Characteristics of all wetlands adjacent to the tributary(if an ) All wetland(s)being considered in the cumulative analysis: Approximately(0.172)acres in total are being considered in the cumulative analysis. For each wetland,specify the following: Directly abuts?(Y/N) Size(in acres) Directly abuts?(Y/N) Size(in acres) Wetland CC Y 0.172 Summarize overall biological,chemical and physical functions being performed: C. SIGNIFICANT NEXUS DETERMINATION A significant ilesaas ana'rsis;vaii assess tine fiow characteristics and functions of the iributar•:itself and the functions performed by anv wetlands adjacent to the tributary to determine if then significantly affect the chemical, physical,and biological integrity of a TNW. For each of the following situations,a significant nexus exists if the tributary,in combination with all of its adjacent wetlands,has more than a speculative or insubstantial effect on the chemical,physical and/or biological integrity of a TNW. Considerations when evaluating significant nexus include,but are not limited to the volume,duration,and frequency of the flow of water in the tributary and its proximity to a TNW,and the functions performed by the tributary and all its adjacent wetlands. It is not appropriate to determine significant nexus based solely on any specific threshold of distance(e.g.between a tributary and its adjacent wetland or between a tributary and the TNW).Similarly,the fact an adjacent wetland lies within or outside of a floodplain is not solely determinative of significant nexus. Draw connections between the features documented and the effects on the TNW,as identified in the Rapanos Guidance and discussed in the Instructional Guidebook.Factors to consider include,for example: • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to carry pollutants or flood waters to TNWs,or to reduce the amount of pollutants or flood waters reaching a TNW? • Does the tributary,in combination with its adjacent wetlands(if any),provide habitat and lifecycle support functions for fish and other species,such as feeding,nesting,spawning,or rearing young for species that are present in the TNW? • Does the tributary,in combination with its adjacent wetlands(if any),have the capacity to transfer nutrients and organic carbon that support downstream foodwebs? • Does the tributary,in combination with its adjacent wetlands(if any),have other relationships to the physical,chemical,or biological integrity of the TNW? Note:the above list of considerations is not inclusive and other functions observed or known to occur should be documented below: 1. Significant nexus findings for non-RPW that has no adjacent wetlands and flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary itself,then go to Section III.D: 2. Significant nexus findings for non-RPW and its adjacent wetlands,where the non-RPW flows directly or indirectly into TNWs. Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: 3. Significant nexus findings for wetlands adjacent to an RPW but that do not directly abut the RPW.Explain findings of presence or absence of significant nexus below,based on the tributary in combination with all of its adjacent wetlands,then go to Section III.D: D. DETERMINATIONS OF JURISDICTIONAL FINDINGS.THE SUBJECT WATERS/WETLANDS ARE(CHECK ALL THAT APPLY): 1. TNWs and Adjacent Wetlands. Check all that apply and provide size estimates in review area: TNWs: linear feet width($),Or, acres. Wetlands adjacent to TNWs: acres. 2. RPWs that flow directly or indirectly into TNWs. Tributaries of TNWs where tributaries typically flow year-round are jurisdictional.Provide data and rationale indicating that tributary is perennial: Stream C flows east for approximately 114 linear feet until its confluence with Perennial Stream A(Figure 1,enclosed). This channel exhibited an average ordinary high water width of 1-2 feet,perennial flow,weak sinuosity,and substrate consisting of silt to large gravel. Perennial Stream C scored 55 out of a possible 100 points on the USACE Stream Quality Assessment Form and 30 out of 71 possible points on the NCDWQ Stream Classification Form,indicating intermittent status(SCP5,enclosed).A Photograph of Stream C is enclosed as Photograph F. Tributaries of TNW where tributaries have continuous flow"seasonally"(e.g.,typically three months each year)are jurisdictional. Data supporting this conclusion is provided at Section III.B. Provide rationale indicating that tributary flows seasonally: Provide estimates for jurisdictional waters in the review area(check all that apply): Tributary waters: 114 linear feet4-5width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 3. Non-RPWss that flow directly or indirectly into TNWs. Waterbody that is not a TNW or an RPW,but flows directly or indirectly into a TNW,and it has a significant nexus with a jurisaiuional. Data;uppnrtin<r this conclusion is at Senon 1_'I.(-. Provide estimates tbrjurisdictional waters ",vithin the review area(check all that apply): Tributary waters: linear feet width(ft). Other non-wetland waters: acres. Identify type(s)of waters: 4. Wetlands directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands directly abut RPW and thus are jurisdictional as adjacent wetlands. Wetlands directly abutting an RPW where tributaries typically flow year-round. Provide data and rationale indicating that tributary is perennial in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW:Wetland CC is located at the downstream portion of Perennial Stream A(Figure 1, enclosed). This forested wetland area is approximately 0.172 acre is size. Dominant vegetation within this area includes black gum(Nyssa sylvatica),black willow(Salix nigra),ironwood(Carpinus caroliniana),silky dogwood (Cornus amomum),false nettle(Boehmeria cylindrical),common rush(Juncus effuses),jewelweed(Impatiens capensis),and various sedges(Carex spp.). This area exhibited low chroma soils(10YR 4/1),inundation to 2 inches,drainage patterns,and saturation within the upper 12 inches of the soil profile. A Routine On-Site Determination Form representative of Wetland CC is enclosed(DP4). Photographs of Wetland CC are enclosed as Photographs C and D. A Routine On-Site Determination Form representative of on-site non-jurisdictional upland areas is also enclosed(DPI). Wetlands directly abutting an RPW where tributaries typically flow"seasonally." Provide data indicating that tributary is seasonal in Section III.B and rationale in Section III.D.2,above.Provide rationale indicating that wetland is directly abutting an RPW: Provide acreage estimates for jurisdictional wetlands in the review area:0.172acres. 5. Wetlands adjacent to but not directly abutting an RPW that flow directly or indirectly into TNWs. Wetlands that do not directly abut an RPW,but when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisidictional.Data supporting this conclusion is provided at Section III.C. Provide acreage estimates for jurisdictional wetlands in the review area: acres. 6. Wetlands adjacent to non-RPWs that flow directly or indirectly into TNWs. Wetlands adjacent to such waters,and have when considered in combination with the tributary to which they are adjacent and with similarly situated adjacent wetlands,have a significant nexus with a TNW are jurisdictional.Data supporting this conclusion is provided at Section III.C. Provide estimates for jurisdictional wetlands in the review area: acres. 7. Impoundments of jurisdictional waters.9 As a general rule,the impoundment of a jurisdictional tributary remains jurisdictional. Demonstrate that impoundment was created from"waters of the U.S.,"or Demonstrate that water meets the criteria for one of the categories presented above(1-6),or Demonstrate that water is isolated with a nexus to commerce(see E below). 8See Footnote#3. 9 To complete the analysis refer to the key in Section IMD.6 of the Instructional Guidebook E. ISOLATED [INTERSTATE OR INTRA-STATE] WATERS,INCLUDING ISOLATED WETLANDS,THE USE, DEGRADATION OR DESTRUCTION OF WHICH COULD AFFECT INTERSTATE COMMERCE,INCLUDING ANY SUCH WATERS(CHECK ALL THAT APPLY):io which are or could be used by interstate or foreign travelers for recreational or other purposes. from which fish or shellfish are or could be taken and sold in interstate or foreign commerce. which are or could be used for industrial purposes by industries in interstate commerce. Interstate isolated waters. Explain: Other factors. Explain: Identify water body and summarize rationale supporting determination: I Tributary waters: linear feel ,vidth(tt). Other non-wetland waters: acres. Identify type(s)of waters: Wetlands: acres. F. NON-JURISDICTIONAL WATERS,INCLUDING WETLANDS(CHECK ALL THAT APPLY): If potential wetlands were assessed within the review area,these areas did not meet the criteria in the 1987 Corps of Engineers Wetland Delineation Manual and/or appropriate Regional Supplements. Review area included isolated waters with no substantial nexus to interstate(or foreign)commerce. ❑ Prior to the Jan 2001 Supreme Court decision in"SWANCC,"the review area would have been regulated based solely on the "Migratory Bird Rule"(MBR). Waters do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction. Explain: Other:(explain,if not covered above): Provide acreage estimates for non jurisdictional waters in the review area,where the sole potential basis of jurisdiction is the MBR factors(i.e.,presence of migratory birds,presence of endangered species,use of water for irrigated agriculture),,using best professional judgment(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet width(ft). Lakes/ponds: acres. Other non-wetland waters: acres.List type of aquatic resource: Wetlands: acres. Provide acreage estimates for non jurisdictional waters in the review area that do not meet the"Significant Nexus"standard,where such a finding is required for jurisdiction(check all that apply): Non-wetland waters(i.e.,rivers,streams): linear feet, width(ft). Lakes/ponds: acres. Other non-wetland waters: acres. List type of aquatic resource: Wetlands: acres. SECTION IV: DATA SOURCES. A. SUPPORTING DATA. Data reviewed for JD(check all that apply-checked items shall be included in case file and,where checked and requested,appropriately reference sources below): Maps,plans,plots or plat submitted by or on behalf of the applicant/consultant: Data sheets prepared/submitted by or on behalf of the applicant/consultant. ® Office concurs with data sheets/delineation report. ❑ Office does not concur with data sheets/delineation report. mlData sheets prepared by the Corps: Corps navigable waters' study: U.S.Geological Survey Hydrologic Atlas: ❑ USGS NHD data. ❑ USGS 8 and 12 digit HUC maps. U.S.Geological Survey map(s).Cite scale&quad name:Skyland,North Carolina, 1991. USDA Natural Resources Conservation Service Soil Survey.Citation: National wetlands inventory map(s). Cite name: 70 Prior to asserting or declining CWA jurisdiction based solely on this category,Corps Districts will elevate the action to Corps and EPA HQ for review consistent with the process described in the Corps/EPA Memorandum Regarding CWA Act Jurisdicdon Following Rapanos. Y State/Local wetland inventory map(s): FEMA/FIRM maps: 100-year Floodplain Elevation is: (National Geodectic Vertical Datum of 1929) Photographs: Aerial(Name&Date): or® Other(Name&Date):See attached report. Previous determination(s). File no.and date of response letter: Applicable/supporting case law: Applicable/supporting scientific literature: Other information(please specify): B. ADDITIONAL COMMENTS TO SUPPORT JD: gi s 1 �ftw # �� r UsTITO=uF MIOMMM, W71111 _ y 0 J f., . x , J `J �"....;,., 1 .N -' �.✓.e�'.: � r�r'r KS i� 2..I. ^ a :�.L.r'.'�sP '"I Yr ` 77 }�s } 1 °• Y 4 JW'/.fkn, � -+t �:�+ 2 T��/ �`r` --�4'f il4 y i7 w•• fir' � + ,:Y',�' ''!� d� i". "" '� j - a,. i ! . k A �µ a._'`e"y's_--•'Y`. +�.�4•gam -:R.?. �i. ..'Ra. ...� ,�'= �..��� ,_ , C - .M w + �'4' �. _ rj',� '\ice �.p � •� .� JII{ ti r� S � '� '' 3 X ., �h Ott � a•'�C *w ilY" B t � r rt�rj+p 5 kM1 e l 16 ~ Y •,�- � �key � ` � P+S�,� �+�n.Y� �"s' ;' •. R ' �r•. 1■. .m.�� �a �:1, Pik ' F I r • •' . • • 1 ii I-Al•• ' • - .. -"�VP .� ,>����: to'"�.,,.�ta�q •ytir�i.'k ��' ' €;. a !'