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SW1231201_Stormwater Report_20240325
rSs MWATER MANAGEMENT DESIGN REPORT BOBBY N. SETZER T ATE FISH HATCHERY RENOVATION 1401 FISH HATCHERY RD BREVARD, NORTH CAROLINA Shaping Communities Together rS MWATER MANAGEMENT DESIGN REPORT BOBBY N. SETZER TATE FISH HATCHERY RENOVATION 1401 FISH HATCHERY RD BREVARD, NORTH CAROLINA Ben Cathey, PE NC Professional Engineer No. 049336 ttttutiurlrrir�,� ��`•a�,�H C A RO�'�•',, mcgiShaping ........... , Communities Together •Q '17�•. SEAL 55 Broad Street 4 Asheville, NC 28801 828.252.0575 '% FNGINEt'� •y NC Firm License #C-0459 3� December 4, 2023 REVISED March 2024 McGILL PROJECT NO. 19.00124 Stormwater Permit No. SW1231201 IFA Shaping Communities Together meJ ill Table of Contents PROJECTDESCRIPTION........................................................................................................................2 SITEDESCRIPTION ................................................................................................................................2 BASISOF DESIGN...................................................................................................................................2 ProjectDensity...................................................................................................................................2 Stormwater Conveyance....................................................................................................................3 StormwaterQuality ............................................................................................................................3 METHODOLOGY......................................................................................................................................3 Timeof Concentration........................................................................................................................3 HydrologicMethodology ....................................................................................................................3 SiteSoils and Cover Type .................................................................................................................3 DESIGNSUMMARY.................................................................................................................................4 Stormwater Conveyance....................................................................................................................4 Stormwater Quality—Stormwater Wetland........................................................................................4 PermanentDitches ............................................................................................................................5 Rip Rap Outlet Protection/Aprons......................................................................................................5 LIST OF APPENDICES A) SCM Drainage Areas Map B) Stormwater Pipe Drainage Areas Map C) Ditch Drainage Areas Map D) Stormwater Pipe Calculations E) Stormwater Wetland Calculations a. Stormwater Wetland Calculations b. HydroCAD Model: 1-inch, 25-year, 50-year, and 100-year storms c. NRCS Runoff Volume Calculations d. HydroCAD Model: Pre vs Post 1-year storm e. Treatment Areas vs Untreated Areas F) Ditch Calculations G) NOAA Atlas 14 — Precipitation Depth H) NOAA Atlas 14 — Precipitation Intensity 1) NRCS Web Soil Survey Report J) Report of Geotechnical Exploration K) Special Use Permit L) Outlet Protection Calculations MCG ILL ASSOCIATES 55 BROAD STREET, ASHEVILLE, NC 28801/828.252.0575/MCGILLASSOCI ATE S.COM 1 Stormwater Management Narrative Bobby N. Setzer State Fish Hatchery Renovation March 2024 PROJECT DESCRIPTION The Bobby N. Setzer State Fish Hatchery Renovation project consists of production and broodstock raceways, each with a cover structure, hatchery building, intake improvements, public restroom, and fish effluent waste treatment. The proposed improvements to the hatchery have the desired goal of replacing the dated and failing infrastructure, while improving operational efficiency and healthy yield of the fish. The runoff from the buildings and associated impervious areas will drain through stormwater networks and discharge to either a constructed wetland on-site, which outlets to Cedar Rock Creek (commonly known as Grogan Creek) or directly into the Davidson River just north of the project site. SITE DESCRIPTION The Bobby N. Setzer State Fish Hatchery is located in Pisgah National Forest on USDA Forest Service land and is maintained and operated by the North Carolina Wildlife Resources Commission (NCWRC). WRC has a Special Use Permit to operate the facility and is renewing it as part of this project. The project site is located at 1401 