����ply• � ��. � ,�� �9. ° n �Q . zs z ,� '�,,,.r•^' �•^fir � •;F. a, �.. > +�' � - � �+' �, �1•'' �-`= � \gam �..J�. if s A, �W !ZX f fl yf• �' 7 fir' t �,."T"3' � F 7*A RCDENR North Carolina Department of Environment and Natural Resources Michael F. Easley, Governor William G. Ross Jr., Secretary June 13, 2007 Mr. Anthony Nardo Carolina Wetland Services 550 E. Westinghouse Blvd. Charlotte,NC 28273 Subject: Asheville Regional Airport Project—Expa d Existing Airport in;ruseructare, l:tcl,er, Buncombe County CWS Project No. 2007-1889 Dear Mr. Nardo: The Natural Heritage Program has no current record of rare species, significant natural communities, or significant natural heritage areas at the site nor within 1/2-mile of the project area. [There are historic records of rare aquatic species in the French Broad River, within one mile.] You may wish to check the Natural Heritage Program database website at www.ncnhp.org for a listing of rare plants and animals and significant natural communities in the county and on the quad map. NC OneMap now provides digital Natural Heritage data online for free. This service provides site specific information on G1S layers with Natural Heritage Program rare species occurrences and Significant Natural Heritage Areas. The NC OneMap website provides Element Occurrence(EO)ID numbers(instead of species name), and the data user is then encouraged to contact the Natural Heritage Program for detailed information. This service allows the user to quickly and efficiently get site specific NHP data without visiting the NHP workroom or w;iting for the Information Request to be answered by NHP staff. For more information about data formats and access, visit<www.nconemap.com/data.html>, or email NC OneMap at<data@ncmail.net>. Please do not hesitate to contact me at 919-715-8697 if you have questions or need further information. Sincerely, Harry E. LeGrand, Jr., Zoologist Natural Heritage Program 1601 Mail Service Center, Raleigh, North Carolina 27699-1.601 ne o Carolina Phone: 919-733-49841 FAX: 919-715-30601 Internet: www.enr.state.nc.us/ENR/ Qtllrll!ll,J An Equal Opportunity I Affirmative Action Employer-50%Recycled 110%Post Consumer Paper �STATE,. North Carolina Department of Cultural Resources State Historic Preservation Office Peter B.Sandbeck,Administrator Michael F.Easley,Governor Office of Archives and History Lisbeth C.Evans,Secretary Division of Historical Resources Jeffrey J.Crow,Deputy Secretary David Brook,Director July 13, 2007 Anthony W. Nardo Andrea L. Hughes Carolina Wetland Services 650 E. `x'es��ghcuse Blvd. Charlotten, NC 28273 Re: Asheville Regional Airport, Fletcher,Buncombe County, ER 07-1252 Dear Mr. Nardo and Ms. Hughes: Thank you for your letter of June 5, 2007, concerning the above project. There are no known recorded archaeological sites within the project boundaries. However, the project area has never been systematically surveyed to determine the location or significance of archaeological resources. Based on the topographic and hydrological situation, there is a high probability for the presence of prehistoric or historic archaeological sites. We recommend that a comprehensive survey be conducted by an experienced archaeologist to identify and evaluate the significance of archaeological remains that may be damaged or destroyed by the proposed project. Potential effects on unknown resources must be assessed prior to the initiation of construction activities. Two copies of the resulting archaeological. survey report, as well as one copy of the appropriate site forms, should be forwarded to us for review and comment as soon as they are available and well in advance of any construction activities. A list of archaeological consultants who have conducted or expressed an interest in contract work in North Carolina is available at www.arch.dcr.state.nc.us/consults.htm. The archaeologists listed, or any other experienced archaeologist, may be contacted to conduct the recommended survey. The above comments are made pursuant to Section 106 of the National Historic Preservation Act and the Advisory Council on Historic Preservation's Regulations for Compliance with Section 106 codified at 36 CFR Part 800. Location Mailing Address Telephone/Fax ADMINISTRATION 507 N.Blount Street,Raleigh NC 4617 Mail Service Center,Raleigh NC 27699-4617 (919)733-4763/733-8653 RESTORATION 515 N.Blount Street,Raleigh NC 4617 Mail Service Center,Raleigh NC 276994617 (919)733-6547/7154801 SURVEY&PLANNING 515 N.Blount Street,Raleigh,NC 4617 Mail Service Center,Raleigh NC 276994617 (919)733-6545/7154801 Thank you for your cooperation and consideration. If you have questions concerning the above comment, contact Renee Gledhill-Earley, environmental review coordinator, at 919/733-4763 ext. 246. In all future communication concerning this project,please cite the above referenced tracking number. Slucerely, l Peter Sandbeck � e ASHEVILLE J AREA CHAMBER OF COMMERCE October 19, 2007 Mr. David Edwards, Jr. Director Asheville Regional Airport Authority PO Box 817 Fletcher,NC 28732 Dear Dave: On behalf of our Chamber of Commerce Board of Directors, I wish to commend you and your Board for your initiative in preparing the Authority's acreage between the runway and 1-26 for development. Clearly, Asheville Regional plays a major role in our regional economy and the additional business envisioned for the northern sites will add to that positive economic impact. I understand that you are in the midst of the permitting process and trust that will progress smoothly. If we can assist in some way, please feel free to call on me. Sincerely, Richard J. Lutovsky President& CEO cc: Craig R. Wyant ?O BOX ioio A�HEVILLE, NORTH CAROUNA °sso° iS° ) 8-cioi FAX 0c,�,. 11 • wto://ww,r.ashcvillccnaml.:.ore asn.vi(c�'a.•nc,•in<:hamxcar¢ v v Asheville Regional Airport Project Individual Permit Application Proiect No.2007-1889 Asheville Regional Airport - Adjacent Property Owners Buncombe County City of Asheville Kachman, David and Martha 35 Branrick Ln, Arden, NC 28704 Mack JR, Woodrow and Patricia 5 Hidden Creek Rd. Arden,NC 28704 Moss, Frank E. 13 Hidden Creek Rd. Arden,NC 28704 Lanning JR, Geo and Connie 130 Tom Johnson Rd. Columbus,NC 28722 Gibson, Charles R. 42 Rattlesnake Dr. Sylva,NC 28779 Osorino, Arturo PO Box 761 Mountain Home,NC 28758 McKinney, James and JoAnne 16 Nathan Dr. Arden,NC 28704 McFalls, Clota J. 323 Jones Rd. Fletcher,NC 28732 Woody, Jerry M. PO Box 6318 Asheville,NC 28816 Green, Gail B. 10 Nathan Dr. Arden,NC 28704 Case JR,Alvin J. 101 Hidden Creek Rd. a r 11 Asheville Regional Airport Project Individual Permit Application Proiect No.2007-1889 Arden,NC 28704 Henderson County Henderson County City of Asheville Cadgene, Marie-Jeanne and Cadgene,Narcisse PO Box 10 Redvale, CO 81431 Broadmoor Group Inc. 101 French Broad Ln. Fletcher,NC 28732 Putman, Charles; Litten, Karl V; Kassouf, Lawrence F 90 Hillcrest Dr. Weaverville,NC 28787 Trenary, Larry M; Atkinson, George W; Trutch, Steven A PO Box 7625 Asheville,NC 28802 French Broad Associates 1609 Rockledge Dr. Rockledge, FL 32955 ° Do 0 7 — 1 84 1 OCT 2 9 2007 WK WKD NO. 'ZU Z7:2,Ord'u. DE:Nk-vVA7ER LTUALIT`Y DICKSON WETLANDS AND STOWATER BRANCH SHEET No. OF community Infrastructure consultants JOB NAME COMPUTED BY C C-t F DATE CLIENT CHECKED BY DATE { � i I 1 I ! i ! { pub I !_. oiq o12 3. } ry _ f t yy� , 1 > i i ! i € € , ! /rye)V i i � ! 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Precipitation Frequency Data Server Page 1 of 4 POINT PRECIPITATION ` ` """ FREQUENCY ESTIMATES ,, FROM NOAA ATLAS 14 North Carolina 35.4361944 N 82.5418056 W 2152 feet from'Precipitation-Frequency Atlas of the United States"NOAA Atlas 14,Volume 2,Version 3 G.M.Bonnin,D.Martin,B.Lin,T.Parzybok,M,Yekta,and D.Riley NOAA,National Weather Service,Silver Spring,Maryland,2004 � Ex(racted:Mon Oct 8 2007 Precipitation Intensity Estimates W/hr) AEP*_ 5 10 15 30 60 124 3 6 1Z 24 48 4 7 10 20 30 45 60 (1Yn min min min min min min hr hr hr hr hr day day day day day day day 0 4.80 3.83 3.21 2.22 1.39 0.81 4.57 0.35 0.22 0.13 0.08 0.04 0. 33 0.02 0.02 0.01 0.01 0.01 0 6.10 4.89 4.12 2.93 1.88 I.09 0.76 0.46 0.29 O.17 O.IO 0.06 0.04 0.03 0.02 0.02 0.01 0.41 10 b.96 5.57. 4.70`: 3.40 2.22 1.29 0.90 0.55 0.34 0.20 0.12 OA6 0.44 QA3 0.02 0.02 6.61 6.61 25 8.03 6.40 5.4I 4.00 2.67 1.55 I.IO 0.66 0.40 0,24 0.14 0.08 0.05 0.04 0.03 0.02 0.02 0.01 50 8.81 7.02 5.92 4.46 3.02 1.76 1.26 0.75 0.45 0.27 O.lb 0.08 0.06 0.04 0.03 0.02 0.02 0.01 100 9.60 Efl 6.43 4.92 3.39 1.98 I.42 0.86 0.50 0.30 0.17 0.09 OF067 0.05 0.03 0.02 0.02 0.02 200 10.37 8.22 6.92 5.39 3.78 2,22 1.6I 4,97 0.55 0.33 O.19 0.10 0.47 0.05 0.43 0.42 0.02 0.02 500 11.40 9.02 7.57 6.02 4.32 2.55 1.87 1.13 O.b3 0,38 0.2I 0.11 4.07 0.06 0.03 0.03 0.02 0.02 1000 12.2I 9.62 8.05 6.52 4.76 2.81 2.08 .2b 0.69 0.4 I 0.23 0.]2 0.08 0.06 0.44 0.03 0.02 0.02 `These precipitation frequency estimates are based on an;111 u (I axima series.AEP is the Annual Exceedance PtobabRity. 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'`:� �i 1'�"- ^'��_�.9•�z��g.;. 7 ..yy�ttR� ,fsV7i. �� ��?r.�-°•�4.��i',•t��4'TS:'r2�1+�7+.tts�i��`~Se�s�.�'.�3Y��?;�`aisNw'�,,...�µ'..�'i�L'�a.�'E �'�S�i���F���.��.l�t��'C3������:�� �.�^�'f�'�(f?'Eesfit�`"`",'`� Normal Depth 0.82 ft Flow Area 11.60 ft2 Wetted Perimeter 18.39 ft Top Width 18.22 ft Critical Depth 0.33 ft Critical Slope 0.02728 fUft Velocity 0.99 ft/s Velocity Head 0.02 ft Specific Energy 0.84 ft Froude Number 0.22 Flow Type Subcritical } f� >g-- � i�� ��� "����''���x��` a�•�+tax�" i�c�°�.� ��u'n , �� vxs�".� ���; „'Y`- "xas .. •s�� �f Downstream Depth 0.00 ft Length 0.00 It Number Of Steps 0 F.ir.,.�Ti���.� T�`/3i �"'� t.�C_, �� ����.'na,._".f.C'i�"�T� .d*. 3Ct.� ... _��€•'.�'.t�Y� �aSZ1�r�.�, fi�- '� s Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity fis Normal Depth 0.82 ft Critical Depth 0.33 ft Channel Slope 0.00100 ftfft Critical Slope 0.02728 fUft Bentley Systems,Inc. Hassled Methods Solution Center Bentley FlowMaster [08.01.066.001 10116/2007 3:46:25 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 1 North General Aviation Development Grassed Swale - 2 �1`�'"'��<� .�5k}a�7tnFr'"�w�����¢>�' 'k'3` "�^�'7. ��i�D,?';'tX7;,��'�F. g" ;����'.• a� 'T '. i:^ar�it .s� 'nt'a 'shfa� til �w3 Friction Method Manning Formula Solve For Normal Depth A ! 3��Z���y �3e''� e '>�Y�i+. r�`���� 1:.�7.:L3:si� ��� ��•i.+�:.t '�'v� � Il .��� ���� fl g< •!r.<� �. an •.<, ..�e!n.r.,,a....sw'.�.W.:S4)(£{. S..N+. iSSSS°�?...44 � � ;..�.{ � Tii.T1;aiT .....s .t .1.iR A!w.:.<.< � .e �•t L�1';`,�`•Y Roughness Coefficient 0.035 Channel Slope 0.00100 f ift Left Side Slope 5.00 ft/ft(H:V) Right Side Slope 5.00 ft/ft(H:V) Bottom Width 28.00 ft Discharge 23.00 fN/s (•}R���- t�y¢¢�. f y� .��;�tk w L�'4f �t�'S'li�'�'T'�"rw$���1trA '� "�,3 '�yi^ k �Q� T �' '�x '�'2' :N k."�ri:pj. �;"' "�, ,f•-a F• �'+� ✓i t1�5£ir� �� r'"Y,s C��:� a'�t - �'t ��(rY��S���.'hi{54,������f i�"la�;h��'�5�:���W� .:u.*p*F�II Normal Depth 0.72 ft Flow Area 22.90 ft' Wetted Perimeter 35.39 ft Top Width 35.24 ft Critical Depth 0.27 ft Critical Slope 0.02806 ft/ft Velocity 1.00 ft/s Velocity Head 0.02 ft Specific Energy 0.74 ft Froude Number 0.22 Flow Type Subcritical � "'8 ,?�� '} `��������� � �Si�rr:• �t t iTC A?&�r�� p r >,> ST` art:.^. _ �ttW;�? zb'"k�� Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 IN 42NEWi119? x Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 It Downstream Velocity Infinity fUs Upstream Velocity Infinity ft/s Normal Depth 0.72 ft Critical Depth 0.27 ft Channel Slope 0.00100 fUft Critical Slope 0.02806 fVft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FtowMaster (08.01.066.001 10116/2007 3:46:00 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 1 North General Aviation Development Grassed Swale - 3 �'x i%.$�tq it "��s4M1 ..f :Y•• ;N: 4}'•��Y.�2h'Fr�� �fi��� );i"'Yv tit 'S »•�.P':.5,} 'S )YF•7 Friction Method Manning Formula Solve For Normal Depth �F.+,:rTii.,..:C.'Ff�:• ,twiA�' ?"d,`"•<w�;f'rkti' e!.,ar.. w'• ,v>.'L• yV'il:��,Y�'1:.:.isi.:'ak. +ix:. :af. ".. .4rQ R '.t,a �;7. c.:tv::,..:sa;e:f1;;'f rg�,i^ (�,,j `{ f f# �ly��y,���itF+�� rya +C� yY fyD� .�,{{pc'�4`` t +7jX,,'b ��tp¢' Sryy7 F� fit•� ° �s 7 �'� * h(J.t��'''� �yF k'�yy.%` ^E;•-� r3 :WA.�x f5 l�..lief`f.''rty5'.LY?3.�AeLCiF .itaA�. F,7.Cf' >`A:f' �.L3:Pe.�i, � n7��)•7 "aitS: i w�+�a „5 �y.�. '"o` F}if>±'ASe';;;3 Roughness Coefficient 0.035 Channel Slope 0.00100 ft/ft Left Side Slope 5.00 ft/ft(H:V) Right Side Slope 5.00 ft/ft(H:V) Bottom Width 28.00 ft Discharge 23.49 fN/s s� l':i�.^>^> .zfs:` k :. x'. N x. ;k:e• v' xoa InE4 �T.�jfA`yL$sg�g� 9 � 5 a05 t"15 *�� '.. '. $ .� '1 L;u'. _ svt a x s s::x -...a fi a, u: :f�....•i s• tf..riA Normal Depth 0.73 ft Flow Area 23.22 ft2 Wetted Perimeter 35.48 ft Top Width 35.33 ft Critical Depth 0.28 ft Critical Slope 0.02794 ft/ft Velocity 1.01 ft/s Velocity Head 0.02 ft Specific Energy 0.75 It Froude Number 0.22 Flow Type Subcritical � 4,'i'8i ! RW.: A'"ni _ Q' j; :.,9�.�fib )- 'J• �� 5� ' �.. 4�� �i��E�4���XFyS.-.,. �u ,: �� :T4Ry�;7��161.2k��� .R . 'zsF ''�.•'¢A���.:..}a�'kl��Sf.'a��3..Y,y1'�.. .wF �S:h:s Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0p � i?„�..`�`.���.'.'�111.��'z���h'+y� 'l p[^�`�Y�S�'FFE,E1t ir�.�'S..x.�b���T�"�•���4"1t� tC �•,�s,.�r�••. �;' y 1<. �•� Upstream Depth 0.00 ft Profile Description Profile Headless 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 0.73 ft Critical Depth 0.28 ft Channel Slope 0.00100 fUft Critical Slope 0.02794 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FtowMaster 108.01.066.001 1011612007 3:46:22 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 1 North General Aviation Development Grassed Swale - 4 �,.j..y.t P Kie a• r a SST< .as '" ," 4 '"r3. o.< �,�y� .a a Friction Method Manning Formula Solve For Normal ormal Depth MINN., \th MIg�5 5+9 4...... 4k3wi:'A�"Q,� Ja.. V Ylti� \� 'R..�r.t✓..f<, � � 3 Roughness Coefficient 0.035 Channel Slope 0.00100 ft/ft Left Side Slope 5.00 ft/ft(H:V) Right Side Slope 5.00 ft/ft(H:V) Bottom Width 28.00 ft Discharge 23.49 ft9/s < ��; �r •� ��s z- ,<� .a \"yuY•75 ." �.1.Eu�.+�i•. Ai<i � 28'.K , ..S: a:i'v.�ylnPiN�.:kiY�C•.. 6 ':. .'G :u+ SA Normal Depth 0.73 ft Flow Area 23.22 ftz Wetted Perimeter 35.48 ft Top Width 36.33 ft Critical Depth 0.28 ft Critical Slope 0.02794 ft/ft Velocity 1.01 ft/s Velocity Head 0.02 ft Specific Energy 0.75 ft Froude Number 0•22 Flow Type Subcritical OM - EROSION Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 fFk,,1•Sx1' '"Q.n �• a'e �g � .E�ao-c ''eq�y, i K � M $� r�� Pl�if/'.2�A1 fi .il�a:��f .. • ������.vS. .f �1�� �13��iJ.Y~z $ s�1'���� Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ftfs Normal Depth 0.73 ft Critical Depth 0.28 ft Channel Slope 0.00100 ft/ft Critical Slope 0.02794 ft/ft Bentley Systems,Inc. Hassled Methods Solution Center Bentley FtowMaster 108.01.066.001 10/16/2007 3:46:"PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-785.1666 Page 1.of 1 North General Aviation Development Grassed Swale - 5_ 'y�gg �. .i..01 ..•,jt j. « Friction Method Manning Formula Solve For Normal Depth :*�J1 y:> #' ix. ,:.Y.:, .. „' '.'i �.' _•`F.;, :,f<ar_ .` ..`:�; ',Rf3'-" 1-0.. 1:9..�.J���'ti��.��R��::Sk 4!1.3,����G�.i�.'��.��w�`;•'N'�:CFIi,Q�Sk�'�'N":3 34f',....� �fAS�ti�.f� g�.:��if.a>VsY�.vN{'_._b �":5:.�3iX.*�>fr.,.>?fk�wi�,k��y K%ncf. Roughness Coefficient 0.035 Channel Slope 0.00100 ftfft Left Side Slope 5.00 ft/ft(H:V) Right Side Slope 5.00 ft/ft(H:V) Bottom Width 10.00 ft Discharge 11.90 ft'/s �S�a��.� x. . •,'���y'C„� L7�f ,a � J S i��' �� y� �Y�. �*L���f 'Y+' + ,� e 3 k. '��.t�t � Normal Depth 0.84 ft Flow Area 11.91 ftz Wetted Perimeter 18.55 ft Top Width 18.39 ft Critical Depth 0.33 ft Critical Slope 0.02710 ft/ft Velocity 1.00 ft/s Velocity Head 0.02 ft Specific Energy 0.85 ft Froude Number 0.22 Flow Type Subcritical 7; ... Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps .0 6• i'�` ^x, � -�� 111610, v .r.. .g ., �, .,�,,, '8. .Yi"rSFir rtY�. .6. it� •it Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity fVs Upstream Velocity Infinity fVs Normal Depth 0.84 it Critical Depth 0.33 ft Channel Slope 0.00100 ft/ft Critical Slope 0.02710 fift Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [00.01.066.001 10/1612007 3,46:59 PM 27 Slemons Company Drive Suits 200 W Watertown,CT 06796 USA +1.203-7554666 Page 1 of 1 North General Aviation Development Grassed Swale - 6 ���i Frrtn'r��a .� 1 vu� t "�.. (� { �:j '�i .Itx �kai�'�y� •'�i�"53'#�. � .• '��+r , ��Ss�������X�d%�✓� 9Xt�.R' .��:: �tv�����i��'� 7a'�'xi$.�4 r e�ri7's a.Ts+L�..ts4. :4.v �:.',��• "i- Friction Method Manning Formula Solve For Normal Depth ✓.�p�ar., �;•}ry .•,S'r'yYr ?M 'KP �.�•`{i��'.iY :r, i:l,:£ZTL: �•:fi.� ::ke ,.�` u7sw:fyr "P iiHf)y�•. '+-ilrxry.. . {'1 �� �, � �� !n� vAw%' �L�lt t?r' ne y�r ��°?"•�"�S4 ,ski..fp �isY� ,ge;a y��r.; - i�..t Roughness Coefficient 0.035 Channel Slope 0.00100 ft/ft Left Side Slope 5.00 ft/ft(H:V) Right Side Slope 5.00 ft/ft(H:V) Bottom Width 44.00 ft Discharge 32.70 ft'/s i x Ar :'Y;«i"'.... ,f... ..yr.=. .�. .,'y{�33':.wA a'e Y•Y •s:YS'.•!'°`�..'s s. •.i.+7 '":C�j, F. ..Xi'.A;w•.. .7N' !e.::;',.:s. E+w.•. ra=s�' A�'. xA ;'� .�«'•.Eac:?:sa �i�F '..' `�` �`�s''�_.�"9a`E'._ .• tics' Normal Depth 0.69 ft Flow Area 32.73 ft' Wetted Perimeter 51.04 ft Top Width 60.90 ft Critical Depth 0.25 ft Critical Slope 0.02844 ftlft Velocity 1.00 ftls Velocity Head 0.02 ft Specific Energy 0.71 ft Froude Number 0.22 jFllow Type Subcritical s .tk111"RONNIE e.�tl3:'• - .�` ..z! '�t'3�£°�'x»:ts7 °��'i'F.sTs�'��' fi+z� Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 _.`:� .r....yy,., '.aft �1iK:> ��•^r �fC• xy ,} Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft!s Upstream Velocity Infinity ftls Normal Depth 0.69 ft Critical Depth 0.26 ft Channel Slope 0.00100 fttft Critical Slope 0.02844 Rift Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMastsr [08.01.066.00) 10/16/2007 3:47:20 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1.203-755.1666 Page 1 of 1 North Genera! Aviation Development Grassed Swale - 7 Friction Method Manning Formula Solve For Normal Depth s. Roughness Coefficient 0,035 Channel Slope 0.00100 flirt Left Side Slope 5.00 tUff(H:V) Right Side Slope 5.00 ft/ft(H:V) Bottom Width 2.00 ft Discharge 6.09 fts/s r e Normal Depth 0.97 ft Flow Area 6.68 ft2 Wetted Perimeter 11.92 ft Top Width 11.73 ft Critical Depth 0.46 ft Critical Slope 0.02720 ft(ft Velocity 0.91 ft/S Velocity Head 0.01 ft Specific Energy 0.99 ft Froude Number 0.21 Flow Type Subcritical NOVEMBER AII-'l7i;l Downstream Depth 0.00 ft Length 0.00 It Number Of Steps 0 Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ftis Upstream Velocity Infinity ft/s Normal Depth 0.97 ft Critical Depth 0.46 ft Channel Slope 0.00100 ft/ft Critical Slope 0.02720 fifft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 1011612007 3:47:32 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 1 North General Aviation Development Trapezoidal Channel - 8 'li 2. Feria?c���^� ������t����'��uxx:Sw•r 'i�x<`n n3'8���v�'���1't��i °.��,�.:stC, n����: s � t .ask$"- �••.�r«�i'•.�C�u.J.1�t��i4 r.0 �J„ •,� .'M_ ��r a a tf' �1�.``_. ?�.- '.i •K•> Friction Method Manning Formula Solve For Normal Depth {�;�"�)•-Tr @> :3i:•;tar�..?:�ti,;..: ..v.&i.c .>.'�i.rk':°>S5t52t: 1$:, ..tx�,§�F7;ke,�.'st�,z:? .�3x• t'CFz.;' ?:"? ,a�.;:k'iz3 [„ � t+z�i�^•"'En. Roughness Coefficient 0.041 Channel Slope 0.09200 ft/ft Left Side Slope 3.00 ft/ft(H:V) Right Side Slope 3.00 ft/ft(H:V) Bottom Width 8.00 ft Discharge 29.90 ft'/s .���� 3:y •tL�k n 'f�y�;�. �x•l,'� y� hry. _ "2`tT �`�. y � ,t�.��..., . # k. `. �r> ...`S4. ,�it�R;# «�;�t;'r���«n�c"�'z•�ic"�h"£+�;��a��,`i`�"' .;�x .�;u�'�Fs. r��n���� � �tr�.ea:-.�3�?'ak+�'..t,�t�.`ii�:� a�� ��F�i�rx�i��.'u���.���i�n� Normal Depth 0.50 ft Flow Area 4.79 ft2 Wetted Perimeter 11.18 ft Top Width 11.02 ft Critical Depth 0.69 ft Critical Slope 0.03022 ft/ft Velocity 6.25 ft/S Velocity Head 0.61 ft Specific Energy 1.11 ft Froude Number 1.67 Flow Type - Supercritical Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 t�� vs�� � �, �rf �u, fitr�x�'� � r• l� ?•xs,�a� *�; ,:ext �f' `3^, '� •�, ,Y�. �;r� .t�CY£R�4'� atm�• ,_�o�t.�a�fy�,f�'1F��� �'iw' .��9.x�'wxx�'�t ?.4 .. ;tom .• .. 4 �i ��a Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity Ws Upstream Velocity infinity ftis Normal Depth 0.60 ft Critical Depth 0.69 ft Channel Slope 0.09200 f ift Critical Slope 0.03022 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 10/1612007 3.47:47 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-766-1666 Page 1 of 1 North General Aviation Development Trapezoidal Channel - 9 is t,..,_.ry,Y'wr rwx .�,. �.^e��;y "Ys�;- K^� crr��R�.�r�.,x .;�.gk• .• •�e.:...�'"4`sE`,s�� r "Aa x;-.,,.x.�. �� ��.���������`#Ta��w�-2�•�z',q¢� s��rK�r'�"s�1�(�t',k`,�i •T�t Itr �'bp �� +; �. t, ��� Y Friction Method Manning Formula Solve For Normal Depth NMI, w+i '`i�5t .xl`m R� °Jx�Eb .� 'S'Sx}�&�'t� e'xhG?^�$G�?r".xiXl r � i"` 4,/�' ^D��'. ;•%.n#"a;..S' �,r� �;...., y�o g"` y` �,afS.d3nliiR`t ,'aEtaF' .f.. i.ts.xa} »?`r>c.;a��r,TFi,:.Ycf.M'4s �4�a .X�:,:,': •r� S L l Roughness Coefficient 0.041 Channel Slope 0,05800 ft/ft Left Side Slope 3.00 ft/ft(H:V) Right Side Slope 3.00 fttft(H:V) Bottom Width 8.00 ft Discharge 34.84 ft'/s +•• ��:�' �?,'�il';j�zxx� .F3p-4�,.� ''%sy��Y„��3''�it k�aa__�'?"a{�4'; "•54 Y� M -ss}'ii ,�+ g' r. ''i.'� ,'�..',�„ .r:.. xrr.; �xs;-x {.:bnt�� � ,S.'"S'ea w �.#r 3:1..et.�:..�fw.a��tr. a6.a.:. ..0., rt..e'a, t.aL.+au � .. ,'�ii1•A.. u.`th Normal Depth 0.63 it Flow Area 6.19 ft' Wetted Perimeter 11.96 It Top Width 11.76 ft Critical Depth 0.76 ft Critical Slope 0.02947 fUft Velocity 5.63 fUs Velocity Head 0.49 ft Specific Energy 1.12 ft Froude Number 1.37 Flow Type Supercritical jr'..a' tY�.I /►,.(S-' .'+{7 fyyt( 5 f��*�"ik�x� `#WIT-- }:.r,�, x a:A` ...'� .. .. sEk .N In Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 g_..%#` .�_It }7���� tiA�'?`x' '��'^`� tx;-U'"3 c+,"'• n'^ Y Y,K�:y .+7r�:� •y va�, nv � „'L,Ly�.ex �av;y>, a. �r� r'v�"tc�"9�`•t!'�t'w����`�� .������&3t';�� £�.✓.:Ss��.�... .�.ss'ti�. .• ,w'c.. a.: .. �'fr �,:t.. .. �° s?:,,,.��5�����.�.�, Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity fUs Upstream Velocity Infinity fUs Normal Depth 0.63 ft Critical Depth 0.76 it Channel Slope 0.05800 ft/ft Critical Slope 0.02947 fUft Bentley Systems,Inc. Hassled Methods Solution Center Bentley FlowMaster 108.01.066.001 10116/2007 3:47:58 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 1 North General Aviation Development Grassed Swale - 10 01 _[p�3 {,��a,� .til .ir '' .p :,l�,Y'.z`y,�,'.A,X �.x# $w '`�` '�'. � � .�"t`3 � dEitLR.L� k !-d �,"�.�e.�• 9R,�'>0�� Wf`11� ' .!sa^' zyi;' s.u,�21 �^ yrJ. � u' .! �� a: --��;y�1 �...1 ;�3Si' .Y'S:tnic�' M.•P!N �n¢.n' ���11�Y..2r..:�•. Friction Method Manning Formula Solve For Normal Depth ���� 4�. ���e•?�;���� >a �'lr�i�' hfr r` 1�� f'�I�y��a 1�n`}w� `��Fk F9�'S,4,�"`�Y�.x�,''DES•. � i�>j>'� f S;i �,�� z � ��`�'?'�„ ti s,s,a —,. ..ze.:P>.. >.er.s<...,.S;,q""...d.r2�r.5 S.ta..... .,.,. s,.a..Y:a.`c�;..�.,fir..s"•,�5'� .�a+"'.:Buww:J�a'tY.2.L.'h:,�ha.let,.�c..xt�.3�.w�4Is.�Fxwka:�s.0 Roughness Coefficient 0.035 Channel Slope 0.00600 ft/ft Left Side Slope 6.00 ft/ft(H:V) Right Side Slope 5,00 Rift(H:V) Bottom Width 14.00 ft Discharge 2.84 it'/S q nr"� G' �.;.�Y`� ty—y :`� a `t'.�?:.X?"�*i"'�*e'`> i'zE?�yrv` `tC;- �¢.t a ^er {w •z�z�,- r �•:•��vvu" :tt1.�'. Z' 30 a z�+!��•!! t �'t�'� �� >u`Y `rv? i�; - .Je' �. '`¢'4. Normal Depth 0.20 ft Flow Area 2.93 ft2 Wetted Perimeter 16.00 ft Top Width 15.96 ft Critical Depth 0.11 ft Critical Slope 0.03812 ft/ft Velocity 0.97 ft/s Velocity Head 0.01 ft Specific Energy 0.21 ft Froude Number 0.40 Flow Type Subcriticalfi �bi � .. � .1.,.. .. .tt y'cP;�i��.,,,�'�J�•::iz1�4� u�� �r'>{t����`t�� �^:�x�•' .... Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 lY F t;;t$�j \ih d� +Y+`ti i ••'! -„Y f�yy{ 4. t r 4 7 Ei�':iC " wt�R��u��l::� ��.r!�3'�����[.�(�4`C..s.�'%� "�.. a��.Y�'aY' � �^• .S � .. tf Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ftls Upstream Velocity Infinity ft/s Normal Depth 0.20 ft Critical Depth 0.11 ft Channel Slope 0.00500 f ift Critical Slope 0.03812 fdit Bentley Systems,Inc. Haestad Methods Solution Center Bentley FtowMaster [08-01.066.001 10/1612007 3:48:13 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 1 North General Aviation Development Circular Pipe - 1 i * '�::�.a �„ :r..,x;..M •�, �-�rv,�h�. fix:,.''�?' �°yz �nt� t �3..�. As.�i' I �•3 `.a.•F�'u"r�'aw.'.1..'.d Y:w':x,.x.%ox'.w-1x+tE':. ak�,vx;'Sx�i�K.'1F..3:Yx Elm,- �•1.,•� .-1 09, "WOR.A::6`h���SFst.Tf." Friction Method Manning Formula Solve For Normal Depth It a{'�x""t'4{E�#�'#`K`�a�''� _ '�t�s7 u i� �" "� f'E<` b.�."'S.raa c acre,,�: �;k1 �, /k82�'d yy.:: scat'-•k; .� 1 r � Rj�€�f�+'` ♦�, t r h �' e���+q� �1:�V�a`"�'q�L���N�" �f y, �q , ?n � r�•(,-&�Y�.�'�;.fr�tv`�"i.�'..�.�.�; �S :s;� .'.c,.? ;'4�r,�.�.i�I,,'.rf�'kr"`e'v. .�iw s..'^'Vin e.n•'�.DvT.�4i`.a�.«Fr: ar ts.7:.:..R#k'�+' �}..7'ia�'3a�f, «.a;C•tf>r'so• f'c1t'ae Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 2.00 ft Discharge 7.30 fPls �w7 ���3�..�t�.���� aL�ia��.'aY'�Y�x�ia};��3�:.�V�.:Yv�V?y s:� � :;ti� � ... l�k•;s T i:x�'aV�,.dS.:;fi• -c �e. +i. �zT' Normal Depth 0.95 ft Flow Area 1.47 ftz Wetted Perimeter 3.04 ft Top Width 2.00 ft Critical Depth 0.96 ft Percent Full 47.4 % Critical Slope 0,00479 ft/ft Velocity 4.98 ft is Velocity Head 0.38 ft Specific Energy 1.33 ft Froude Number 1.02 Maximum Discharge 17.21 f sls Discharge Full 16.00 fris Slope Full 0.00104 ft/ft Flow Type SuperCritical �`�31��x�� .., zV"A.�'..'..:..�`i ,. ���.f�fw'z��C��a'�.?�� xFx•:Tx:'au ��t� .:T"�.a�a''•�a�'�� Sw:•£.k''���.w�'..�a. .d.,i fit �a. Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 Upstream Depth 0.00 ft Profile Description Profile Headioss 0.00 ft Average End Depth Over Rise 0.00 % Normal Depth Over Rise 47.40 % Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Bentley Systems,Inc. Haestad Methods Solution Center Bentley FtowMaster 108-01.066.001 10116/2007 3:46:30 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 2 _ North General Aviation Development Circular Pipe - 1 ���}j S Y siz,? 5t � s;s 1; ��?. t.U. s ? a..,# ON. ?ata,. *s :t Normal Depth 0.95 ft Critical Depth 0.96 ft Channel Slope 0.00500 ft!ft Critical Slope 0.00479 Wit Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 1011612007 3:48:30 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-7654666 Page 2 of 2 North General Aviation Development Circular Pipe - 2 Friction Method Manning Formula Solve For Normal Depth a ,'k yar ik�^ t 'r a�R r4y a(,Ci .fir �.K s L'�; 'LGE�%�'tNv.rye x. •v' i'�� Y�z'e<Rffi�r e='t.0-�`A��� -.t'*,tY3�,r+�"•S�4ii�s'";s. ,,5. �.< -i�l�'1x.r.<...,..�.er2lYti..�.i. E�i1.z..'m,�{x<l .,.,�e,.�:?+�?S�tY�z2,.ksc co ,<5.�?FX..r0>as .,n..x.' ��t.±t«ir3�.;da��`C.j.�.ti,+ft�.,'�1.,.a.�` !�?..<i..`7v..•...!zy,r� � Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 3.00 ft Discharge 10.26 ft'/s =;��+ p JAM):. tf.:a:w�v�>:y .Q.7liy!y R> _�.+{.-�j4!Pli ry'..:. 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Hassled Methods Solution Center Bentley FlowMaster 108.01.066.001 10/16/2007 3:48:41 AM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1.203-755.1666 Page 1 of 2 North General Aviation Development Circular Pipe - 2 ",�x.3.,2jS'J. g.} �x HEN 17Y> afdu;Yst;Fl 1.�1�E,.:.. ` '6w`aau{.:� r.'rsi '6H x•of .ate•s" 'z'I-.' �:' :i�a4 Normal Depth 0.95 ft Critical Depth 1.01 ft Channel Slope 0.00500 fttft Critical Slope 0.00391 fUft Bentley Systems,Inc. Hassled Methods Solution Canter Bentley FlowMaster [08.01.066.001 10/16/2007 3:48:41 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 96795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 3-1 t Pe";+.t��� -�'��2q� �J •1 � � •.: {ate�A `. / A�.�4 n l�.. t Y �� � J' ;• M4�1.1h; ""° k t`� ,c,.a cam.,, z :�;'�a'1 �.:. ..n...����k�5a; .., .ra.�' ',3a.:� •�.:�. ., ,.. 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Haestad Methods Solution Center Bentley FlowMaster [08.01.068.00] 10/1612007 3:49:50 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 3-1 Normal Depth 0.68 ft Critical Depth 0.67 ft Channel Slope 0.00600 f ift Critical Slope 0.00517 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FtowMaster 108.01.066.001 1011 8120 07 3:48:50 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-765-1666 Page 2 of 2 �{{ggg3� North General Aviation Development Circular Pipe - 3-2 {i �'#�'0 'f h ° ° .� }� >,k#> F y '�t #;.>l� sfii�r�»k# S;'>, cY^«1110 , ��f>� �� a L, x1. E.'..I,°_"e.6r I t��6S r�i i�"43$vi..��aL,.� ���.x��R�...a'l'sTE Ott"'S.. 'fee. �+�;t�s�.t�L&��u -ate...-.ems ,.�'r?J•fd.'},`fl+�Ta aLY.ci'�E�wiRXl�Ra��. `.. ua .. Friction Method Manning Formula Solve For Normal Depth ,a..�� Ct Y S :'.y?;s `�f;'rvr:x<,� .rt;w .s�i? 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Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10/1612007 3:48:59 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 3--3 �Z.Y.����`'•A�...,�w�.��.1.. .� u.aFV�.a�'�wL����f�.`.S`�A. .�Y:_'� � 'a.-�3f.F`.`i-p??5,.'���'�i;�w{y�.w�.'`�.f.���.�,..n��k �,...i '�' Friction Method Manning Formula Solve For Normal Depth .f :+a,!'.:1'i3'd=.':��..r x w.�•.+..�Xb'�� .r�•i'n`t`nr"„'r.�;!,ro��.�,�:�:'••;<,;t a;�oA. ..r:; fS 2zi` '.Y:.<<2:•• ''z:^.v--•ut;�... $;is'3�%... - �.h �i,{;�,..:`a�iq�- •^.�a,`� ��a 1�� � x.�'Y.�" El.d+ l �Y' -g .t;Z� .`� # �•"'lTtdi#''r�jyf ♦�� ' v' t �. e � Yi4�x. �ss�i'`t' b'Yju T+i3��(�i'�.h n :'�Se �vm�Sa �w7;'x'a�w,s�'+ ^ n� { Y f ���'<3 ����?...«lY ����,`.l���i�li?�.h���f�.�E�.fR��s�k'+'.. �i#.�n s�:•.j��fJ :� Cf�Fs��R .�f..�..`+'I.�.�.Y•�r4 F.�4 �t2y� tt Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 2.00 ft Discharge 14.63 ft'/s 01, -�t'gytits�'''"4:•'a°..'.Y<i'4".:' ,':t�< �ii•k,•ia'.<`"x;;,r,�w•:.Trr�•,�tae*�:.iga:' �.'�'T:' i3l"�:<`'3,'`�`j'�t�:+;e ?::q"xellG,:i.,x.i;nx' C' `�:"':4 k& A�3:13v'`�.11 y{uYt•''i:!&`".�as..� a .;'.•x -r acH.