Fish Hatchery Road, Brevard NC 28712. The total area of the property is +/-41.2 acres with +/- 16.5 acres to be disturbed during construction activities. The site is in the French Broad River Basin and does not reside in an area subject to Riparian Buffer requirements. The site primarily drains from west to east and there are no existing wetlands on-site. The impervious areas currently on-site consist of buildings and asphalt pavement. The remaining pervious area is grass and considered to be in good condition. The soils on-site are a mix of A and B soils. Most of the A-rated soils are covered up by impervious area, therefore, we assumed B soils in our model. The project site is bordered by the Davidson River to the north and Cedar Rock Creek (commonly known as Grogan Creek) to the south, with small tributaries in between. Both streams are classified as trout and high-quality waters. BASIS OF DESIGN Project Density According to the North Carolina Code of Ordinances, the maximum percent built-upon area for a low-density project is 12%. Given solely this information, the proposed project would be classified as a low-density project. However, after discussion with a state stormwater regulator, we will be following high-density project requirements since stormwater flow will be concentrated into proposed conveyance systems. See the table below for the proposed built-upon area and project density calculations. The proposed project introduces 1.88 acres of new impervious area. Project Density Calculation Total Property Area 41.17 ac Existing Built-Upon Area 6.84 ac Proposed Condition Built-Upon Area 8.72 ac Project Density 5.47% % MCG ILL ASSOCIATES 55 BROAD STREET,ASHEVILLE, NC 28801/828.252.0575/MCGILLASSOCI ATE S.COM 2 Stormwater Management Narrative Bobby N. Setzer State Fish Hatchery Renovation March 2024 Stormwater Conveyance The stormwater networks were designed using the 25-year/5-minute storm intensity with Rational Method and open channel capacities. See the stormwater pipe calculations in Appendix C for capacity calculations. Stormwater Quality The stormwater control measures have been designed to meet North Carolina requirements by treating the runoff from the 1" storm for at least the net added impervious area from the project. The 1" design volume was calculated using Discrete NRCS Method for the entire area draining to the stormwater control measure. Per the NCDEQ Erosion Control Manual, stormwater outlet measures are required to pass the 10-year/24-hr storm without causing erosion. METHODOLOGY Time of Concentration Time of concentration (ToC) was calculated for the stormwater management models using the NRCS TR-55 method. Calculated ToC for the stormwater networks were found to be less than 5 minutes. Therefore, an assumed 5-minute minimum ToC was used for all storm drainage pipe calculations. Hydrologic Methodoloc NRCS TR-20 Method of stormwater analysis was used to model the pre- and post-developed drainage areas and size stormwater management via HydroCAD. NOAA Atlas 14 Precipitation Depth Table for the site was used for this method. Rational Method of stormwater analysis was used to size storm pipes and inlets. NOAA Atlas 14 Precipitation Intensity Table for the site was used for this method. Site Soils and Cover Type The NRCS Web Soil Survey Map with Hydrologic Classification Groups was used to assign the appropriate curve numbers based on the existing soil types and ground covers present on site. The soils on-site are a mix of A and B soils. Most of the A-rated soils are covered up by impervious area, therefore, we assumed B soils in our model. The same ground cover curve number assumptions were made for both the pre- and post-developed site. The curve number for the impervious areas was assumed to be 98 and the rest of the pervious area was good grass cover (CN of 61). Composite curve numbers have been calculated for the pervious and impervious areas separately for the drainage area identified based on the uses defined above and delineated within each drainage area. MCG ILL ASSOCIATES 55 BROAD STREET,ASHEVILLE, NC 28801/828.252.0575/MCGILLASSOCI ATE S.COM 3 Stormwater Management Narrative Bobby N. Setzer State Fish Hatchery Renovation March 2024 DESIGN SUMMARY The project site consists of three existing stormwater conveyance systems, two of which discharge to the Davidson River just north of the project site, and one that discharges into Cedar Rock Creek (commonly known as Grogan Creek) to the south. The system that flows to Grogan Creek first goes to an existing stormwater pond that is no longer maintained; the pipe discharge of the pond has not been found. The remainder of the site that is not captured by existing stormwater conveyance measures sheet flow towards both Davidson River and Grogan Creek. The flow patterns of the stormwater conveyance systems will be relatively similar between existing and proposed conditions. The post development conveyance systems will continue to discharge to nearly the same analysis points as in the existing condition. Stormwater Conveyance The site contains multiple stormwater networks that convey stormwater either into the Davidson River or the proposed wetland. These stormwater networks capture runoff from the impervious areas from the building structures and the associated roads and parking areas. The stormwater networks have been designed to convey the 25-year storm. See the stormwater pipe drainage areas map and calculations in Appendix B and D for additional information. The existing conditions of the outfalls today have not caused erosion problems in the stream and our proposed improvements have lowered discharge velocities due to our increased pipe size with only minimal impervious area increases. To increase the factor of safety with our plan, we have added an impact curb to both HW A and HW C to further reduce the velocity. Appendix L shows the velocity calculations with the curb added for each outfall and those are 2.75 ft/s for HW A and 2.92 ft/s for HW C. A typical stable streambed velocity for the observed characteristics of the Davidson at our outfalls is 5 ft/sec and the flow rate observed during a normal flow depth was 3 ft/sec. Based upon this data, the receiving streambed will be stable at the outfalls A and C. Stormwater Quality—Stormwater Wetland The stormwater wetland was dimensioned and designed using both the NCDEQ Stormwater Design Manual Section C-4 and the Stormwater Wetland Calculations spreadsheet provided in Appendix E. The wetland's temporary pool volume has been sized based off the 1" design volume as calculated in the Discrete NRCS Method in Appendix E. The emergency overflow is activated after the 50-year storm event. Note that where the NCDEQ Stormwater Design Manual Section C-4 guidelines differ from the NCDEQ Wet Detention Basin Supplement guidelines, the Design Manual was used. A summary of all Minimum Design Criteria (MDC) for Stormwater Wetlands are provided in the table below: MCG ILL ASSOCIATES 55 BROAD STREET,ASHEVILLE, NC 28801/828.252.0575/MCGILLASSOCI ATE S.COM 4 Stormwater Management Narrative Bobby N. Setzer State Fish Hatchery Renovation March 2024 MDC MDC Description Notes Number 1 Temporary Ponding Depth See Wetland Calculation 2 Peak Attenuation Depth Additional Volume Provided 3 Surface Area See Wetland Calculation 4 Soil Amendments See Sheet C-140 5 Location of Inlets and Outlet Inlet and Outlet at opposite ends 6 Forebay See Wetland Calculation 7 Non-Forebay Deep Pools See Wetland Calculation 8 Shallow Water Zone See Wetland Calculation 9 Temporary Inundation Zone See Wetland Calculation 10 Drawdown Time See Wetland Calculation 11 Protection of the Receiving Stream See Wetland Calculation 12 Landscaping Plan See Sheet L-103 13 Shallow Water Plantings See Sheet L-103 14 Temporary Inundation Zone Plantings See Sheet L-103 15 Dam Structure and Perimeter Slopes See Sheet C-140 16 No Cattails See Sheet C-140 17 Trash Rack See Sheet C-140 According to wetland MDC 6, the forebay is best colonized by plants. In order to accommodate this and to ease maintenance of the forebay, no rip-rap outlet protection was provided in the forebay. Appendix L demonstrates that the velocity of the submerged influent storm water is greatly reduced within the forebay and will not cause erosion. Rip-rap outlet protection is provided for the stormwater wetland discharge into Grogan Creek. The wetlands captures and treats just over 3 acres of impervious area, both proposed and existing. This far exceeds the amount of impervious area introduced as part of this project. During the 1-yr, 24-hour storm, the proposed discharge from the stormwater wetland is less than the existing conditions; minimizing hydrologic impacts to the receiving channel. Permanent Ditches Permanent ditches were dimensioned and designed with NCDEQ Erosion and Sediment Control Planning and Design Manual Section 6.21. The ditches were designed for the 25-year storm. The flows and velocities utilized for sizing were sourced from both the stormwater network calculations and Hydraflow Civi13D extension. Rip Rap Outlet Protection/Aprons Rip rap outlet protection/aprons were dimensioned and designed with NCDEQ Erosion and Sediment Control Planning and Design Manual Section 6.41 and Appendix Section 8.06. The outlet protection was designed using the 10-year/24-hour peak runoff. The flows and velocities utilized for sizing were sourced from both the stormwater network calculations, Hydraflow Civi13D extension, and HydroCAD model. MCG ILL ASSOCIATES 55 BROAD STREET,ASHEVILLE, NC 28801/828.252.0575/MCGILLASSOCI ATE S.COM 5 Appendix A — SCM Drainage Areas Map z O PLAN O z W ry W U H Q _ _ co LL LLI H Q N 0-1 N H W U) 10 Lu ��� \ r/�/// 1 1 _r/ // /� I ��r —_ —/ i� --f`-- —,4v— 111 ^( I 1 I / �1 / I r / / � ��= \ \ ~ —\I Z U) f �� ✓J r \ f 1 �/ `t\ ` \ W L` t,_J _=ice_ \ - �� ��� ' �f `i / i/iZ\-`�_` �Yo� \ 1\?jams -'`\: �' - � - - - �Ji^ \_ O / l / \ate%-� -�\ _ ti-� -- --_= ._ f< / 1 \ .