✓a_.vR.'iS•h�`R" .r.H '4'...uzi,C{:y!er.Ph,..d 'Normal Depth 1.50 ft Flow Area 2.53 ft' Wetted Perimeter 4.20 ft Top Width 1.73 ft Critical Depth 1.38 ft Percent Full 75.2 % Critical Slope 0.00622 ft/ft Velocity 5.77 ft/s Velocity Head 0.52 ft Specific Energy 2.02 ft Froude Number 0.84 Maximum Discharge 17.21 ft'Is Discharge Full 16.00 ft'!s Slope Full 0.00418 ftlft Flow Type SubCritical .. {i.SwSS\� 9r;.ttk .. 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Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10/16/2007 3:49:10 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 08795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 5-1 ell k."":r .xR+'�?�w'<�w.�.� r(e 73y b a` I 4x)(.�l£ r •? � ) `ate' i�"'.ti 4 3 z� Ci,l .�:i-'•iU1 tL'.'VvuiGQ- ) x.. ..'�... :', `9&2� �.:`'.':.I-. _$ ..i.[`� tSv'� i�.x �i.�.:'Sg: Friction Method Manning Formula Solve For Normal Depth 14..p. 9 1 3: ) µ tl'YN,• n4 )j,->`c f,{!r; 1. 54 G M:" ;+�, �•i'�','p`�1�..a��;�`'�5 .< �{,�'��xSuk�a n�,��,r°i��n��€r � z�r^� �r���"r`s+ �i`"�'i� k,t'��{"��rL s•cS�F-P� �k'43.,��•,r t'� 4'"j� 3;�'� �;%�.�'t'��`+�r� •t14011! t �..:r.. Roughness Coefficient 0.013 Channel Slope 0.00600 fuft Diameter 2.00 ft Discharge 7.10 ft'is �a3yg r •r�:. <.. ..^i<i'i"'•, f..x->^sx »�-e+:�Ywl..- t':;:�E1•: J"•" t"', yrefif,'` .+` >a ' '�z3.w�: it4 4.!) q'4 ;xt .�( k�S',�I ..i u4'sa... 0 H�,.i "' :•d�.''iA '>2 � c � ."£". 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Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10/16/2007 3:49:18 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-756-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 5-1 ..' #: rat• r@� Uar.3 5? s 5� R y t, g ppw w3 a s 1S s� �.rr Q t 1.+ " � � y � 3 a <X 3 ' Mu51�ik��`��4 �1 is v��v v.u.ana�'.�a. ko�'a' i.c�Y �.3n Rp .1ra' � �i1 s.\.�y'�,an�#i Y1! 1 a c s r k4. '.3� r+i s<. .. .�`Lz... X ;fat Normal Depth 0.93 ft Critical Depth 0.96 ft Channel Slope 0.00500 ft/ft Critical Slope 0.00477 ftift Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 1011612007 3:49,18 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755.1666 Page 2 of 2 North General Aviation Development Circular Pipe - 5-2 Volvo "�r �p;��'. � "�'•« .,. 33'` �Y 'r "'"7� �r} qm'' s �r� 235�,-'> ?x ,hrc c{>} r. ,� k�"�.$'''�s. 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Haestad Methods Solution Center Bentley FlowMaater 108.01.068.001 10/16/2007 3:49:46 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-7554666 Page 1 of 2 North General Aviation Development Circular Pipe - 5-4 y%.:G7 .,»S:,�..')S!1 '�:Y� h•„:..,.a;.e,.�...:.�,y �� � -:E'-�• (�+, Nn .fib:,.:,..•,.rc� y.�,:�m ts� �,. ���'c3�, U � INNSM.?�v..i7?l .';..•l�in1L"? ":e,3Slpv�fmziia5�f9,�... .+ Ks:R:'fix:efa34:!4rv.�iiCa`,:r!tel*s4'.9F'k1'*.z+ ..ra-.n•Bsesr,,.,zxcx ,...ems i 3Ys.'�6• Normal Depth 0.92 ft Critical Depth 0.93 It Channel Slope 0.00500 fUft Critical Slope 0.00474 fUft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 10/1612007 3:49.46 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 5-5 -',,-�,.;:� ���. ry: w:e -ifir,, ..�sr art.•. tNre. . _� ,�.. - g' sFa�.`,,� `fie �;h.'",�".%w.` ' ^xi k•7�' 'ri.Y' ,,.•rL`�SS'M .ik!'h� "Y' r, .' i* "?!yx�lr��. .� �4{iY [� �? s. t� .d .a.i"'v3 w i; <c 4 4i•,i...:�'3 _�i: ���. •.� `�'YE.;kk,.X....� x ;.v�.Yl���� Friction Method Manning Formula Solve For Normal Depth O � "x'D �s.i i.:£t�3k+? ;;ai;Fr"'t S•:'s)',�:�; h:✓t, <t;4$.s ti7;c.�;x.��'� ;ya: ,:,�s.0'.tt�r±}.�,,.:�_.�$'�.. ... °e s' s�.'F _"''�,„y�`.� 'F'"6a ct�Y:`� 4�9'"' '��'.,k"fio t..;' tw t��''�?,a n Ek �� ..c�.x,�?i}.iY`, .usq. t,�'ah' .. , �. ��-T �S £ -x t,x•�nr ' M e�.�s,1 T:;R;r s.. t,�.. �i,��# ).rt��,s.���€u�Z�����i i'�� l��h�wka i,".�^Q::�3:5:,S a.,..$«:.p•k:: li.�•`Tk�ta. 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Hasstad Methods Solution Center Bentley PlowMaster [08.01.066.001 10A612007 3:49:58 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1.203.755-1666 Page 2 of 2 North General Aviation Development Barrel 1 ^x? �'�+5-_ ..�•Y 1"�i 'zs._ ,.�, xii:^iy;vr. �����F Lrr \i 3 ri°{5" � i 9 ,CS A M ii3:.µ�Sal.'.'Y'k87w. _SP :5&!:t> %Lw tSr32 •a,r.S y '�`w.P ai..S3'C..S, x cti. R.n a> v Friction Method Manning Formula Solve For Normal Depth .� ,,,. ..��•; .?'�'-.';� ?st�,r »�.....,�.., �,, .:�eH. �;.-,y... ..z� •yn"• cos-.3N.T'�����i, x�> '�{:>w;3,:Krr;�..�:: ^yyi-'i`� �'�� 11 �� ,�+�t �r ; +� �?��Ts' L �7Lk� 3•..r. e � 'rsfi� z:' .�'c,,,��,fRi <� "� '�' 1 ,, 3,�Y 1' 4� +�k�r i :�s�'iJ`ta fS�+� �'u�jaS � {5�`^�S^a 7�s4�wsZ gym,;t Y.,° ,�)`k ,fig .z*•.:n�i���K:.�v a'� r`. ,r�'�u�.'.v Li��'z:.d':��a 1..•��..'�k��;;^ n,>....:�..,cM_z>. ...,�Y.d;.�.�`..s _a.:�v..:Ft..,...a<..� x.r....,,..=<x.._....3..>. ..t._?;'+�Y •.z..,.!I�z S�h._ >.a.,z :, ... 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Rk x:+. e••.[ 'aF';M' �.xX�"c Yiv .c Normal Depth 0.69 ft Flow Area 1.24 ft2 Wetted Perimeter 3.01 ft Top Width 2.63 ft Critical Depth 1.10 ft Percent Full 23.2 % Critical Slope 0.00393 ft/ft Velocity 9.69 ft/s Velocity Head 1.43 ft Specific Energy 2.13 ft Froude Number 2.42 Maximum Discharge 108.81 ft'/s Discharge Full 101.15 WIs Slope Full 0.00032 ft/ft Flow Type SuperCritical a•Y•aca r r fir,' i"�,-,`h �'• `i�t'.'� t� .e gt�. iti i YS. • � y %• MIN �..y-/ kxrl.......[LA:•.0 ... ?.A�' Y�R!gpvirs"`-'•.fix. 2a '.�32. iu; < w fY Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Average End Depth Over Rise 0.00 % Normal Depth Over Rise 23.16 % Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Bentley Systems,Inc. Haestad Methods Solution Center Bentley Flowmaster 108.01.066.001 10/18/2007 3:50:08 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA 0-203-755-1666 Page 1 of 2 North General Aviation Development Barrel 1 { tx,� z :.tip rt "roP; i to Y y�g> a nvxk^Z 7yg x��v P ✓t' a ea.�-� �i..>r'��,�, .>�� " � FJ�..A��`:�°.'u4: �.���1�3.�x;1�,�;i�y� ��4.� ;t.�'�`� 1.si .a���� •,. �' �..«. ���{�...x'��. �ri1 Normal Depth 0.69 ft Critical Depth 1.10 ft Channel Slope 0.02300 fVft Critical Slope 0.00393 ft/ft Bentley Systems,Inc. Hasstad Methods Solution Center Bentley FlowMaster (08.01.066.001 10/16/2007 3:50:08 PM 27 Wemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-756-1066 Page 2 of 2 North General Aviation Development Circular Pipe - 8-1 k?•?oayu?gJ?: •?[a. - j .?: fx' x. ?;y' ?,3?.'..;,r cr ?.;a ,;?sf .?.,+???.".?." _: •.y?g?: c.a;,N-r< ??L?>ra? .. G4. Friction Method Manning Formula Solve For Normal Depth t '? ...:.., .. -...., . ?:..'Ea ..fie ? -. ...g:. rv .:.?:., , :t?( .,;s?z,..,,F, : es• ;fv ' El• ec .'?'St •z;K? . ys a ?:?j. ,?Z _ . •Y . tt6.g . r?^x¢a•..,?.Ex:??.v . N +!S ? ? ?, rt 9 ? ? t z?rt`?• 4i JiE' "t',.. r ? i'a.1' ? ? rk ?? a c ?•' r?? ?{''• ?' ' F v:, a ,? 4?n?.??•e::_..?cx?a. ? ?ii.?..`?zs?.>.?f.? ? ?a.«.h. E.:.a.:.:?`?z?..?.?<e1E?. Sas;lf?..»..,.. aY"? .s ?'t :. Ear s*??< a. ?.?E .:r.... E,,._ ,EU..: >w?E?. ?,. «x.'?.x Roughness Coefficient 0.013 Channel Slope 0.00600 ft/ft Diameter 200 ft Discharge 7.10 fP/s MUMMIES r?g ?'Y:4+'''t'? :.`: ?:? - ',.?-,?s: ??'i`If ?nf,? n>n:n??$E3£.?i''...5' '•?' ?;;,4j7?, .s i ?,R,,.. ?"?-'r'E*'.5)? ..•.}? K???'i??{'?fY?. r?,'?w.i. .? 1. :{. ? e1$ LYrk,fss ? fi g:.....wrr1?S.:..? S:.i .E,aw:,•r. 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Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 1011612007 3:50:18 PM 27 Slemons Company Drive Su Ito 200 W Watertown, CT 06795 USA +1-203-755-1066 Page 1 of 2 North General Aviation Development Circular Pipe - 8-1 FyF ��t: 101,.' .rA :" �R 1M .. Normal Depth 0.93 ft Critical Depth 0.95 ft Channel Slope 0,00500 ft/ft Critical Slope 0.00477 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.068.001 10/le/2007 3:50:18 PM 27 Siemons Company drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-2 TIN ,., >b y. { ` " :asn>• ._ dv gw. .:.�ro,� yet.,. a ss .,i n x rr � � � +T � I,s a 6�N 041 M":,u+ r" ,.w�.i.. ....5 ..t� �i� ys. ..-h• .t a .:.Q•, - ...Y + .Y's .- 1rd..'.t; Friction Method Manning Formula Solve For Normal Depth �i' 3x z���°seta fix; a •"�k�"�$`i°x��lw�Sf,�L � s�}�;r �..&� ' r.' ��S .�'�'��" fir.as�KpYs'''�§a�•�`'�,.[�"�rP ?�••. ... 1'� �. �.��*�e �Y��'''�..�r� .e��.� t s�;�'"'r�ya 5 si�,s�j�� 5 3i�,v����. �`�����•� `'H'�yL?'1.n {¢s�.a''s�ft 4' .-V�'..a_.:ki� €�>.I.�+s� J.-??:...,,.L�� � x �•''�L N3iv.x. 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J. a� a ar. n F:W. >s .w r '.+ : 4w.7 : ar5a w Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 ��t.K i m7��i'�.��S�Mwd�'f6Qd7.•Xf7a#kJNi73b.S.4S"�7�i'Srifa^RR.S4w�''1°t�l�,tp ..� Y s' x���.w• .is'"�.s�" Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Average End Depth Over Rise 0.00 % Normal Depth Over Rise 25.28 % Downstream Velocity Infinity ft/s Upstream Velocity Infinity fUs Bentley Systems,Inc. Hassled Methods Solution Center Bentley FlowMaster 108.01.066.001 10116/2007 3:50:33 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1.203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 8-2 F,v«?!:•: - - -. A�..> ..raR,:.j ,�•c.•_ n-:7>;�,.:Prix�.�,s.v�:q �.�r�,rgF .t,�.�.,�. [�� �.•� ���'"`"�`��y� '�"..���.:� �"�''�3�$�.� ���,4�,��`t n^e"'�7�3 ��r,. t' t z�`, y�of M `a.M�..'h„ �ro�r�, L.0 <k?a:�:4x•. :�.:N U,iia: ��''��4'd .eli"L'k 5 3>..'� 7 �nixs. 4:d�1�6i»91���.. 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Naestad Methods Solution Center Bentley FlowMaster [08.01.066.001 10/16/2007 3:60:33 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-756-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-3 u ,. •..��,,,'r�,•l`1 ;,+>. ,�r'd,;,: :�g%v d'3 :<•.. 1,c:'Xa,r.,m�tt VIEW , r:. :t^,.,. mW1. 1 .�,x•; , 5•3.YTS.it .�v.. �"I�+Sv c£".t��w#' �.z `e,.•Z.s T3'. .`? `k I 9 rr x���~� i�a�». hr�A� ..�ht IN Friction Method Manning Formula Solve For Normal Depth -ran.• am' - nr�c «a ay,. ^sx ::cvt,.e :u:N.F3lnisn;;ki ,.y,..��iYc$'' S;: �y�fry.+.; .�;,r�%•r.;y-^scc�7!':<'xii3C•T'a 5'�v f( �5][¢ k�i.S'�".i3_� :z::'.z,��iklGd ''x._L143,9?�x;�,�:.>.��«? i K<:�taF,�''.,.,�.`k`.:.SY�Ki�Rio•!r^..������� ���' �'e�'di�?���� i,��-�ca�+r�.�..e"_a;.3�tr:.�.,?ti�St�+..:t"!� Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 2.00 ft Discharge 10.43 ft3/s Q `ti•A Y,C;1:.;G:y)'Ly:^st'fM1 'k xr a x•�,:3."an.'{ J' ^ixJ �<da rx�k. .k'r .if"�AP''•Aq...•xf'ff 4 ,h. P!'c WIN �+ i H,C+ $ate ti •^ � $ �T +"�$ y< �f ��F.Y.�j;E'*•a 'X5..�r� "r'G+�'C -iN �R s �-.�� ��!s�.aYir..3_t x�i.�d..<��k::.:�5� � �ta�3r.'33:;i.� 7 �i,Fx�vw iG�3a. �b Sartx+<:�l a.^��•Y'.Y� ar+Y 'i •y. 8z.16.i� "�eu,� d TO:F�.!:._ .?w. Normal Depth 1.18 ft Flow Area 1.92 ft' Wetted Perimeter 3.50 ft Top Width 1.97 ft Critical Depth 1.16 It Percent Full 58.9 % Critical Slope 0.00528 ft/ft Velocity 5.42 ft/s Velocity Head 0.46 ft Specific Energy 1.63 ft Froude Number - 0.97 Maximum Discharge 17.21 ft3/s Discharge Full 16.00 ft'/s Slope Full 0.00213 ft/ft Flow Type SubCritical pj�q�.;..xr��;.��.�.�• ' UP r .��"`�� Downstream Depth 0.00 It Length 0.00 ft Number Of Steps 0 `I/rxF is°p`< 4 l°tt .2- �kl t��.s"''.. ur' .s�+.s�l� .}Y�'i�•l:*.�a�' '.4...,yx i. � ;5>. : '". 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Hassled Methods Solution Center Bentley FlowMaster [08.01.066.001 1011612007 3:50:41 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06705 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-4 Friction Method Manning Formula Solve For Normal Depth _">.� '$.t£}• .2'. < 7 iYf. '•;�:r.: _.SF'. wrnaerE „-µ..y'df: �i.w�._ :•i?:..+rnyy ..+.r�..�iY.•yw.�S! aa?�ya`iv,'�'4�i: �r�.4"a"�Kr2y.,ti�.z�•?' }([�1�x. (,,�,{'.nl't.e..,.th+i,. '�i$:y � .{"�H.ci93i ����y�•,3''}�y�i3���st_i..��"�� `�.,.x`�.1� ,,�.�> e.<=. 1e r '`fntiTT�,:�... e•r�,.�y-(. ..� .�rQ�.,,.�di>� ��Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 2.00 ft Discharge 12.55 fV/s ����- .tr •. '•F"'" �7'=±ri lsP.:,.: r.6.,�,.. -n<"r ir-m• a r ..ru :� roc 1." y .v n.��i 1 iirr�,�y ?&��r s-.l.f d? :i'1"' `•',� :F�:P ',�•!=r.��°:>' 'Y °�>„.i"''�Y x �' "�"ih:�. 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Hasslad Methods Solution Canter Bentley FlowMaster 108.01.066.001 10/1612007 3:50:56 PM 27 Slemone Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 8-4 �br��+ k'tt� '.4j r fa'> .fw x,�++� ,,,. .x "�X -«, qya �t a •#.. �����, f����kf .. _�4`�`n�`i:.l�� n _ �..c' �'•-ex� •t�5h rr '1.�1:u)�`..a ����k�d279'�w.,'.52i'S2 ... � i�{is!S� . '.��:x1 ,d.£.f Normal Depth 1.33 ft Critical Depth 1.27 ft Channel Slope 0.00500 fllft Critical Slope 0.00570 fUft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster (08.01.066.00] 10/16/2007 3:50:56 PM 27$lemons Company Drive Suite 200 W Watertown,CT 06705 USA +1-203-7554666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-5 eu E a��" .r ..�...' K�x '�y�F + s� fi .>'abQ� �1 r _ 'ia i�.MINIM w.'� ..&��sri'.`•� Friction Method Manning Formula Solve For Normal Depth F S; :a••n;.s>C ':'"�F�c i �'S�' �H'4. 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Haestad Methods Solution Center Bentley FlowMaster 108.01.086.001 10/16/2007 3:51:07 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-6 aY•wts."n' ia,r- ,«x,N: .x �, ,. .+n •a..z-.�;,. .. V'♦ } qw� �� v��+j+G�M."S� �to� fiT'"Y' fR a�ain�'n�e3't;,'s+�t"1'i&�'s��Ji•.nt...>yF.t s!-t G�fs+,1.�'•c-.�sk?i,G i% �k]c'u�: ��nN�ein�..�, zd.�i�-i+`�iRk�L+"i,i�kr�Vsl f.NOW— n�Y ,.0}kr a' Friction Method Manning Formula Solve For Normal Depth �CFv' s�.,Sx�'�%'�>�.x���c���:'4r''�'.x?'�S�,�d:'^,s'3x�`,�����,���L.�::� s v.��.AA1�i�r�rr s �,�kii�.�u.�s.� •�.ts�;�15;��s,�`� e�:au�'�.�'�s..,..� ���( Roughness Coefficient 0,013 Channel Slope 0.00500 ft/ft Diameter 2.50 ft Discharge 18.25 fP/s M ' �3vs,•t: ,V... .��fc ^x.1.-':,� e. 1 •S w ,s ytr' .+@ m+���. w':x. 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Hassled Methods Solution Center Bentley FlowMaster 108.01.066.001 1011612007 3:51:16 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 8-6 a .ft�l f"caTr. .� ciYst6 ?. ��pit7'''`` y •_r`,r. ? td `nr. �i '�;#��. Normal Depth 1.44 ft Critical Depth 1.45 ft Channel Slope 0.00500 ft/ft Critical Slope 0.00490 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 1011612007 3:51:16 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-7 Friction Method Manning Formula Solve For Normal Depth �::;��, ^"�"'•Ri ;bx+i> ..:�eE .ar: z:n `ifs... _M1,:. �ctt:. ...,.,.