—��—��.,= ---1— — r — — ,� �1 .J /-/ l✓ o/ "� p p Y\ \ ti` s^_- 2340 '� ``� / /'aJ�I� �- /� n L (� \ z DAVIDSON RIVER /y i i V i��- -�. i - 1_ i'! `` •%l=7- -= ..- '':�f \ f �%�--- -- I N � -- `�"�ti� ' J \ �� --� ._.�-_ —� JU i = _\ � �L� �` �.-� o 6 1 / fI ✓ \ - - ��n- _� -r - - -1. - ...'_-T<-•r-mil�-• - --- \ O ^✓ - ... f --'" = }, - -^ Y` � // ;� \_ �, � � r � v;— ^� — —� 4.77 ACRES ` �� -_ / %' r -- \ -\ - / �_� % ����f _'-��_-� = _=��=L I \ - -ti (3.06 ACRES IMPERVIOUS) \��f 1 \rr \ � _ -/� -tip �=�- 1 TELL ��v _ZDA VIDSON R1 J / I -� e °/ � .� j" \ JIB `--•/ /1 ` \ � �' ti \• r � —_ —_�-'—-- � �\—L� . �✓'� � ,�/ JJ J y1) r j rJ ✓ J✓_-' ✓' MR l TOP1:BEECH t 1 —-- —✓ --,-� -r' � f J ——T—————T -----T— T --T---5--T---———T-7 T-----T s T � -` -SIGN / r r \ --W—=/--W —' D W-----W� r\ ^ / I to J S N \ \ N 7 1 1 1 N N / --J o fi o Z Ll jt - _ ----___,----- \— —T--- � T--- I 2 i/ \ r----------- I \ \� 2340 O`\\ i \\ S� ��s \i i ■ 3g0� '� �// I / I I X X� l �V-) L_- 71 `1. - l �! 2 -y r II I I v � J 1 x X �cLINEE --------------- - WETLAND DRAINAGE AREA VIA ROOF DRAINS r r \` AND STORM WATER CONVEYANCE SYSTEM D BEN C (TYP) SIGN I'SIGN !l -SIGN \BENCH \ / BENCH / - 0 r\ \�-- / / i i= y \r l ti SI - 2340 -771 77 nn L / SUP �( ` `/ SI 2340 - I z 2340I � 2380 \ '�� •yh I � \ �� CREEK i- g0 - - - Q \ A ^� / \ / 1 / \'— GROGAN 0 LLI J \ \ -1110 H IX 2 2400' WLu -----SPRING .101j a J � / U \ ✓ \ 2320 U) z U \ Q1 0 O. W IU Q I \ I _ U LL W I I Q H W N H W U) mz BOBBY N. SETZER $� 0 4a 8a 160 SHEET \\\��11111111// ;'����"E Ao°� STATE FISH HATCHERY RENOVATION U O °�� °� � GRAPHIC SCALE DIVISION VALUE = 80 FEET SCM DRAINAGE AREA MAP TTTT 3 ® 55 Broad Street - `ems SEAL 9�°� z Asheville NC - a 0SEAL z - � _ �y SCO PROJECT # 19-20324-02A a�` �V ` OFFICE MANAGER DESIGNER EX=ST1 828.252.0575 = `' NC WILDLIFE RESOURCES COMMISSION M. CATHEY N. CROOM o °FNGIN���°°P O NC Firm License # C-0459 2,�°°°°°°°°° SF, ''•,,CHAE� ����`� PROJECT MANAGER REVIEWER DATE PROJECT# FUNDING# mcgillassociates.com �„IIII„� TRANSYLVANIA COUNTY NORTH CAROLINA a NO. DATE BY DESCRIPTION K. SEAMAN B. CATHEY OCTOBER 2023 19.00124 SCO #19-20324-02A Appendix B — Stormwater Pipe Drainage Areas Map z O PLAN O z W ry W U H Q _ _ co U- ui H Q N co 0-1 N H W co Z } 00 00 O m Z O U) U f O � U Lu •J(11 / J , \ �'/ - ,/ \ - �----_-ram _ LL —2360 % // 1 t �_7'J ( v�� / \\\ I ( /' /� r / f—_ — z X. f L \ � /� � � J 111 !� —� \_, � 111 J f \ � � /( r• ti/'—�Y /��� J JJ // _ J 1l\� i�—!mot `„%���c ✓J / �/ ) / 11 J \ / r _�� --� S � j /%/ \ /� o� - ` < �-�= �� f/i j/// �1���j ✓ f f _ '` / — l / I / / / RIVER pgVlpS0N — — ( < lvr \ f In �� '�` " I z�" _�60 p , 1 f� \�=J l — ✓ f -) fQ \/` /` Jv _ 7 "= ��—`�^�- '�� �_- ( ( l \ AVl TEL DSON RIVER / •�� FMR_VII }ogfx /r~ TO�PI:BEECH � -_�— /'�r- �•`----- �—`�—� �� -J /f`'' ---"_ �� -/ r)//-- / GJGj \ 1 � 2� 1 '�:Js, � `'T8 r��/ _ 1`— — --T T-----T— T—— T---"—T-----T—T----T-----T R---T� TSIGN CB—C2 — — CB—C4 CB—05 _ C1 CB C3 / CB D12(B) ✓ Lod I p / I / _ ` ) LO / w-----w—=---w-- --w-----w—� I r7 r0 r7 r0 J /� N - N N N � / � �'�_ �� — � � '' �--ELECT Ic � �f t r = < l\ � � ■ e \ /�\ CI—D13 --- —------- — �� m b CB—D9 _ — v \ CB—A4 M . f ————_� CB—D4(B)` / — 1 CB D11(B) a o \ \ / CB B1 a5o/ , � , I / I CB D6 x x l I d1 3 _ 11 � f o y SUP ti 1 O - �fL/41 JL/`o f5 1 I ry r- -,- - -\------------ ` GRAVEL_ GRJtVErt ——— _ ✓J / ) t7 V VIM — o 1 `1 , / / G/ , I ti,Jl A\ BENC (TYP) SIGN/ T \� // ("=— k L----J3 ELL , ,: \ ` .� A, / UP UP L /� _.0 ` � � � W \ o (SIGN ySIGN CB—Ai /� _ _ _ BENCH Q 1 ~,. /��/� BENCH U if Ln s / / ��_ --,-``.�.1~ �° SI - 2340 / 04 Q CB—A3 BE O BE�C sIGN N • ` ' SI / / cam.— —'I �-..� �.. /I \\ `--- N�„o /. . N234 ✓ I / — i CB—A2 �� 13 GREEK / 234 I Q \ !Pa ti \\ \\ / \_ FROG j i y�2360 0 W 2380 0 2390 \ 239 \ \\ 2380 c� U) \ / / 2380 w \ w oI/ / 00 2420 \ /Lu / 2 2400�0� Z g z430 G \\\ SEE STORMWATER PIPE CALCULATIONS SPRIN �6p ti SPREADSHEET FOR STRUCTURE Lu DRAINAGE AREAS AND CALCULATIONS 2370 LL Q 0 \ � I W I N .\ H W U mz BOBBY N. SETZER 80 0 40 80 160 SHEET \\�,,,�I III11/o � E AO°° STATE FISH HATCHERY RENOVATION ;�aaoF ti�� � � STORMWATER PIPE 55 Broad Street = °°� 9 ° O GRAPHIC SCALE DIVISION VALUE = 80 FEET R , SCO PROJECT # 19-20324-02A DRAINAGE AREA MAP z Asheville, NC 28801 - B 042470 o Z - J OFFICE MANAGER DESIGNER N �► 828.252.0575 ° � NC WILDLIFE RESOURCES COMMISSIONEX=ST2� F°a. /ycINE��oo ; O M. CATHEY N. CROOM NC Firm License # C-0459 ///, ..°°°°°° ' CNAE\- PROJECT MANAGER REVIEWER DATE PROJECT# FUNDING# mcgillassociates.com 011111HO TRANSYLVANIA COUNTY NORTH CAROLINA a NO. DATE BY DESCRIPTION K. SEAMAN B. CATHEY OCTOBER 2023 19.00124 SCO #19-20324-02A Appendix C — Ditch Drainage Areas Map z O PLAN O z W ry W U H Q _ _ co U- W H Q N co 0-1 N H W co Z m O i _ t, w —2360 — \ I � _— ` \ \4 ) Lu Lu �� Z �j \� \ \ {� � L W =239��fiii�%ir1Li ( �_'!='ice=1—'� z`�="��`'�`= �/'��__�-.-- — }`\�J �—i �•��' -1 -"'� "J .-- —�1� — / // ) ` _ / --\ 1 JJ1 /r (I } / 1 \ N � �� `", -\ � \\ � \�� � � \ � j 0 34p _�_ � Z RIVER I —L- 1 — i r _.._ =- — i{�\-- ='— /r ( r DAVIDSON ` J _ _ _ ~� 1�C�� / f /— / // \ l� --�� _1 to —``�� C I N I — 4�'`—_L�-1 —`' \ ..i( � �` —� �_ JU 1 \1 0 ,\ �L�—�� ��-�Y \ `�\ O 6— I �i ---- — l I 1 r—_ �23 D �f-`r 1 Li- \_`1 _ �` - -�^� —r = `— `T<i="-`'��it tip-• i--— r \ \ \ I Z n l^J'1 - • V"1'- .i i-_, .� --may t _ -'-^-�= w — `- !fr /J ZDAVIDSON RI ER JTEL: tr / s I r — �'J` i \ / T o ? I• 1 t 1��'x o \ `--L TOP1•BEECH 30" i .o� --�� T—— T—----T— ---T—————T——— " —T --T—T--- ---TS-f�� DRAINAGE AREA OF WORST �� WORST — o I WORST CAS�(:) CASE DITCH. DITCH CONDITIONS \ CASE 7 FF N N III LL APPLIED TO OTHER PROPOSED — /A DITCHES ON—SITE. i CC 77 o "1 5D�- ✓ . �- -^''f � I I O ) 1 I X• x_ I d- z� `�e ,a\ \ \ \ rn 3 J rn X Et-LINE o SSA T oCo-� `Fl O y— —r-- — — `� J \-- ---- - /f/--J GRAVEL— GRAVE Jl'\ BEN�C/F�V(TYP) SIGN/ ELL P � 1� J '� ��. //G :P U ��� y--\D( /^\ / X 1 I SI i DRAINAGE AREA OF WORST CASE DITCH ALONG RACEWAYS. \\ ' a/ �M� s ---�/ ' c�` /��/� AREA PRIMARILY FROM ROOF DRAINS. DITCH CONDITIONS _ APPLIED TO EACH PROPOSED DITCH ALONG RACEWAYS. — 1 N / _OIGN •UP SI // / /� ��--- —2340�------I I --� /I �� // 7 Oup / \ i J —_—— _Nc " K ./ 2340��p / M2380 / `\\> !P' / / \ / ti� `\ \ / �. \— SRO AN / ti�060 ?3902310 2380 310 \ / w \ \ a 2A00 \�\ 0/gIz2420 ———— — Lu 24000 O 2 CD w zSp 1 / SPRING U \ 2370 Z W _ H \�\ Q I U \ I I L W I Q IH U W N H W mz BOBBY N. SETZER $� 0 40 8a 160 SHEET \\\��11111111// ,'����"E AO°a STATE FISH HATCHERY RENOVATION 19 ;�as OF ti�� STORMWATER DITCH DRAINAGE 55 Broad Street = °�� 9 O GRAPHIC SCALE DIVISION VALUE = 80 FEET JE ® - SEAL - _`�<C, SCO PROJECT # 19-20324-02A AREA MAP Asheville, NC 28801 =�B 042470 ,�QZ, VV OFFICE MANAGER DESIGNER EX=ST3 828.252.0575 -�`�a `' NC WILDLIFE RESOURCES COMMISSION M. CATHEY N. CROOM o aFNGIN���a°P� O NC Firm License # C-0459 2//,o.. aaaaa SF, ''•, CHAE� PROJECT MANAGER REVIEWER DATE PROJECT# FUNDING# mcgillassociates.com TRANSYLVANIA COUNTY NORTH CAROLINA a NO. DATE BY DESCRIPTION K. SEAMAN B. CATHEY OCTOBER 2023 19.00124 SCO #19-20324-02A Appendix D — Stormwater Pipe Calculations STORM DRAIN PIPES Pipe Characteristics Rational Method Calculation Q=CiA Manning's and Inlet Control Values for 25-YR Design Outcomes Upstream Weighted 25-YR Rainfall 10-YR Rainfall Headwater HDS-5 Manning's Inlet Control Pipe Size Upstream Downstream Length Drainage Area Drainage Incremental Total(CFS) Incremental Total(CFS) Roughness Controlling Pipe ID Structure ID Structure ID Structure (FT) Inv.In Inv.Out Diameter(IN) (SF) Area (AC) Runoff Intensity Intensity (CFS)25-YR 25-YR (CFS)10-YR 10-YR Pipe ID Pipe Material Coef.(n) Pipe Slope Available Inlet Capacity Capacity Adequacy Factor Rim Coef. C IN/HR IN/HR F Ref.No. CFS CFS Comment Al CB-Al CB-A2 2356.80 93.5 2353.81 2351.94 15 9349 021 0.31 9.19 N/A 0.62 0.62 N/A N/A Al HDPE 0.012 2.00% 2.99 1 9.90 9.05 OK Inlet A2 CB-A2 CB-A3 2354.50 62.9 2351.84 2351.53 15 2690 0.06 0.30 9.19 N/A 0.17 0.79 N/A N/A A2 HDPE 0.012 0.49% 2.66 1 4.91 8.31 OK Manning's A3 CB-A3 CB-A4 2355.00 146.8 2351.43 2350.64 15 12191 028 0.92 9.19 N/A 2.36 3.15 N/A N/A A3 HDPE 0.012 0.54% 3.57 1 5.13 10.17 OK Manning's A4 CB-A4 JB-A5 2354.35 73.6 1 2350.54 234920 1 18 38656 0.89 0.88 1 9.19 N/A 7.18 10.33 N/A N/A A4 I HDPE 0.012 1.83% 3.81 1 1 15.38 14.87 OK I Inlet A5 JB-A5 JB-A6 2356.83 67.1 2349.10 2348.61 24 0 0.00 0.00 9.19 N/A 0.00 14.16 N/A N/A A5 HDPE 0.012 0.72% 7.73 1 2084. 