�Y ::�,w: ..,,. .r�,;�. ..,fis. ,t',>w-r:+ ,t�.. ."c5 yy ( ��� � � f. 3x:�4�1•�t �¢��: �)X� � ts, �9��� !.�''a`3. ti'x , � ay,,.a�t �,us.�i�'�^ti�'Y'dc���,ric� Eib��... ;i fl.Mgc�'a8s .� �-'.S13R. ...�x!Cn.. `�. ..Ea?Ycal.�i�.^.,F..�.mi.x�.t.�:a...,..r3.;.�k�.•''�sY ..�,..-n.�>'s��,�tr : X,..w}Zic:{`�.-.`�f> CY.,z;�...c., a4ht �� Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 1.50 ft Discharge 2.92 ft3/s {,y � .Y�`yL-. .Y,:.�, r„ •Y:K. :f.£' tS.,,bx,`ci••^,([_c<',�� � �q�47'«�J,.`:, da•. .��.•:rr :,,�.�.: 1�>•af• ':.5•"n:'•..`: ;:'�-£r.,:•u'^-6, �Y _..��' .nl:.. �t'•� �Rzz.�4.�a.`.',`�w'x�"',r`�,'..,sxi:«.��',xi�a:� �` rF"� ���, ._... �.*^^!�. ^" s"�;,,� ,!• � 3Y 4>,« ..L,.n,t•. sic^e. k..,.� Cr'wn. !as ati Normal Depth 0.65 ft Flow Area 0.74 ft' Wetted Perimeter 2.16 ft Top Width 1.49 ft Critical Depth 0.65 ft Percent Full 43.6 Critical Slope 0.00511 ft/ft Velocity 3.95 ft/s Velocity Head 0.24 ft Specific Energy 0.90 It Froude Number 0.99 Maximum Discharge 7.99 fees Discharge Full 7.43 ft'/s Slope Full 0.00077 ft/ft Flow Type SubCritical S.��:. .Z ..tn' s% ..gym ,+s�y?�� .+» -vx ,.y,:' •• .,�. `c' �<<,,Y, I:. 1.� �: t. ` Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 � �• :. �,i�: t :-1'��s,. �� "`� Yale C ry�0 z' 'r- .y. 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Haestad Methods Solution Center Bentley PlowMaster [08.01.066.001 10N612007 3:61:26 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-765-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-8 f45:•.WwLxaS:G .w u' y n��i�T.1fSk t a,•�S Ab .A;.}l�p[#d'.�v'�u J �M�-07 W s:�kili'�1 .` Friction Method Manning Formula Solve For Normal Depth ''ru" W� :�53l. ::�;:%°'z,Y-" a,i��i�`"',`s+.t'fi••� {a:.,,`��si:Y:'.><<�.'�'�i•.-. �: <'3'�,•�y%`�"' :rr;� '�`�t:,s"yY�i.s�x c F4nrb. ;aq ,o:4�f�Liy' --r�::%i� { f�} F�y�' ��e,� .3'ro `�., t rJ'. � � ff'( �¢"" !.o1�b' � i 7"'r y3�ejr, .�' ���S '+i �#•s�Fx•S ;•Fn`f �i��17�'��,�. .� .�����"� 0•i s�zx�'t•�" .�'������',��jh'k'!SRs L�f�'i ai�z��� �� a�"�S3Tf fn �' � *7�<° iG�•8" t>Ai. x..� z>.;a�_kY ....�. ..k«....<.l.•'�.. -d?.x..,s.:�•. a3S....ka�•r�Se•.> ..'�....�a ros A�. Vic`;..n...zl...#�...��',tr. .ot<.s..`"sk....fi�..'.A ...,,.. 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Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 10116/2007 3:51:35 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1.203-755.1666 Page 1 of 2 North General Aviation Development Circular Ripe - 8-8 ..,.x,., fc.,,[;j.�)t,.y1rY::':/,i's'.itti?'xb'K. i.sa•-3��*'irn�:,;s�.-r ��n {,� {�±"wrf.M4 ' RE, . � Bj-t Ri1.S+3.«.�afaytx'iaG. $..7.£.+3til,r �.'$$e .�°x .ii�i7 lly ''� .:..�. :. Normal Depth 1.58 ft Critical Depth 1.56 ft Channel Slope 0.00600 ft/ft Critical Slope 0.00519 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster (08.01.066.001 10116/2007 3:51:36 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-9 i :z:�� -n• .�, '•�«�'pa. ±y��j:a raw.s;w„�r:� is�'rn,:ti%�;'4`y ;�'1"+��,: +sm' ,�,.s;::r'. :r< �,�,;•.. �,�•v,. e. 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Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10116/2007 3:51:43 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203.755-1606 Page 2 of 2 North General Aviation Development Circular Pipe - 8-10 ��' ieas4 �y� rtfF�"%.'�'!,?+�g•� 'F rY"� nt r z "+c^`•:`•:g• "gfYu<.' ' �s:z R MO. t... �.s Sr Friction Method Manning Formula Solve For Normal Depth 3' mj'�..E ."'a�.3%�:t�s��i��< >t��i cre`" $cr f �ri;,�;tL.,...�,fir Y Ek -uv r.+»+ �ursy,;:^ Y"S rye ♦ s�, ,tt �,a - . 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Haestad Methods Solution Center Bentley FlowMaster 106.01.066.001 10/1012007 3:51:61 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-12 �F�1161 Friction Method Manning Formula Solve For Normal Depth n ^yr• au• fix. xjy�a,sk�� § �t'h'' ax'�'�•�3`Sr t�.ar,�t-";.i E�' tE ��.vy''F :� :9G•sow.yn^-M T�a y,.y..: Y 1�a ti s�,�°is"';9 ri ���� am•k >x• ��.^u�v���N�i��,�. �`� ><r, '2����Y:K�?�x'�r�'+��.» "�. ���`" `�. +'' ?. ��' }4"'�,s'e+ bM�`'�: �$..E�.�rSsE'.�:P.e�Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 1.50 ft Discharge EE 3.55 ft/s 4 r:CE' �tiy-a, •S:?6'',},.�.;,y _is�r `wna:r-+;�^ x:. -qe f3)�?qr y^ CS't ter. �:' �;.'eas mZ�sw. ,p� {r3i'�:�Ss���33'ri..��"�illti�lY,'w!�k�.3xz����d. �.�z>�.3: Iv ,"'w. a��L���:. .��,,,,tt '�,,��,, ' x r�•-•+ �.'�+.��.�' .. nsa. ~- c aY "ff� 3��.�"...•+:&.E i..... ..�d w;:a. .+�:.z�x.ifu`as, Normal Depth 0.73 ft Flow Area 0.85 ft' Wetted Perimeter 2.32 ft Top Width 1.50 ft Critical Depth 0.72 ft Percent Full 48.7 % Critical Slope 0.00528 fUft Velocity 4.16 fUs Velocity Head 0.27 ft Specific Energy 1.00 ft Froude Number 0.97 Maximum Discharge 7.99 ft'!s Discharge Full 7.43 frfs Slope Full 0.00114 ft/ft Flow Type SubCritical It Downstream Depth 0.00 It Length 0.00 ft Number Of Steps 0 Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Average End Depth Over Rise 0.00 %, Normal Depth Over Rise 48.68 %, Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 109-01.066.001 10M612007 3:52:02 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 8-12 �y �Tj Q"n'c'��e � t;`-r"•."'.W �;'.' .z'L p" -�a' s??'ofas"»T�'^ �.,'8.��`.ii;'_. �'.>•::;:Mti'.'Us,w:=:"..:.�,.�: s,�"lt . •: ^,, zf.VaM?.;iv� c. .:�.s.` 8x�....r,.,zi...v�&S•3? .z€ac :'.�.s:3,?':di�.","..�f t2 '.�d�'kK�:. 4: . *' ..'St .. . eai2.�l: Ztez,." r� .Ti,�.;x M. Normal Depth 0.73 ft Critical Depth 0.72 ft Channel Slope 0.00500 ftfft Critical Slope 0.00528 fUft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 1011612007 3:52:02 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755 4 6 66 Page 2 of 2 North General Aviation Development Circular Pipe - 8-13 }++ .7,�.re.. '' :,ya::� .. i. .'fled '.'� 'r�,,x���•r- ;'Y-r�,+e` �».��;�,. .�,3nS.,,x.:Y OY'r�i ^Q.':.. 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Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10/1612007 3:52:23 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 8-14 l; .:i.Y:w-.'.�r•.q iif`�"i`t�,r:fX3_!' z'?;k�.>'v t='� x;L�S•.• ,.ate f - y�.;; _ WO .. r. i ,I Qp C�.a y,.'f `,: ,a;a �v "' a k mom' da^"'>• G��O�y�����i 'ON]�&��4 � 7�5kS�����J�Q�ar ��� �JS � � J�`���3 Ic:^i.es C.js..-.�..,t.# tsxs �L.,.,.,. ,._. >S,dar)at<'x.ii-ns `sY$Sis ..a ?'..� �*Y'.:L" +._ !Ra„ ?s:'5r.; Normal Depth 1.25 ft Critical Depth 112 ft Channel Slope 0.00500 ft/ft Criticaf Slope 0.00648 fftft Bentley systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 10/16/2007 3:52:23 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 08795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-15 Friction Method Manning Formula Solve For Normal Depth I,�M b"1 1101k��,..Yr�XvM,�.�*�<+qJ�yfs �.<�� �t �4as��a�V,�.�1�r34���: t��a��:^,a_�r��i�#faa ����1 �r�<saLK��Z�{1��p33% •c��+�����x� � a.Roughness Coefficient 0.013 Channel Slope 0.00500 ft/ft Diameter 2.00 ft Discharge 14.41 ft°/s ���c[;�es� 3}r L..,.Fr.� "'5�:q,..` ;,?e'�.��";:tw`,S`..'•' ,s�'. .+fF,�Y��' �n�.,w.F�.;�w- yitYSs*�> «t xi+ T..�. + s f.":^•, <r' -'sv Normal Depth 1.48 ft Flow Area 2.50 ft' Wetted Perimeter 4.15 ft Top Width 1.75 ft Critical Depth 1.37 ft Percent Full 74.2 % Critical Slope 0.00616 fUft Velocity 5.76 ft/s Velocity Head 0.52 ft Specific Energy 2.00 ft Froude Number 0.85 MaAmum Discharge 17.21 ftz/s Discharge Full 16.00 ft'/s Slope Full 0.00406 ft/ft Flow Type SubCritical �'"�',.� `r... ,�,d" .�., �:���`�`�` ,x�r.3!a,�. �j��' �1 n:'+$� •,• ,�7> K �;•. :� � -..ram ftwTikf Downstream Depth 0-00 ft Length 0.00 ft Number Of Steps 0 AE Upstream Depth 0-00 ft Profile Description Profile Headloss 0.00 It Average End Depth Over Rise 0.00 % Normal Depth Over Rise 74.23 % Downstream Velocity Infinity ft/s Upstream Velocity Infinity fits Bentley Systems,Inc. Hoestad Methods Solution Center Bentley FlowMaster [08.01.066.001 1011612007 3:52:33 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 8-15 G�}Ki��•F.�df��:'i�,..•• )�K�..`.X`.4'�Fs,'(.'�. �� . �. y4 z.t4�• �>.a'�' .�e••Y... -farL '7 4 `aMX :NE,% �f ���`,�vi�yptt �� _k�). 1i2'�'�r�WC� '�� �^$' •r_fi? ... l M��ise�'H <�� Normal Depth 1.48 ft Critical Depth 1.37 ft Channel Slope 0.00500 ft/ft Critical Slope 0.00616 Wft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 100.01.066.001 1 011 612007 3:62:33 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-4666 Page 2 of 2 North General Aviation Development Circular Pipe - 8-11 p E��,3y�Y.W.3`A`.�: Y :ce��'�Tl� 0.t�.3t'•���'•�x.��",.�.,Sw^i3n.-,`s�.'�L.,.t.�G'�Sn�����z�'�%�, ti5�am./,x$tWy�<�a�!'£:c e.-..w.. sr�.1.� ,.£. 7.?3��•uZ�tx��'`w��t Friction Method Manning Formula Solve For Normal Depth ^fxp r;v��, 'x+jx ,vim"�!::. ^E.xse�i=�':^.`f�nnE:�a �'?t :ii+,^ 'h i ce...yyl'+'''�:.e:�xYy: •'a 7;.,..o�;a.. �,d ,�, ��. 6 '§�, '�`°. � a''�a,����•''�°z<a�yic�n �. `E �yg7��xn� 4,� �Y" .y �r �4�, i � r��� L�(��'������ �'1 x Y-1 s. ,✓,.x>'•. s��' ,.<.._ ra.�°�y„ ,:�x.�.�.a.... 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Haestad Methods Solution Center Bentley FlowMaster (08.01.066.001 10116/2007 3:52:42 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pipe - 10-3 53 ?, e, 1s eke f ?fSa 54t rv? !`r ?9?: acs x 1; ?x t+ faS "}>1 rr3>° 'M-0 .? ?''000.'r?';?? Friction Method Manning Formula Solve For Normal Depth Roughness Coefficient 0.013 Channel Slope 0.05800 fUft Diameter 1.50 it Discharge 7.84 ft'/s i;w. 144 ? K is rtav t x;xaa ?+ z 4`?.t .'- -% Paz, •?' „Y ;rte ;-Sr :<yu,.+d" ??:;v ¢ a ? :' }?' ° E?a+ :yn(5- 7 t?+. .,s.ti?'??:isk'Z.?oss.<a#?r1?.'?i%.a..Y.k..&ccsce. x+,.ti?G...Yzecwi3.n:«.fH:.H."/.n.ia}- ?..t:. '.s,"yr+.v:x:r.. i4 4 ???:?'d?.?j? a .ibUY??,:. M?`(.«•??Normal Depth 0.57ft Flow Area 0.62ft2 Wetted Perimeter 2.00ft Top Width 1.46ft Critical Depth 1.09ft Percent Full 38.2Critical Slope 0.00731fUft Velocity 12.62ft/sVelocity Head 2.47ft Specific Energy 3.05ft Froude Number 3.41Maximum Discharge 27.21ft'!sDischarge Full 25.30f?/sSlope Full 0.00557fUft Flow Type SuperCritical 3 ?: ? T' "3. '? 8,3 ?_"n. e? ? a..y,. .:.!!::+M: ..• .<? 'i,'A9- is R.y:T^^y3w:rX :•?!Y.::: tPwii X 'It? V. ..l . , .fir-? ??a? ?-'?`.YJ.e '?1' . '???p . ?' ' ? d??'. ??! Y' ?.?.^. y.: ••"'^,° lj:?Sy? N"??. r ?t'q., ?w... ?.,;.?? <.'.i C?. Ti, Y 'iii: ? ?"2ix?r}'lc ??'??'X:t'his:??'???'?7i?4:m?.....'f..;s??.lir?la•?. .... .3?:"'.?4fi?.?Sas:`,'{3r??..; rR!s.?i?':..iK?'!4"ia?Y.?Y ?-'.K Y?" ev."?+???'?Downstream Depth 0.00ft Length 0.00ft Number Of Steps 0 fat'? k??+.?.??.?.?.?c?'r.?s?'.?'.?>?"w??',???*z;,. <.?'?'a?? d??:??n3"?' : ??.s?? .???'.'•`?Upstream Depth 0.00ft Profile Description Profile Headloss 0.00ft Average End Depth Over Rise 0.00Normal Depth Over Rise 38.23Downstream Velocity Infinity fVs Upstream Velocity Infinity Ws Bentley Systems, Inc. Haestad Methods Solution Center Bentley FlowMaster [06.01.066.00]1011612007 3:52:50PM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666Page 1 of 2 North General Aviation Development Circular Pipe - 10-3 i��y,��^t � �,t"�.'".,�•� �f��e�- ��3i `�tsu� :�.�3�� �3�*��4,��+ri�y '��x �S '�'�. ;,� ��" � �u����� �v;,a �,;. ra+....��U��..,.��:'���`xs.� °yaka�u����'���;��;�:?',�3T�'���,.,'•`•u-. � '�T,$1 '=x*- a .. ..�°�.t�. '��'� :.�v1s'S'1.CPxttn���va Normal Depth 0.67 ft Critical Depth 1.09 ft Channel Slope 0.05800 ftlft Critical Slope 0.00731 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.00] 10116/2007 3:52:50 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-756.1666 Page 2 of 2 North General Aviation Development Circular Pipe - 10-2 �'i�`ni>ii�S�r$`�Y"�' s y �aY�.z �-u � r �� J �^ r v,x a •w, � u r•� ii.�.�T��GAa�L�1.4`.L.Ip'`i..c',.:.s.>z^,:,w13 ��.".;sn•(.�iY?C���ztftf�r��sW�sS'F=3[.f��� :�s-.use;S'�':`l isw'(' ��:. s.,..fts+, t?:�ls ;'•�s1..'�sS.a;��ra`iv Friction Method Manning Formula Solve For Normal Depth ��}?vr-.r:*:�.•:,ti^�slRrx,:ra:H wx;a..�~�?"^.;� s;:x:.•"..<gK+`:y'l' - '<f..,sn�,= •.zr•�Y.% •.�.x: .,a tyF 'P � •� `°;1xf spwp .x.., i4��}�}� : �.•.y�� ``�t `c? k ���vE����z�� ���*,r��•t� ��„, � �' l 3 � �d�` 4� ro.'�`i'�''+� » li..u,Ikt*tae.�:�:?���Y�:����k, Roughness Coefficient 0.013 Channel Slope 0.00600 tuft Diameter 1.50 ft Discharge 2.62 ft'!s �' ,T :�: <a, -^�` ;gi.i.-0 � x, f y; x� .�. z• us:�y :x a •,•� � r. a '� .: a: ,� f � hj";'...x^ •':�r''��:� ';�� �� ,R '�",� .is:�'`` :� •'l:.; ,s. -<zy...,�;.>a.-:f;i'• � �n='"�=„�'„°i.�s� ¢ �?:-�, II� � �: ``'a,�,yE�t � � �i<sa So3 ��'%�zt ",, s• t �, �,,�i.•"r+�` �"'!�a3�z�, �E !'t�`du`''�•�:. Mltx: s�:+Gs ����vts:?:" 4kt..'�Y�3I':�3Y �k�t '�:at� _xs�.�1 .1���;;1:.y��•'��i���:t�:-` 'a' ..:�5'a?a\t"'...,.s<�'Ri�.��..aS`.D:^�����'•`:s:�'oz5nv Normal Depth 0.60 ft Flow Area 0.66 ft' Wetted Perimeter 2.06 ft Top Width 1.47 ft Critical Depth 0.60 ft Percent Full 40.1 %, Critical Slope 0.00503 fvft Velocity 3.80 fVs Velocity Head 0.22 ft Specific Energy 0.83 ft Froude Number 1.00 Maximum Discharge 7.99 fris Discharge Full 7.43 f afs Slope Full 0.00068 ft(ft Flow Type SubCritical ���ii� �� ��/� ��� 'S»1�'9 f �+�'� wit �3F' , 'SF 4 .�.s'�N�x��.R'��9�F.�;.����A,�•a S� �t ` ;{ <i Y' .�� 'l i 4xJ 3"�� �' •t �fi�v" Y �. C..Si 1 f t ..- A t., N 1'.Y'�Fvr wNl�1.. 1111'•••���� ``k��.''•SI SN >�'¢�.wi!!�•'iY�.ji�t,•iY�w: iX'.ENs � � � t' Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 IBM, >r _Y s `F.•.. Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 it Average End Depth Over Rise 0.00 %, Normal Depth Over Rise 40.16 %, Downstream Velocity Infinity ftls Upstream Velocity Infinity ff/s Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10/16/2007 3:52:58 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1.203.755-1666 Page 1 of 2 North General Aviation Development Circular Pipe - 10-2 ���.�.. y�'�t:.,: '��;3. s�N����•.: y�4;;Y �s�,v� r � sages.. y. ►}n ,M•�. ��,{ F^} � 2 �.,.�� �,�` �e jY� �i�, tCy. .. ��. 4F� �'��i� 7'� �.�,�?• �'7# {§-Zi t>�t � v � `�f x' wt.�Ze�=x�k t L 6F Normal Depth 0.60 ft Critical Depth 0.60 ft Channel Slope 0.00500 fi/ft Critical Slope 0.00503 ftift Bentley Systems,Inc. Haestad Methods Solution Center Bentley FiowMaster 108.01.066.001 10/16/2007 3:52:58 PM 27$lemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Circular Pepe - 10-1 ice'»''Z � �•�'�S'}�`�s"�2�1'., t ��;�'e;"y�'+ri � �issD "i' s 1��s2��4'u�+5.? 'Y.�ty�j s .:ef:+x� ��� vaxY.< '"�. '{'I� N't�i ' �',j�Y'� Friction Method Manning Formula Solve For Normal Depth �:kkz��'J..C'•�?'`"A �1 t .t 'x45, vOv:Y.k,:r.�x,�{33.'•;w;,K'Y.rA3 y .lT t ynss ��Lv• ¢"��s!t.^ .,... .. ..:(•s .•c.M1�.: 3'ru>?".••s .fir ;KN�jy.•.t> �Y 1 r ejrp,G�,�4 ¢ l.16121"k Roughness Coefficient 0.013 Channel Slope 0.00600 ft/ft Diameter 1.50 ft Discharge 2.51 ft-/s *a�_ . �J-�F.�.���a.itiv��r?� ���.,s'�'.S°",>?k%}�x?�i �s'�y-�`-�z �au+��s�;'.?�,' t���`Fsa �+sK��,ry�� ��•. °r���xr : Normal Depth 0.60 ft Flow Area 0.66 ftz Wetted Perimeter 2.06 ft Top Width 1.47 ft Critical Depth 0.60 ft Percent Full 40.1 % Critical Slope 0.00503 ft/ft Velocity 3.79 ft/s Velocity Head 0.22 ft Specific Energy 0.82 ft Froude Number 1.00 Maximum Discharge 7.99 ft3/s Discharge Full 7.43 ft'ts Slope Full 0.00057 ft/ft Flow Type SubCritical �3�,. �: •;ii4a"`�`s, :'<" y�-• .y..F�ci _ .' s.. ._ {a a � t� e '.r �,r,'-{n. f..::wa.�•., <s». »` «k..s&at�....��i'�`^�.i4�ini2 �. � 4�' x'a�r M1.sA.°ffi � i - ��� Downstream Depth 0.00 ft Length 0.00 ft 334.E Number Of Steps ,J �+ 0 {, 1: ��'..''��� �it'..M£l�.T•.'.. `I"l:K�?�3kS.-2��X� ^ ��Z��.� � ✓an��5 4 .3'f3� < 4sa�'., tY• ,. ix•. Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Average End Depth Over Rise 0.00 % Normal Depth Over Rise 40.06 % Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Bentley Systems,Inc. Hassled Methods Solution Center Bentley FlowMaster 108.01.066.001 10/1612007 3:53:00 PM 27 Simon Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 2 North Generaly Aviation Development Circular Pipe - 10-1 _ �s'�.'..��.;,AwlS�x�s'���•.i,`r.'r.�1f�tl��j'.�.'���`.��S�cf:a�tr:..lk�e�F':t:t���a.�a���?s�:.ssF8.�31�>1.}ie'�i�°aka. :,.�a �4iS.�C�:im '�S3 �::' ���,�e�.'ie`��� t�'i:.'�r�,'7 Normal Depth 0.60 ft Critical Depth 0.60 ft Channel Slope 0.00500 ft/ft Critical Slope 0.00503 ft/ft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 10/16/2007 3:53:06 PM 27 Siemone Company Drive Suite 200 W Watertown,CT 08795 USA +1-203-755-1666 Page 2 of 2 North General Aviation Development Barrel 2 BOOM O " $ C"' cxo, u Y.3�F••'x ar., { 5r,: "I'xrcx' - b.. ,r �`"' # .'•..�± ti ' % �� .s� x.•n�s� - ..'arrr uS.:?,�v 4 .v"»"Y �=ilyd':.r ` $... rw e,~ux..1 dd Friction Method Manning Formula Solve For Normal Depth jtl�,•.;A.4�is�" �s�3FrJi'��'`�z�4 �� 4§ Sr�`z?;��aa �m+t� ?"-hsy rsy�sasw � '*b�a�ra� r"is� � r,��-cc4ayk,. :€�' �• q stu tl` !:e: ir".?: Roughness Coefficient 0.013 Channel Slope 0.02900 ft/ft Diameter 3.00 ft Discharge 2.84 ft'fs HIT, rid' ;�*;;,^t\�; ..T � '"a .'t„ £. r t 'ur:' r K"J't�'- {rr .y� a•- [;�t+,:-y ���;'t"' r�%.�" ,��a�i.";~;icy;��at .��<.:�;i�:•'tit: ,;��; �F�c��. ::y�x R a�,'�:`�c:, x•'•• �, .:a '�i '..of. S :iCfj'.:.,:�;;Y�r,'k4'ai�:.rx`z:,yii!� t $ ;:>.� ';,'NL5:. 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Haestad Methods Solution Center Bentley FlowMaster 108.01.066.001 1 011 612007 3:53:18 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 2 North General Aviation Development Barrel 2 3) m : iFx`,...,.�A�£t��fi.�°'.1�i..1xiTwH.».�'w�a�uZ�ks�'_°Scx.:��i�6!�Ce:t ? .`�.�.'N..,a�'.,��.r1+'�.:`t..��`r�."d.Lca:�✓� x_a :4.d �� k����S'�xi Normal Depth 0.33 ft Critical Depth 0.52 ft Channel Slope 0.02900 ft/ft Critical Slope 0,00409 fyft Bentley Systems,Inc. Haestad Methods Solution Center Bentley FlowMaster [08.01.066.001 10/16/2007 3:53:18 PM 27 Slemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 i0 b m 3 C - o 0 ai rci ri J L tl0 C _ J K (A O1 0- 0 L 'O 3 x (n a 0 t- � w � o s o in v ui o m a Ca .� zo C ,d co U r U w O O w N N E LL 0 L 2 o I° � u 7 c Ta ..y U U > V U V ro A co co ro _ w 0 o _v dr M y v v ro x 1 E o . 5 Y in J N cz ^ 3Y ,o�NON 0 � C Q O E r m m �.+ E U L c p Y V MMRI U U � U V Q °° c +� w o o E ut o vt oN o N u o o v ro O 1� c N °O u tl0 �_ o v c co co U o m o d w ro v w tv cv C w . o c -a c in '� x V E o ro aw O n !\ o oo 00 n U c �j ) 3 to .o E U ao Z tL o n n E v c c m m a m c o w ro o a a N a o a o a i= g w I, ;; „ a Do o °ar u t�i of o C ❑ tv `o c n a b4 y o c ? m U M cn ~ L 0 o c ❑ o o _ E U m y O °!' > V m m y p n co Q O act c m o m U E c y M ro `O oo a Y w Z 00 O N 1 Q �1 M o Y O w Z N w w y y in w U;{ .'r v w > w w w n r col co N N C7 = — ❑ c m v °P Q ice' o m U — — v d d H n i v w coj 0 c .;F: ro o ro -L v w a^' c �' 'ro '' w O O o r L v _h Z w w w v S d `o 9 y (n n .D Z O N N � �+.t o O4 N '- N C rL Z ao ca w 3 c w m > n a U n aw co 0 w Table of Contents Basins.gpw Hydraflow Hydrographs by Intellsolve Tuesday,Oct 16 2007,3:4 PM Hydrograph Return Period Recap ..................................................................... 1 2 - Year SummaryReport ................................................................................................................ 2 HydrographReports .......................................................................................................... 3 Hydrograph No. 1, Rational, POST 1+2+3+4+5+6+7 ...................................................... 3 Hydrograph No. 2, Reservoir, BASIN 1 ........................................................................... 4 PondReport ................................................................................................................ 5 Hydrograph No. 3, Rational, POST 8+9+10+11 .............................................................. 6 Hydrograph No. 4, Reservoir, BASIN 2 ........................................................................... 7 PondReport ................................................................................................................ 8 10 - Year SummaryReport ...................................................................:............................................ 9 HydrographReports ........................................................................................................ 10 Hydrograph No. 1, Rational, POST 1+2+3+4+5+6+7 .................................................... 10 Hydrograph No. 2, Reservoir, BASIN 1 ......................................................................... 11 PondReport .............................................................................................................. 12 Hydrograph No. 3, Rational, POST 8+9+10+11 ............................................................ 13 Hydrograph No. 4, Reservoir, BASIN 2 ......................................................................... 14 PondReport .............................................................................................................. 15 25 - Year SummaryReport .............................................................................................................. 16 HydrographReports ........................................................................................................ 17 Hydrograph No. 1, Rational, POST 1+2+3+4+5+6+7 .................................................... 17 Hydrograph No. 2, Reservoir, BASIN 1 ......................................................................... 18 PondReport .............................................................................................................. 19 Hydrograph No. 3, Rational, POST 8+9+10+11 ............................................................ 20 Hydrograph No. 4, Reservoir, BASIN 2 ......................................................................... 21 PondReport .............................................................................................................. 22 100 - Year SummaryReport .............................................................................................................. 23 HydrographReports ........................................................................................................ 24 Hydrograph No. 1, Rational, POST 1+2+3+4+5+6+7 .................................................... 24 Hydrograph No. 2, Reservoir, BASIN 1 ......................................................................... 25 PondReport .............................................................................................................. 26 Hydrograph No. 3, Rational, POST 8+9+10+11 ............................................................ 27 Hydrograph No. 4, Reservoir, BASIN 2 ......................................................................... 28 PondReport .............................................................................................................. 29 1 Hydrograph Return Period Recap Hyd. Hydrograph Inflow Peak Outflow(cfs) Hydrograph No. type Hyd(s) description (origin) 1-Yr 2-Yr 3-Yr 5-Yr 10-Yr 25-Yr 50-Yr 100-Yr 1 Rational ------- ----- 22.21 —- ---- 34.52 40.91 ----- 50.86 POST 1+2+3+4+5+6+7 2 Reservoir 1 ------- 2.62 —— -— 11.90 20.79 ------ 33.43 BASIN 1 3 Rational ------ ------- 26,53 --- ------ 39.86 46.48 ------- 56.43 POST 8+9+10+11 4 Reservoir 3 ------ 0.61 ------- ------- 2.84 3.97 --- 8.38 BASIN 2 Proj, file: Basins.gpw Tuesday, Oct 16 2007, 3:04 PM Hydraflow Hydrographs by Intelisolve 2 Hydrograph Summary Report Hyd. Hydrograph Peak Time Time to Volume Inflow Maximum Maximum Hydrograph No. type flow interval peak hyd(s) elevation storage description (origin) (cfs) (min) (min) (cult) (ft) (tuft) 1 Rational 22.21 1 39 51,980 --- ---- ------ POST 1+2+3+4+5+6+7 2 Reservoir 2.62 1 73 50,715 1 2136.14 48,866 BASIN 1 3 Rational 26,53 1 20 31,834 ---- ------ ------ POST 8+9+10+11 4 Reservoir 0.61 1 40 31,334 3 2104.29 30,951 BASIN 2 -- Basins.gpw Return Period: 2 Year Tuesday, Oct 16 2007, 3:04 PM Hydraflow Hydrographs by Intelisoive 3 Hydrograph Plot Hydrallow Hydmgraphs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. I POST 1+2+3+4+5+6+7 Hydrograph type = Rational Peak discharge = 22.21 cfs Storm frequency = .2 yrs Time interval = 1 min Drainage area = 19.730 ac Runoff coeff. = 0.6 Intensity = 1.876 in/hr Tc by User = 39.00 min IDF Curve = AVL Airport.IDF Asc/Rec limb fact = 1/1 Hydrograph Volume=51,980 cult POST 1+2+3+4+5+6+7 Q (cfs) Hyd. No. 1 --2 Yr Q(cfs) 24.00 - — - 24.00 _._... _ . ._..... --..__.... ..... 20.00 .. .. - 20.00 ...........-... __ ._............._................ ....................................... . ...........-- 16.00 16.00 _...................... .._........................ .. ..........................._.... ... ... ............. __......._...... ......................... .........._ ............ .._. .. .. - --.. ..__.._. ... 12.00 - --- -- 12.00 ..................... ........................ .. ..................................... - -------.------..-......------.. 8.00 8.00 --- --- ........._..._..------ -. -------- -- .._-. --------- .._.. - 4.00 - 4.00 0.00 -- 0.00 0.0 0.2 0.3 0.5 0.7 0.8 1.0 1.2 1.3 Time(hrs) Hyd No. 1 4 Hydrograph Plot Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 2 BASIN 1 Hydrograph type = Reservoir Peak discharge = 2.62 cfs Storm frequency = 2 yrs Time interval = 1 min Inflow hyd. No. = 1 Max. Elevation = 2136.14 ft Reservoir name = BASIN 1 Max. Storage = 48,866 tuft Storage Indication method used. Hydrograph Volume=50,715 cult BASIN 1 Q(cfs) Hyd. No. 2--2 Yr Q(cfs) 24.00 24.00 _........ . - ... ...................._ ..... __...._..__ 20.00 - 20.00 ---------- 16.00 16.00 -------------------- ----------- _... . -...._ ........... _._. 12.00 -- --- — _. 12.00 .......... .............. ......._.. 8.00 - 8.00 4.00 - 4.00 0.00 0.00 0 5 10 15 19 24 29 34 39 44 48 Time(hrs) Hyd No. 2 Hyd No. 1 Pond Report Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 1 - BASIN 1 Pond Data Bottom LxW = 150.0 x 60.0 ft Side slope = 3.0:1 Bottom elev. = 2132.00 ft Depth = 8.00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sqft) Incr.Storage(cult) Total storage(cult) 0.00 2132.00 9,000 0 0 0.40 2132.40 9,510 3,702 3,702 0,80 2132.80 10,031 3,908 7,609 1.20 2133.20 10.664 4,119 11,728 1.60 2133.60 11,108 4,334 16,062 2.00 2134.00 11,664 4,554 20,616 2.40 2134.40 12,231 4,779 25,395 2.80 2134.80 12.810 •5,008 30,403 3.20 2135.20 13,401 5,242 35,644 3.60 2135.60 14,003 5,480 41,125 4.00 2136.00 14,616 5,723 46,848 4.40 2136.40 15,241 5,971 52,819 4.80 2136.80 15,877 6,223 59,042 5.20 2137.20 16,525 6,480 65,522 5.60 2137.60 17,185 6,742 72,264 6.00 2138.00 17,856 7,008 79,272 6.40 2138.40 18,539 7,279 86550 6.80 2138.80 19,233 7,554 94,104 7.20 2139.20 19,938 7,834 101,938 7.60 2139.60 20,655 8,118 110,056 8.00 2140.00 21,384 8,407 118,464 Culvert/Orifice Structures Weir Structures IA] IBl [C] [D] [A] [B] [C] [D] Rise(in) = 36.00 3.00 12.00 0.00 Crest Len(ft) = 16.00 13.00 0.00 0.00 Span(in) = 36.00 3.00 12.00 0.00 Crest El.(ft) = 2137.00 2138.00 0.00 0.00 No.Barrels = 1 1 2 0 Weir Coeff. = 2.60 2.60 0.00 0.00 Invert El.(ft) = 2124.00 2132.00 2135.60 0.00 Weir Type = Riser Broad -- Length(ft) = 78.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.30 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Exfiltration= 0.000 in/hr(Wet area) Tailwater Elev.= 0.00 ft Note:Culvert(Orilice outflow have been analyzed under inlet and outlet control. Stage(ft) Stage/Discharge Stage(ft) 10.00 10.00 8.00 8.00 6.00 -..._.._-. _- . - -- 6.00 4.00 - -- -- 4.00 2.00 - - 2.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220.00 240.00 Discharge(cfs) Total Q Hydrograph Plot HydraFlow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 3 POST 8+9+10+11 Hydrograph type = Rational Peak discharge = 26.53 cfs Storm frequency = 2 yrs Time interval = 1 min Drainage area = 18.910 ac Runoff coeff. = 0.5 Intensity = 2.806 in/hr Tc by User = 20.00 min 1DF Curve = AVL Airport.IDF Asc/Rec limb fact = 1/1 Hydrograph Volume=31,834 cult POST 8+9+10+11 Q(cfs) Hyd. No. 3--2 Yr Q(cfs) 28.00 -- 28.00 _._._. . . . . ...................._.......................... _ .......... ._....................... .... _ ................... ..........._..... ..... . ...........--........... ._ _... 24.00 -....._._ - ------ ._ 24.00 ------- ___ . . ................_. ....... .......... ........ -...._.._................ _.......... ............. ... . ......---- --- ------ ---------- 20.00 20.00 _... ... __ ..------....... ........... ... _....- -._......................... .. ---------------. .. ._ . 16.00 16.00 ------.......------ ------ --- 12.00 -- .... 12.00 8.00 8.00 4.00 - 4.00 0.00 - — 0.00 0.0 0.1 0.2 0.3 0.3 0.4 0.5 0.6 0.7 Hyd No. 3 Time(hrs) Hydrograph Plot 7 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 4 BASIN 2 Hydrograph type = Reservoir Peak discharge = 0.61 cfs Storm frequency = 2 yrs. Time interval = 1 min Inflow hyd. No. = 3 Max. Elevation = 2104.29 ft Reservoir name = BASIN 2 Max. Storage = 30,951 cuft Storage Indication method used. Hydrograph Volume=31,334 tuft BASIN 2 Q(cfs) Hyd. No.4--2 Yr Q (cfs) 28.00 28.00 _ .........._. _.._.......- . --................_.. ...._ ... _...... _ _.._. 24.00 --------- _.... _.........----------------- ------ 24.00 ........... ..... _.. .................... .... .. 20.00 20.00 ............... ..............._ .. .. . .. 16.00 16.00 ...................................... ... . 12.00 - 12.00 8,00 8.00 4.00 4.00 0.00 0.00 0 5 9 14 18 23 27 32 36 41 45 Time (hrs} Hyd No. 4 Hyd No. 3 Pond Report $ Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 2 - BASIN 2 Pond Data Bottom LxW = 166.0 x 71.0 ft Side slope = 3.0:1 Bottom elev. = 2102.00 ft Depth = 7.00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sgft) Incr.Storage(cuft) Total storage(cuft) 0.00 2102.00 11,786 0 0 0.35 2102.35 12,288 4,213 4,213 0.70 2102.70 12,799 4,390 8,603 1.05 2103.05 13,319 4,570 13,173 1.40 2103.40 13,847 4,754 17,927 1.75 2103.76 14,385 4,940 22,867 2.10 2104.10 14,931 5,130 27,997 2.45 2104.45 15,486 5,323 33,320 2.80 2104.80 16,050 5,519 38,838 3.15 2105.15 16,623 5,717 44,556 3.50 2105.50 17,204 5,919 50,475 3.85 2105.85 17,794 6,124 56,60U 4.20 2106.20 18,393 6,333 62,932 4.55 2106.55 19,001 6,544 69,476 4-90 2106.90 19,618 6,758 76,234 5.25 2107.25 20,244 6,976 83,210 5.60 2107.60 20,878 7,196 90,406 5.95 2107.95 21,521 7,420 97,826 6.30 2108.30 22,173 7,646 105,472 6.65 2108.65 22,834 7,876 113,348 7.00 2109.00 23,504 8,109 121,457 Culvert I Orifice Structures Weir Structures [A] [B] [C] [D] [A] [B] [C] [D] Rise(in) = 36-00 4.00 12.00 0.00 Crest Len(ft) = 16.00 12.00 0.00 0.00 Span(in) = 36.00 4.00 12.00 0.00 Crest El.(ft) = 2106.00 2107.00 0.00 0.00 No.Barrels = 1 1 1 0 Weir Coeff. = 3.33 2.60 0.00 0.00 Invert El.(ft) = 2090.00 2102.00 2104.40 0.00 Weir Type = Riser Broad --- --- Length(ft) = 112.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.90 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Extiltration= 0.000 in/hr(Wet area) Taiiwater Elev.= 0.00 ft Note:Culvert/Orifice outflows have been analyzed under inlet and outlet control. Stage(ft) Stage/Discharge Stage(ft) 7.00 7.00 6.00 6.00 .._.....-......._._..._._. ...... . ........ ..............._................._....... ....._................._................. _._. .............. .. 5.00 5.00 ......... ....... ... ....-..._. ... _.......... ......._..._..... ........_......... 4.00 - ---- -_ -- 4.00 _..... .. .------ _- ._ - .......__.. ... 3.00 --- -- - 3.00 2.00 2.00 _.._.......-- ..............---- ...... - - -._.- _... _...__....... 1.00 1.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220.00 240.00 Total Q Discharge(cfs) 9 Hydrograph Summary Report Hyd- Hydrograph Peak Time Time to Volume Inflow Maximum Maximum Hydrograph No. type flow interval peak hyd(s) elevation storage description (origin) (cfs) (min) (min) (cult) (ft) (tuft) 1 Rational 34.52 1 39 80,777 - ---•-- - POST 1+2+3+4+5+6+7 2 Reservoir 11.90 1 65 79,408 1 2137.19 65,370 BASIN 1 3 Rational 39.86 1 20 47,832 ---- --- ----- POST 8+9+10+11 4 Reservoir 2.84 1 39 47,257 3 2105.21 45,608 BASIN 2 Basins.gpw Return Period: 10 Year Tuesday, Oct 16 2007, 3:04 PM Hydrallow H dro ra hs by Inteiisolve Hydrograph Plot 10 Hydrallow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 1 POST 1+2+3+4+5+6+7 Hydrograph type = Rational Peak discharge = 34.52 cfs Storm frequency = 10 yrs Time interval = 1 min Drainage area = 19.730 ac Runoff coeff. = 0.6 Intensity = 2.916 in/hr Tc by User = 39.00 min IDF Curve = AVL Airport.IDF Asc/Rec limb fact = 1/1 Hydrograph Volume=80,777 cult POST 1+2+3+4+5+6+7 Q(cfs) cfs Hyd. No. 1 -- 10 Yr Q( ) 35.00 35.00 ...................._._...... ._..................._..........- ..._ ....._...................... ............. ._.... . ..... -.... 30.00 - 30.00 25.00 25.00 - ...... . . ................-- ......._.......... 20.00 20.00 .................. .................... 15.00 - 15.00 ........ --- ......... 10.00 10.00 ................_._.................. ..... -._... . 5.00 --- -.. 5.00 0.00 0.00 0.0 0.2 0.3 0.5 0.7 0.8 1.0 1.2 1.3 Hyd No. 1 Time(hrs) 1'! Hydrograph Plot Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 2 BASIN 1 Hydrograph type = Reservoir Peak discharge = 11.90 cfs Storm frequency = 10 yrs Time interval = 1 min Inflow hyd. No. = 1 Max. Elevation = 2137.19 ft Reservoir name = BASIN 1 Max. Storage = 65,370 cult Storage Indication method used. Hydrograph Volume=79,408 tuft BASIN 1 Q (cfs) Hyd. No. 2-- 10 Yr Q(cfs) 35.00 -- 35.00 30.00 - --..... .- -- 30.00 25.00 - 25.00 ......._...................--.._.... .....- -- ........................ 20.00 — 20.00 ...... -..... ...................._... --...-....................._............. .._- 15.00 - - — 15.00 - _... _.._.. ---------------..... _.. 10.00 10.00 _........__. ...._ .. .....---.....- ....------------------............._....._........ .._...... .......... .... . ...------......---...........__..._...__.......-._._......_..................._......._................._. ........ . 5.00 - — - 5.00 0.00 0.00 0 4 8 12 16 20 24 28 32 36 40 44 Time(hrs) Hyd No. 2 Hyd No. 1 Pond Report . 12 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 1 - BASIN 'I Pond Data Bottom LxW = 150.0 x 60.0 ft Side slope = 3.0:1 Bottom elev. = 2132.00 ft Depth = 8.00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sqft) Incr.Storage(cuft) Total storage(cuft) 0.00 2132.00 9,000 0 0 0,40 2132.40 9,510 3,702 3,702 0.80 2132.80 10,031 3,908 7,609 1.20 2133.20 10,564 4,119 11,728 1.60 2133.60 11,108 4,334 16,062 2.00 2134.00 11,664 4,554 20,616 2.40 2134.40 12,231 4,779 25,396 2.80 2134.80 12,810 5,008 30,403 3.20 2135.20 13,401 5,242 35,644 3.60 2135.60 14,003 5,480 41,126 4.00 2136.00 14,616 5,723 46,848 4.40 2136.40 15,241 5,971 52,819 4.80 2136.80 15,877 6,223 59,042 5.20 2137.20 16,525 6,480 65,522 5.60 2137.60 17,185 6,742 72,264 6.00 2138.00 17,856 7,008 79,272 6.40 2138.40 18,539 7,279 86,550 6.80 2138.80 19,233 7,554 94,104 7.20 2139.20 19,938 7,834 101,938 7.60 2139.60 20,655 8,118 110,056 8.00 2140.00 21,384 8,407 118,464 Culvert/Orifice Structures Weir Structures [A] [B] [C] [D] [A] [B] [C] [D] Rise(in) = 36.00 3.00 12.00 0.00 Crest Len(ft) = 16.00 13.00 0.00 0.00 Span(in) = 36.00 3.00 12.00 0.00 Crest El.(ft) = 2137.00 2138.00 0.00 0.00 No.Barrels = 1 1 2 0 Weir Coeff. = 2.60 2.60 0.00 0.00 Invert El.(ft) = 2124.00 2132.00 2136.60 0.00 Weir Type = Riser Broad --- Length(ft) = 78.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.30 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Exfiltration= 0.000 in/hr(Wet area) Tailwater Elev.= 0.00 ft Note:Culverd0rifice outflows have been analyzed under inlet and outlet control. Stage(ft) Stage/Discharge Stage(ft) 10.00 10.00 8.00 8.00 6.00 - --- 6.00 4.00 - 4.00 2,00 2.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220,00 240.00 Total Q Discharge(cfs) Hydrograph Plot 13 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 3 POST 8+9+10+11 Hydrograph type = Rational Peak discharge = 39.86 cfs Storm frequency = 10 yrs Time interval = 1 min Drainage area = 18.910 ac Runoff coeff. = 0.5 Intensity = 4.216 in/hr Tc by User = 20.00 min IDF Curve = AVL Airport.IDF Asc/Rec limb fact = 1/1 Hydrograph Volume=47.832 cult POST 8+9+10+11 Q(cfs) Hyd. No. 3-- 10 Yr Q(cfs) 40.00 40.00 30.00 - — 30.00 20.00 -- - ._._.. .._._-. 20.00 ...-..................._......_.................------------ ._.. ------- ------... ............ - ... ... ... _.. .._._....... 10.00 10.00 _.. _._....._....... - - - .._... =..__ ._ ........ 0.00 -V 0.00 0.0 0.1 0.2 0.3 0.3 0.4 0.5 0.6 0.7 Time(hrs) Hyd No. 3 Hydrograph Plot 14 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 4 BASIN 2 Hydrograph type = Reservoir Peak discharge = 2.84 cfs Storm frequency = 10 yrs Time interval = 1 min Inflow hyd. No. = 3 Max. Elevation = 2106.21 ft Reservoir name = BASIN 2 Max. Storage = 45,608 cuft Storage Indication method used. Hydrograph Volume=47,257 cult BASIN 2 Q cfs Hyd. No.4--10 Yr Q(cfs) 40.00 40.00 . ...-........... ... -. ......_....... .- ................_.._.. 30.00 30.00 20.00 - — -- - 20.00 ._.........--................ .. _ . ... ................... _._....._..._......... 10.00 10.00 ..... ............. .... ................................................... 0.00 0.00 0 3 7 10 13 17 20 23 27 30 33 Time{hrs) Hyd No.4 Hyd No. 3 Pond Report Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 2 - BASIN 2 Pond Data Bottom LxW = 166.0 x 71.0 ft Side slope = 3.0:1 Bottom elev. = 2102.00 ft Depth, = 7.00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sqft) Incr.Storage(cuft) Total storage(cult) 0.00 2102.00 11,786 0 0 0.35 2102.35 12,288 4,213 4,213 0.70 2102.70 12,799 4,390 8,603 1.05 2103.06 13,319 4,570 13,173 1.40 2103.40 13,8,47 4,754 17,927 1.75 2103.75 14,385 4,940 22,867 2.10 2104.10 14,931 5,130 27,997 2.45 2104.45 15,486 5,323 33,320 2.80 2104.80 16,050 5,519 38,838 3.15 2105.15 16,623 5,717 44,556 3.50 2105.50 17,204 5,919 50,475 3.85 2106.86 17,794 6,124 56,600 4.20 2106.20 18,393 6,333 62,932 4.55 2106.56 19,001 6,544 69,476 4.90 2106.90 19,618 6,758 76,234 5.25 2107.25 20,244 6,976 83,210 5.60 2107.60 20,878 7,196 90,406 5.95 2107.95 21,521 7,420 97,826 6.30 2108.30 22,173 7,646 106,472 6.65 2108.65 22,834 7,876 113,348 7.00 2109.00 23,504 8,109 121,457 Culvert I Orifice Structures Weir Structures [A] [B] [C] [D] [A] [B] [C] [D] Rise(in) = 36.00 4.00 12.00 0.00 Crest Len(ft) = 16.00 12.00 0.00 0.00 Span(in) = 36.00 4.00 12.00 0.00 Crest El.(ft) = 2106.00 2107.00 0.00 0.00 No.Barrels = 1 1 1 0 Weir Coeff. = 3.33 2.60 0.00 0.00 Invert El.(ft) = 2090.00 2102.00 2104.40 0.00 Weir Type = Riser Broad - -- Length(ft) = 112.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.90 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Exfiltration= 0.000 in/hr(Wet area) Taiiwater Elev.= 0.00 It Note:Culvert/Orifice outflows have been analyzed under inlet and outlet control. Stage(ft) Stage/Discharge Stage(ft) 7.00 7.00 6.00 6.00 5.00 5.00 ------------- ...._... _.......-_ _... .. .......... .......- ._......... 4,00 - - - ---.....__ - - 4.00 3.00 3.00 2.00 2.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220.00 240.00 Total Q Discharge(cfs) 16 Hydrograph Summary Report Hyd. Hydrograph Peak Time Time to Volume Inflow Maximum Maximum Hydrograph No. type flow interval peak hyd(s) elevation storage description (origin) (cfs) (min) (min) (cuff) A (cuft) 1 Rational 40.91 1 39 95,734 ---- ------ ------ POST 1+2+3+4+5+6+7 2 Reservoir 20.79 1 58 94,360 1 2137.43 69,315 BASIN 1 3 Rational 46.48 1 20 55,777 ---- ------ ------ POST 8+9+10+11 4 Reservoir 3.97 1 38 55,189 3 2105.61 52,427 BASIN 2 Basins.gpw Return Period: 25 Year Tuesday, Oct 16 2007, 3:04 PM HydraHow Hydrographs by Intelisolve 17 Hydrograph Plot Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 1 POST 1+2+3+4+5+6+7 Hydrograph type = Rational Peak discharge = 40.91 cfs Storm frequency = 25 yrs Time interval = 1 min Drainage area = 19.730 ac Runoff coeff. = 0.6 Intensity = 3.456 in/hr Tc by User = 39.00 min IDF Curve = AVL AirporLIDF Asc/Rec limb fact = 1/1 Hydrograph Volume=96,734 cuft POST 1+2+3+4+5+6+7 Q(cfs) Hyd. No. 1 --25 Yr Q(cfs) 50.00 --- -- 50.00 .. ..............--- ---- --------- _.. . . . ............._... ............................_........ .... .. ....... -........._......_...._......._.... ... ------ . 40.00 - 40.00 30.00 --- - 30.00 ... . ... ............._.................... .....__...._............................_........... ..... --------------..-......................- ... .. .. ........................................ ........ 20.00 — -- 20.00 10.00 10.00 -- -------- ....................... .. _... .................--..... -......... _...... ...... ...................... ............ . .. . . . ........................ ........ 0.00 0.00 0.0 0.2 0.3 0.5 0.7 0.8 1.0 1.2 1.3 Hyd No. 1 Time(hrs) 18 Hydrograph Plot Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 2 BASIN 1 Hydrograph type = Reservoir Peak discharge = 20.79 cfs Storm frequency = 25 yrs Time interval = 1 min Inflow hyd. No. = 1 Max.'Elevation = 2137.43 ft Reservoir name = BASIN 1 Max. Storage = 69,315 cult Storage Indication method used. Hydrograph volume=94,360 cult BASIN 1 Q(cfs) Hyd. No. 2 --25 Yr Q(cfs) 50.00 — - 50.00 _......... ........__......... _. .. ... ......................... .............. ...... ........... ._. _........__...... ...... ......... _.. ....... 40.00 — . _.._ - -- .. 40.00 30.00 30.00 _............. ............ ---------------------------- - ....__........... . . _..... ........._....... ........ ......................_........................_............ ..... .. _.. 20.00 20.00 10.00 10.00 ................._..... __..... . ........... ......... .............--.........-............ .._......... -....... .. ............................-----.. ----............_. ._._ _._ .. 