39.84 OK Manning's A6 JB-A6 HW-A 2354.66 127.7 2348.61 2347.75 24 0 0.00 0.00 9.19 N/A 0.00 14.16 N/A N/A A6 HDPE 0.012 0.67% 6.05 1 20.11 3420 OK Manning's B1 CB-B1 JB-B2 2357.21 38.2 2352.23 2351.85 15 43751 1.00 0.41 9.19 N/A 3.83 3.83 WA N/A B1 HDPE 0.012 0.99% 4.98 1 6.98 12.53 OK Manning's B2 JB-B2 JB-A5 2357.28 105 2351.75 2350.70 15 0 0.00 0.00 9.19 N/A 0.00 3.83 N/A N/A B2 HDPE 0.012 1.00% 5.53 1 7.00 13.33 OK Manning's C1 CB-101 JB-C2 2352.93 238.5 2348.37 2344.58 15 1568 0.04 0.74 9.19 N/A 024 0.24 N/A N/A C1 HDPE 0.012 1.59% 1 4.56 1 8.82 11.88 OK Manning's C2 JB-C2 CB-C3 2350.50 238.5 2344.48 2341.18 15 17193 0.39 0.95 9.19 N/A 3.45 3.69 N/A N/A C2 HDPE 0.012 1.38% 6.02 1 8.23 14.02 OK Manning's C3 CB-C3 CB-C4 2348.39 238.5 2341.08 2338.58 18 26755 0.61 0.80 9.19 N/A 4.52 8.21 N/A N/A C3 RCP 0.013 1.05% 7.31 1 10.75 2226 OK I Manning's C4 CB-C4 CB-05 234425 351.4 2338.48 2336.51 24 20461 0.47 0.78 9.19 N/A 3.37 11.57 N/A N/A C4 RCP 0.013 0.56% 5.77 1 16.94 33.17 OK I Manning's C5 CB-05 HW-C 2339.76 79.2 2336.41 2335.01 24 32297 0.74 1 0.86 9.19 N/A 5.86 17.44 N/A N/A C5 RCP 0.013 1.77% 3.35 1 30.08 22.42 OK Inlet D1 JB-D1 JB-D2 2351.36 238.5 2344.74 2341.18 18 15031 0.35 0.95 9.19 8.05 3.01 3.01 2.64 2.64 D1 HDPE 0.012 1.49% 6.62 1 13.90 21.01 OK Manning's D2 JB-D2 JB-D3 2347.69 238.5 2341.08 2337.51 24 14982 0.34 0.95 9.19 8.05 3.00 6.02 1 2.63 527 D2 HDPE 0.012 1.50% 6.61 1 29.98 3620 OK Manning's D3 JB-D3 JB-D4 2344.05 77.4 2337.41 2336.52 24 15094 0.35 0.95 9.19 8.05 3.03 9.04 2.65 7.92 D3 HDPE 0.012 1.15% 6.64 1 2628 3629 OK Manning's D4 JB-D4 JB-D5 2343.47 245.6 2336.42 2333.84 24 0.00 0.00 9.19 8.05 0.00 9.04 0.00 7.92 D4 HDPE 0.012 1.05% 7.05 1 25.12 37.66 OK Manning's D4(B) CB-D4(B) JB-D4 2343.51 6.8 2340.00 233921 15 2238 0.05 0.45 9.19 8.05 0.21 9.25 0.18 8.10 D4(B) HDPE 0.012 11.62% 3.51 1 23.85 10.19 OK Inlet D5 JB-D5 CB-D6 2339.79 7.7 2333.74 2333.70 24 0 0.00 0.00 9.19 8.05 0.00 9.25 0.00 8.10 D5 HDPE 0.012 0.52% 6.05 1 17.66 34.19 OK I Manning's D6 CB-D6 JB-D7 2339.37 20.6 2333.60 2333.50 24 36697 0.84 0.74 9.19 8.05 5.70 14.95 4.99 13.10 D6 HDPE 0.012 0.49% 5.77 1 17.08 33.16 OK Manning's D7 JB-D7 JB-D8 2340.45 106.6 2333.40 2332.87 24 0 0.00 0.00 9.19 8.05 0.00 14.95 0.00 13.10 D7 HDPE 0.012 0.50% 7.05 1 1728 37.65 OK Manning's D8 JB-D8 CB-D9 2340.92 26 2332.77 2332.64 24 0 0.00 0.00 9.19 8.05 0.00 14.95 0.00 13.10 D8 HDPE 0.012 0.50% 8.15 1 17.33 41.11 OK Manning's D9 CB-D9 JB-D10 2339.54 562 2332.54 233226 24 7767 0.18 0.57 9.19 8.05 0.93 15.89 0.82 13.92 D9 HDPE 0.012 0.50% 7.00 1 17.30 37.48 OK Manning's D10 JB-D10 JB-D11 2339.79 59.8 2332.16 2331.86 24 0 0.00 0.00 9.19 8.05 0.00 15.89 0.00 13.92 D10 HDPE 0.012 0.50% 7.63 1 17.36 39.51 OK Manning's D11(B) CB-D11(B) JB-D11 2338.76 16.6 2335.82 2335.45 15 12345 028 0.51 9.19 8.05 1.33 1.33 1.16 1.16 D11(B) HDPE 0.012 223% 2.94 1 10.45 8.95 OK Inlet D11 JB-D11 JB-D12 2339.75 1092 2331.76 233120 24 0 0.00 0.00 9.19 8.05 0.00 17.21 0.00 15.08 D11 HDPE 0.012 0.51% 7.99 1 17.55 40.62 OK Manning's D12(B) CI-D12(B) JB-D12 2337.80 178.4 2334.77 2332.99 15 12573 029 0.95 9.19 8.05 2.52 2.52 221 2.21 D12(B) HDPE 0.012 1.00% 3.03 1 6.99 9.12 1 OK Manning's D12 JB-D12 CI-D13 2337.65 163.4 233120 2330.00 24 0 0.00 0.00 9.19 8.05 0.00 19.73 0.00 1728 D12 HDPE 0.012 0.73% 6.45 1 21.00 35.62 OK Manning's D13 CI-D13 FES-D 1 2335.61 23.9 2330.00 2329.67 24 37957 0.87 0.95 9.19 8.05 7.61 27.34 6.66 23.95 D13 HDPE 0.012 1.38% 5.61 1 28.80 32.59 OK Manning's WP Outlet WP Box HW 2336.00 86.9 2332.00 2331.50 (2)24 See HydroCAD Reports N/A N/A WP Outlet RCP 0.013 0.58% 4.00 1 #VALUEI #VALUEI #VALUEI #VALUEI Notes: 1. Inlet control capacities are calculated using Equation 28 located in the Federal Highway Administration publication HDS-5-Hydraulic Design of Highway Culverts 2.Calculations do not take into account reduced flow on account of oversized pipe and outlet control structure- 3-Assumed flow of existing storm pipes crossing under US H WY-64 were determined by full pipe capacity at their as-built slope&depth- 4-See plan sheets for Temporary Stream Crossing details- 5- HDS-5 Inlet Reference Numbers are as follows- 1 RCP,Square edge w/headwall 2 RCP,Groove w/headwall 3 RCP,Groove End Projecting 4 CMP,Headwall 5 CMP,Mitered to Slope 6 CMP,Projecting 7 Circular,Beveled Ring,45o Bevel 8 Circular,Beveled Ring,37o Bevel P:\2019\19.00124-NC WRC-Bobby N Setzer State Fish H atche\Design\Calcs\Civil\Stormwater\19.00124-Pipe Calcs Appendix E — Stormwater Wetland Calculations id me 1 Stormwater Wetland Calculations Project Description: Selzer (Procedure and Calculations taken from NCDEQ Stormwater BMP Manual,11/20/2020 Revision) Project Number: 19.00124 Date: 11/21/2023 Calculated By: N Sawyer Step 1:Calculate Design Volume Step 2:Determine Minimum Surface Area at Maximum Ponding Depth Step 3:Verify Actual Pond Sizing and Determine Wetland Area Requirements User Input Cells Calculated Cells Step 1:Solve for Design Volume Minimum Volume Required(cf): 8,868 cf(Discrete NRCS Method)(Separate Calculation) Step 2:Determine Minimum Surface Area at Maximum Ponding Depth(Temporary Pool) Minimum Design Volume(cf): 8,868 cf Maximum Ponding Depth(in): 15 in MDC 1-Maximum Ponding Depth=15" Minimum Average Surface Area(sf): sf MDC 3-Minimum Surface Area Step 3:Verify Actual Pond Sizing and Determine Wetland Area Requirements Permanent Pool Elevation: 2,333.00 Permanent Pool Surface Area(sf):l 6,380.49 Temporary Pool Elevation: 2,334.251 Temporary Pool Surface Area(sf):l 10,203.35 Maximum Ponding Depth:-in OK Calculated Treatment Volume(cf): OK Minimum Area(sf) Maximum Area(sf) Area Provided(sf) Forebay Requirement(sf): 1,531 1,182.86 MDC 6-10 to 15% OK Deep Pool Requirement(sf): 510 1,531 829.70 MDC 7-5 to 15% OK Shallow Water Zone(sf): 3,571 4,5921 4,367.93 MDC 8-35 to 45% OK Temporary Inundation Zone(sf): 3,061 ,592 3,822.86 MDC 9-30 to 45% OK Drawdown Time(hours): 66 OK MDC 10-Drawdown between two and five days (Separate Calculation) 150 Ib/cf concrete 62.4 Ib/cf water Buoyancy Calculations basin id riser area(ft^2) height(ft) volume(ft^3) weight of water displaced(lbs) volume of concrete required(ft^3) anti-floatation dimension volume provided(ft^3) Factor of safety 1 48"x 72"Concrete Box 40 5 200 12480 83.2 8'x 8'x 3' 192 2.307692308 II . mcgill Dewatering/Drawdown Calculations Project Description: Setzer Project Number: 19.00124 Date: 11/29/2023 Designed Drawdown Storage Volume(cf): 8868 Water Surface Elevation(ft): 2334.25 Orifice Invert Elevation(ft): 2333 Orifice Size(in): 1.5 Coefficent of Discharge(See Table 1 Below): 0.6 Total Headwater"HW'(ft): 1 Area of Orifice(sq in): 0.012 Total flow"Q"(cfs): 0.064 HW/3 flow(cfs): 0.037 Dewater Time(hours): 66.295 User Input Cell -Calculated Cell Table 1 Typical Default Value 0.6 Square-edged entrance 0.59 Concrete Pipe,grooved end 0.65 Corrugated metal pipe,mitred to sloe 0.52 Corrugated metal pipe,projecting from fill 1 is Post-Development 1P Stormwater Wetland Subcat Reach on Link Routing Diagram for 19.00124-Stormwater Wetland Prepared by McGill Associates, Printed 3/21/2024 HydroCADO 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC 19.00124 - Stormwater Wetland Prepared by McGill Associates Printed 3/21/2024 HydroCADO 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 2 Rainfall Events Listing (selected events) Event# Event Storm Type Curve Mode Duration B/B Depth AMC Name (hours) (inches) 1 1-inch Type II 24-hr Default 24.00 1 1.00 2 2 10-yr Type II 24-hr Default 24.00 1 7.88 2 3 25-yr Type II 24-hr Default 24.00 1 9.30 2 4 50-yr Type II 24-hr Default 24.00 1 10.50 2 5 100-yr Type II 24-hr Default 24.00 1 11.70 2 19.00124 - Stormwater Wetland Type 1124-hr 1-inch Rainfall=1.00" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 3 Summary for Subcatchment 1S: Post-Development [49] Hint: Tc<2dt may require smaller dt Runoff = 1.30 cfs @ 11.98 hrs, Volume= 0.069 af, Depth> 0.17" Routed to Pond 1 P : Stormwater Wetland Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 1-inch Rainfall=1.00" Area (sf) CN Description 133,351 98 Paved parking, HSG B 74,516 61 >75% Grass cover, Good, HSG B 207,867 85 Weighted Average 74,516 35.85% Pervious Area 133,351 64.15% Impervious Area Tc Length Slope Velocity Capacity Description (min) (feet) (ft/ft) (ft/sec) (cfs) 5.0 Direct Entry, 5-min Subcatchment 1S: Post-Development Hydrograph I I ❑Runoff 1.30 cfs Type 1[24-hr 1rinch RainfallT1 .007 -- -- -- -- - - -- -- ...RUn'off Area=20T,-867-.Cff- RLjnOff,VQ1Ljme=0.060 Of Runoff'Depth>0.17" LL TcT5.'0 117ih PN=85 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 1124-hr 1-inch Rainfall=1.00" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 4 Summary for Pond 1 P: Stormwater Wetland Inflow Area = 4.772 ac, 64.15% Impervious, Inflow Depth > 0.17" for 1-inch event Inflow = 1.30 cfs @ 11.98 hrs, Volume= 0.069 of Outflow = 0.03 cfs @ 21.01 hrs, Volume= 0.025 af, Atten= 98%, Lag= 541.7 min Primary = 0.03 cfs @ 21.01 hrs, Volume= 0.025 of Secondary = 0.00 cfs @ 0.00 hrs, Volume= 0.000 of Routing by Stor-Ind method, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Peak Elev= 2,333.27' @ 21.01 hrs Surf.Area= 6,753 sf Storage= 1,922 cf Plug-Flow detention time= 375.8 min calculated for 0.025 of(36% of inflow) Center-of-Mass det. time= 202.7 min ( 1,099.0 - 896.3 ) Volume Invert Avail.Storage Storage Description #1 2,333.00' 42,807 cf Custom Stage Data (Prismatic)Listed below Elevation Surf.Area Inc.Store Cum.Store (feet) (sq-ft) (cubic-feet) (cubic-feet) 2,333.00 6,381 0 0 2,334.00 7,747 7,064 7,064 2,334.25 10,203 2,244 9,308 2,335.00 11,257 8,048 17,355 2,336.00 12,712 11,985 29,340 2,337.00 14,223 13,468 42,807 Device Routing Invert Outlet Devices #1 Primary 2,331.00' 24.0" Round Culvert X 2.00 L= 86.3' RCP, square edge headwall, Ke= 0.500 Inlet / Outlet Invert= 2,331.00' / 2,331.00' S= 0.0000 T Cc= 0.900 n= 0.011 Concrete pipe, straight & clean, Flow Area= 3.14 sf #2 Device 1 2,333.00' 1.5" Vert. Orifice/Grate C= 0.600 Limited to weir flow at low heads #3 Device 1 2,334.25' 36.0" W x 3.0" H Vert. Slots C= 0.600 Limited to weir flow at low heads #4 Device 1 2,335.00' 72.0" x 48.0" Horiz. Top of OCS C= 0.600 Limited to weir flow