0.00 - — 0.00 0 3 6 10 13 16 19 22 25 29 32 35 Time (hrs} Hyd No.2 Hyd No. 1 Pond Report 19 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 1 - BASIN 1 Pond Data Bottom LxW = 150.0 x 60.0 ft Side slope = 3.0:1 Bottom elev. = 2132.00 ft Depth = 8.00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sqft) Incr.Storage(cult) Total storage(cult) 0.00 2132.00 9,000 0 0 0.40 2132.40 9,510 3,702 3,702 0.80 2132.80 10,031 3,908 7,609 1.20 2133.20 10,564 4,119 11,728 1.60 2133.60 11,108 4,334 16,062 2.00 2134.00 11,664 4,554 20,616 2.40 2134.40 12,231 4,779 25,395 2.80 2134.80 12,810 5,008 30,403 3.20 2135.20 13,401 5,242 35,644 3,60 2135.60 14,003 5,480 41,125 4.00 2136.00 14,616 5,723 46,848 4.40 2136.40 15,241 5,971 52,&19 4.80 2136.80 15,877 6,223 59,042 5.20 2137.20 16,525 6,480 65,522 5.60 2137.60 17,185 6,742 72,264 6.00 2138.00 17,856 7,008 79,272 6,40 2138.40 18,539 7,279 86,550 6.80 2138.80 19,233 7,554 94,104 7.20 2139.20 19,938 7,834 101,938 7.60 2139.60 20,655 8,118 110,056 8.00 2140.00 21,384 8,407 118,464 CUIVert/Orifice Structures Weir Structures [A] [B] [C] [D] [A] [Bl [C] [D] Rise(in) = 36.00 3.00 12.00 0.00 Crest Len(ft) = 16.00 13.00 0.00 0.00 Span(in) = 36.00 3.00 12.00 0.00 Crest El.(ft) = 2137.00 2138.00 0.00 0.00 No.Barrels = 1 1 2 0 Weir Coeff. = 2.60 2.60 0.00 0.00 Invert El.(ft) = 2124.00 2132.00 2135.60 0.00 Weir Type = Rlser Broad --- --- Length(ft) = 78.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.30 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Exfiltration= 0.000 inlhr(Wet area) Tailwater Elev.= 0.00 ft Note:CulverttOrfte outflows have been analyzed under inlet and outlet control. Stage(ft) Stage 1 Discharge Stage(ft) 10.00 10.00 8.00 8.00 6.00 - - 6.00 4.00 _.... _ - --- - 4.00 2.00 2.00 0.00 a.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220.00 240.00 Total Q Discharge(cfs) Hydrograph Plod 20 Hydraflow Hydrographs by lntelisolve Tuesday.Oct 16 2007,3:4 PM Hyd. No. 3 POST 8+9+10+11 Hydrograph type = Rational Peak discharge = 46.48 cfs Storm frequency = 25 yrs Time interval = 1 min Drainage area = 18.910 ac Runoff coeff. = 0.5 Intensity = 4.916 in/hr Tc by User = 20.00 min IDF Curve = AVL Airport.I DF Asc/Rec limb fact = 1/1 Hydrograph Volume=55,777 cuft POST 8+9+10+11 Q {ems) Hyd. No. 3--25 Yr Q(cfs) 50.00 - 50.00 ..... .................... .............. .. --------- ......... _.._.._.......... ...... ........................... . . 40.00 - -- --— 40.00 30.00 - — 30.00 20.00 20.00 10.00 — 10.00 ------------ . .. .. --................... ........... _..........-.................. ...... 0.00 _--- 0.00 0.0 0.1 0.2 0.3 0.3 0.4 0.5 0.6 0.7 Hyd No. 3 Time(hrs) Hydrograph Plot 21 Hydrallow Hydrographs by Intellsolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 4 BASIN 2 Hydrograph type = Reservoir Peak discharge = 3.97 cfs Storm frequency = 25 yrs Time interval = 1 min Inflow hyd. No. = 3 Max. Elevation = 2105.61 ft Reservoir name = BASIN 2 Max. Storage = 52,427 cuft Storage Indication method used. Hydrograph Volume=55,189 cuft BASIN 2 Q(cfs) Hyd. No. 4--25 Yr Q(cfs) 50.00 — 50.00 ....._.. ......... _ ............................................. ........ ............... . .--......... . ...-.. .. .. 40.00 — 40.00 30.00 30.00 _.... ..............._................. ........... .. ......... ......_........................ ....-----.---------------------------------------------------------- ------............-... ............. _.. _ ..............._......._.._..._._...._........_.......... .............-... .. 20.00 -- 20.00 10.00 10.00 ............... ....................._......................... ....._... ..... . ........................ _ 0.00 0.00 0 3 6 10 13 16 19 22 25 29 32 Time(hrs) Hyd No.4 Hyd No. 3 Pond Report 22 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 2 - BASIN 2 Pond Data Bottom LxW = 166.0 x 71.0 ft Side slope = 3.0:1 Bottom elev. = 2102.00 ft Depth = 7,00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sgft) Incr.Storage(cult) Total storage(cuft) 0.00 2102.00 11,786 0 0 0.35 2102.35 12,288 4,213 4,213 0.70 2102.70 12,799 4,390 8,603 1.05 2103.05 13,319 4,570 13,173 1.40 2103.40 13,847 4,754 17,927 1.75 2103.75 14,385 4,940 22,867 2.10 2104.10 14,931 5,130 27,997 2.46 2104.45 15,486 5,323 33,320 2.80 2104.80 16,050 5,519 38,838 3.15 2105.15 16,623 5,717 44,556 3.50 2105.60 17,204 5,919 50,475 3-85 2105.85 17,704 6,124 56,600 4.20 2106.20 18,393 6,333 62,932 4.55 2106.56 19,001 6,544 69,476 4.90 2106.90 19,618 6,758 76,234 5.25 2107.25 20,244 6,976 83,210 5.60 2107.60 20,878 7,196 90,406 5.95 2107.95 21,521 7,420 97,826 6.30 2108.30 22,173 7,646 105,472 6.65 2108.65 22,834 7,876 113,348 7.00 2109.00 23,504 8,109 121,457 Culvert/Orifice Structures Weir Structures [A] [Bl [C] [D] [A] [B] [C] [D] Rise(in) = 36.00 4.00 12.00 0.00 Crest Len(ft) = 16.00 12.00 0.00 0.00 Span(in) = 36.00 4.00 12.00 0.00 Crest El.(ft) = 2106.00 2107.00 0.00 0.00 No.Barrels = 1 1 1 0 Weir Coeff. = 3.33 2.60 0.00 0.00 Invert El.(ft) = 2090.00 2102.00 2104.40 0.00 Weir Type = Riser Broad - -- Length(ft) = 112.00 0.00 0.00 0.00 Multistage = Yes No No No Slope(%) = 2.90 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = Na Yes Yes No Exfiltration= 0.000 in/hr(Wet area) Tailwater Elev.= 0.00 ft Note:CuhrefUOrifice outflows have been analyzed under inlet and outlet controt. Stage(ft) Stage/Discharge Stage(ft) 7.00 - 7.00 ....................... -................. . 6.00 5.00 5.00 - - - --- 4.00 .-. ... - 3.0Q - _ _.-......._................. _.................... 3.00 2.00 2.00 _......._....... .........- __. . -- . ...._... _._...._.._...........__..... 1.00 1.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220.00 240.00 Total Q Discharge(cfs) 23 Hydrograph Summary Report Hyd. Hydrograph Peak Time Time to Volume Inflow Maximum Maximum Hydrograph No. type flow interval peak hyd(s) elevation storage description (origin) (cfs) (min) (min) (cult) (ft) (cuft) 1 Rational 50.86 1 39 119,017 ---- ---- ...... POST 1+2+3+4+5+6+7 2 Reservoir 33.43 1 52 117,638 1 2137.58 73,674 BASIN 1 3 Rational 56.43 1 20 67,721 ---- ---- --- POST 8+9+10+11 4 Reservoir 8.38 1 37 67,119 3 2106.16 62,155 BASIN 2 Basins.gpw Return Period: 100 Year Tuesday, Oct 16 2007, 3:04 PM Hydraflow Hydrographs by Intellsoive Hydrograph Plot 24 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 1 POST 1+2+3+4+5+6+7 Hydrograph type = Rational Peak discharge = 50.86 cfs Storm frequency = 100 yrs Time interval = 1 min Drainage area = 19.730 ac Runoff coeff. = 0.6 Intensity = 4.296 in/hr Tc by User = 39.00 min IDF Curve = AVL Airport.IDF Asc/Rec limb fact = 111 Hydrograph Volume=119,017 cuft POST 1+2+3+4+5+6+7 Q(cfs) Hyd. No. 1 -- 100 Yr Q(cfs) 60.00 - 60.00 ...................................................... ------._.. .._ . . _......... ..... _._. ......... ... ... .................--............-............ .........._. 50.00 50.00 40.00 - 40.00 _ - ....................__. ........._.......... ---------------- ---------. ....._...-__ .... .........._... ................................. . 30.00 --- - 30.00 20.00 20.00 _. ._ _ - - -------............................... . ... . 10.00 _.. 10.00 ......................._.......................... . .. .... ..................-............... .... .... .. . .......... _.. .... ........ 0.00 0.00 0.0 0.2 0.3 0.5 0.7 0.8 1.0. 1.2 1.3 Hyd No. 1 Time(hrs) Hydrograph Plot 25 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 2 BASIN 1 Hydrograph type = Reservoir Peak discharge = 33.43 cfs Storm frequency = 100 yrs Time interval = 1 min Inflow hyd. No. = 1 Max. Elevation = 2137.68 ft Reservoir name = BASIN 1 Max. Storage = 73,674 cuft Storage Indication method used. Hydrograph Volume=117.638 cult BASIN 1 a (cfs) cfs Hyd. No. 2 -- 100 Yr Q� ) 60.00 60.00 - ......................... _................... ................. .. ... ......................_....... ............ _... 50.00 -- - - 50.00 ... ... . . . ... .. . 40.00 40.00 ......... ------- . .......................... ................. . . ............ ._.. .. - - ----- - 30.00 20.00 - - 20.00 .. ............-._....... ..._...._.... ............. ................. -............................... 10.00 10.00 0.00 - T 0.00 0.0 1.8 3.7 5.5 7.3 9.2 11.0 12.8 14.7 16.5 18.3 Hyd No. 2 Hyd No. 1 Time(hrs) Pond Report 26 Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Pond No. 1 - BASIN 1 Pond Data Bottom LxW = 150.0 x 60.0 ft Side slope = 3.0:1 Bottom elev. = 2132.00 ft Depth = 8.00 ft Stage/Storage Table Stage(ft) Elevation(ft) Contour area(sqft) Incr.Storage(tuft) Total storage(cult) 0.00 2132.00 9,000 0 0 0.40 2132.40 9,510 3,702 3,702 0.80 2132.80 10,031 3,908 7.609 1.20 2133.20 10,564 4,119 11,728 1.60 2133.60 11,108 4,334 16,062 2.00 2134.00 11,664 4,554 20,616 2.40 2134.40 12,231 4,779 25,395 2.80 2134.80 12,810 5,008 30,403 3.20 2135.20 13,401 5,242 36,644 3.60 2135.60 14,003 5,480 41,125 4.00 2136.00 14,616 5,723 46,848 4.40 2136.40 15,241 5,971 52,819 4.80 2136.80 15,877 6,223 59,042 5.20 2137.20 16,525 6,480 65,522 5.60 2137.60 17,185 6,742 72,264 6.00 2138.00 17,856 7,008 79,272 6.40 2138.40 18,539 7,279 86,550 6.80 2138.80 19,233 7,564 94,104 7.20 2139.20 19,938 7,834 101,938 7.60 2139.60 20,655 8,118 110,056 8.00 2140.00 21,384 8,407 118,464 Culvert I Orifice Structures Weir Structures [A►] [B] [C] [D] [A] [B] [C] [D] Rise(in) = 36.00 3.00 12.00 0.00 Crest Len(ft) = 16.00 13.00 0.00 0.00 Span(in) = 36.00 3.00 12.00 0.00 Crest El.(ft) = 2137.00 2138.00 0.00 0.00 No.Barrels = 1 1 2 0 Weir Coeff. = 2.60 2.60 0,00 0.00 Invert El.(ft) = 2124.00 2132.00 2135.60 0.00 Weir Type = Riser Broad --- --- Length(ft) = 78.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.30 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Exfiltration= 0.000 inmr(Wet area) Tailwater Elev.= 0.00 ft We:CulverUOrince oulflows have been analyzed under inlet and outlet control. Stage(ft) Stage I Discharge Stage(ft) 10.00 - 10.00 _........... ...................... ................... 8.00 8.00 6.00 _-... -- ---- 6.00 4.00 - --- - - - ---- 4.00 2.00 2.00 0.00 - 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200,00 220.00 240.00 Total Q Discharge(cfs) Hydrograph Plot 27 HydraFlow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 3 POST 8+9+10+11 Hydrograph type = Rational Peak discharge = 56.43 cfs Storm frequency = 100 yrs Time interval = 1 min Drainage area = 18.910 ac Runoff coeff. = 0.5 Intensity = 5.969 in/hr Tc by User = 20.00 min IDF Curve = AVL Airport.IDF Asc/Rec limb fact = 1/1 Hydrograph Volume=67,721 cult POST 8+9+10+11 Q (cfs) Hyd. No. 3-- 100 Yr Q(cfs) 60.00 -- - 60.00 ..--............................... --.... ...... - ------ _...................................._._......... ............ 50.00 .---------- 50.00 40.00 40.00 ................................._............- ............. ...............................-- .._....... ..._...._.._...------------ - ..__................. ................._..........._..---------- ........... __......._...... -- .. _... 30.00 ..----.-..... . - — -... 30.00 20.00 20.00 - _....... _. .......... . ......_............... ... ._............ _...........__.... .... ........ ..................... ................. .................... ..............._...... . ... .. ........_.... 10.00 10.00 0.00 0.00 0.0 0.1 0.2 0.3 0.3 0.4 0.5 0.6 0.7 Hyd No. 3 Time(hrs) Hydrograph Plot zs Hydraflow Hydrographs by Intelisolve Tuesday,Oct 16 2007,3:4 PM Hyd. No. 4 BASIN 2 Hydrograph type = Reservoir Peak discharge = 8.38 cfs Storm frequency = 100 yrs Time interval = 1 min Inflow hyd. No. = 3 Max. Elevation = 2106.16 ft Reservoir name = BASIN 2 Max. Storage = 62,155 cuff Storage Indication method used. Hydrograph Volume=67,119 cult BASIN 2 Q(cfs) Hyd. No.4--100 Yr Q(cfs) 60.00 -- 60.00 _ ...... _._...._.......... .... .........---......._................_........................ _........... ...... ..... _ .................._.. ..................................................................._............. ......._............ 50.00 ---- ---..._._.............. . . _.._ 50.00 40.00 40.00 _............-....................................... _ ... _......_......._._....... ....... ...................................... ............. . ... .. . . . . ........... ....................... ............--................ ......... .. 30.00 - - - 30.00 20.00 — - 20.00 ........_.......... .. ................._._....._..........._...._........-........ .......... . __......... ... 10.00 - 10.00 .... ....---._...._. .--..............._.....--......._.. .. . .. ----------------- .............-------------._._. 0.00 0.00 0 3 6 9 11 14 17 20 23 26 28 Time(hrs) Hyd No. 4 Hyd No. 3 Pond Report 29 Hydrafiow Hydrographs by Intellsolve Tuesday,Oct 16 2007,3:4 PM Pond No. 2 - BASIN 2 Pond Data Bottom LxW = 166.0 x 71.0 ft Side slope = 3.0:1 Bottom elev. = 2102.00 ft Depth = 7.00 ft Stage 1 Storage Table Stage(ft) Elevation(ft) Contour area(sqft) Incr.Storage(cuft) Total storage(cuft) 0.00 2102.00 11,786 0 0 0.35 2102.35 12,288 4,213 4,213 0,70 2102.70 12,799 4,390 8,603 1.05 2103.05 13,319 4,570 13,173 1.40 2103.40 13,847 4,754 17,927 1.75 2103.75 14,385 4,940 22,867 2.10 2104.10 14,931 5,130 27,997 2.45 2104.45 15,486 5,323 33,320 2.80 2104.80 16,050 5,519 38,838 3.15 2105.15 16,623 5,717 44,556 3.50 2105.50 17,204 5,919 50,475 3.85 2105.85 17,794 6,124 56,600 4.20 2106.20 18,393 6.333 62,932 4.55 2106.55 19,001 6.544 69,476 4.90 2106.90 19,618 6,758 76,234 5.25 2107.25 20,244 6,976 83,210 5.60 2107.60 20.878 7,196 90,406 5.95 2107.95 21,521 7,420 97,826 6.30 2108.30 22,173 7,646 105,472 6.65 2108.65 22,834 7,876 113,348 7.00 2109.00 23,504 8,109 121,457 Culvert I Orifice Structures Weir Structures [A] [B] [C] [D] [A] [B] [C] [D] Rise(in) = 36.00 4.00 12.00 0.00 Crest Len(ft) = 16.00 12.00 0.00 0.00 Span(in) = 36.00 4.00 12.00 0.00 Crest El.(ft) = 2106.00 2107.00 0.00 0.00 No.Barrels = 1 1 1 0 Weir Coeff. = 3.33 2.60 0.00 0.00 Invert El.(ft) = 2090.00 2102.00 2104.40 0.00 Weir Type = Riser Broad -- -- Length(ft) = 112.00 0.00 0.00 0.00 Multi-Stage = Yes No No No Slope(%) = 2.90 0.00 0.00 0.00 N-Value = .013 .013 .013 .000 Orif.Coeff. = 0.60 0.60 0.60 0.00 Multi-Stage = n/a Yes Yes No Exfiltration= 0.000 in/hr(Wet area) Taiiwater Elev.= 0.00 ft Note:Culvert/Orifice outflows have been analyzed under inlet and outlet control. Stage(ft) Stage I Discharge Stage(ft) 7.00 7.00 6.00 _ .... _.. _. 6.00 5.00 5.00 4.00 . ............_.................... -..._-....._..._.......-.-.._. .... .. .. 3.00 . ...... .. 3.00 2.00 2.00 ..................................................- - _... . . . . - 1.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 180.00 200.00 220.00 240.00 Total Q Discharge(cfs)