at low heads #5 Secondary 2,336.00' 10.0' long x 1.00' rise Emergency Spillway Cv= 2.62 (C= 3.28) Primary OutFlow Max=0.03 cfs @ 21.01 hrs HW=2,333.27' (Free Discharge) L1=Culvert (Passes 0.03 cfs of 23.83 cfs potential flow) 12=Orifice/Grate (Orifice Controls 0.03 cfs @ 2.20 fps) 3=Slots ( Controls 0.00 cfs) 4=Top of OCS ( Controls 0.00 cfs) Secondary OutFlow Max=0.00 cfs @ 0.00 hrs HW=2,333.00' (Free Discharge) L5=Emergency Spillway ( Controls 0.00 cfs) 19.00124 - Stormwater Wetland Type 1124-hr 1-inch Rainfall=1.00" Prepared by McGill Associates Printed 3/21/2024 HydroCADO 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 5 Pond 1 P: Stormwater Wetland Hydrograph 1.30 CfS ■Inflow /� �. w 1��I ❑Outflow Q Primary Inflow �f"�Iie;a-4.i/ /i2 iac ■Secondary 'i,Peak IF-I0v=2,333.V' Stbrgg',eT1#922, cf 0 LL 0.03 cfs 0.00 cfs 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type/1 24-hr 10-yr Rainfall=7.88" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 6 Summary for Subcatchment 1S: Post-Development [49] Hint: Tc<2dt may require smaller dt Runoff = 48.94 cfs @ 11.95 hrs, Volume= 2.423 af, Depth> 6.09" Routed to Pond 1 P : Stormwater Wetland Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 10-yr Rainfall=7.88" Area (sf) CN Description 133,351 98 Paved parking, HSG B 74,516 61 >75% Grass cover, Good, HSG B 207,867 85 Weighted Average 74,516 35.85% Pervious Area 133,351 64.15% Impervious Area Tc Length Slope Velocity Capacity Description (min) (feet) (ft/ft) (ft/sec) (cfs) 5.0 Direct Entry, 5-min Subcatchment 1S: Post-Development Hydrograph ----------�--+--�--�----- --�--�--�- - - �- �- +- r- �__ ■Runoff 48.94 cfs 50 T T F - - 1 - --T--r-- -----Tpe-uT2_ -h,r_- 45 --' i--L-- J --1--1--10ryr_R'aiofalP;7_8817 40 -------------7--!--!----------, -- Runoff Are';a 2a7,867_i9f - 35 ;RL;n pff Vp 1�m6=2.42 �f ------------------------------ ------------------------ 42$_O 30 Runoff Dupth>16.09';.. --r--i---i--r--r--r--r--r--i---i--r --r--r--r--r--r----r--r--r--r--r-- 25 Tc=5&O to i h 20 CAN=86 15 ---------- -- -- -- ----------- -- -- -- ------------- -- -- ----- 10 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type/1 24-hr 10-yr Rainfall=7.88" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 7 Summary for Pond 1 P: Stormwater Wetland Inflow Area = 4.772 ac, 64.15% Impervious, Inflow Depth > 6.09" for 10-yr event Inflow = 48.94 cfs @ 11.95 hrs, Volume= 2.423 of Outflow = 44.41 cfs @ 11.99 hrs, Volume= 2.183 af, Atten= 9%, Lag= 2.2 min Primary = 44.41 cfs @ 11.99 hrs, Volume= 2.183 of Secondary = 0.00 cfs @ 0.00 hrs, Volume= 0.000 of Routing by Stor-Ind method, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Peak Elev= 2,335.72' @ 11.99 hrs Surf.Area= 12,308 sf Storage= 26,011 cf Plug-Flow detention time= 92.4 min calculated for 2.178 of(90% of inflow) Center-of-Mass det. time= 42.4 min ( 828.7 - 786.4 ) Volume Invert Avail.Storage Storage Description #1 2,333.00' 42,807 cf Custom Stage Data (Prismatic)Listed below Elevation Surf.Area Inc.Store Cum.Store (feet) (sq-ft) (cubic-feet) (cubic-feet) 2,333.00 6,381 0 0 2,334.00 7,747 7,064 7,064 2,334.25 10,203 2,244 9,308 2,335.00 11,257 8,048 17,355 2,336.00 12,712 11,985 29,340 2,337.00 14,223 13,468 42,807 Device Routing Invert Outlet Devices #1 Primary 2,331.00' 24.0" Round Culvert X 2.00 L= 86.3' RCP, square edge headwall, Ke= 0.500 Inlet / Outlet Invert= 2,331.00' / 2,331.00' S= 0.0000 T Cc= 0.900 n= 0.011 Concrete pipe, straight & clean, Flow Area= 3.14 sf #2 Device 1 2,333.00' 1.5" Vert. Orifice/Grate C= 0.600 Limited to weir flow at low heads #3 Device 1 2,334.25' 36.0" W x 3.0" H Vert. Slots C= 0.600 Limited to weir flow at low heads #4 Device 1 2,335.00' 72.0" x 48.0" Horiz. Top of OCS C= 0.600 Limited to weir flow at low heads #5 Secondary 2,336.00' 10.0' long x 1.00' rise Emergency Spillway Cv= 2.62 (C= 3.28) Primary OutFlow Max=43.27 cfs @ 11.99 hrs HW=2,335.71' (Free Discharge) L1=Culvert (Passes 43.27 cfs of 55.08 cfs potential flow) 12=Orifice/Grate (Orifice Controls 0.10 cfs @ 7.83 fps) 3=Slots (Orifice Controls 4.17 cfs @ 5.56 fps) 4=Top of OCS (Weir Controls 39.01 cfs @ 2.75 fps) Secondary OutFlow Max=0.00 cfs @ 0.00 hrs HW=2,333.00' (Free Discharge) L5=Emergency Spillway ( Controls 0.00 cfs) 19.00124 - Stormwater Wetland Type/1 24-hr 10-yr Rainfall=7.88" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 8 Pond 1 P: Stormwater Wetland Hydrograph 48.94 cfs ' ■Inflow r--r-r--r-r--r-r--r-- -r--r-r--r-r--r-r--r-r--r-- ■Outflow !�� -- ■Primary ' y--r- --r----t----t---- -- -Inflow rea:4.772-iac ■Secondary AA Al 50 - --r- --r--I-- --I-- 44.41 cfs 45- &O- QqO--2 V�0 1 l i Cif - -- - -- ---- ---- ---- - - -- - -- ---- -t- -t- - 40 - - 35 w 0 25 - --F ---- � ---- ---- ---- ---- -- - -- ---- ---- ---- -- LL i 20 ---------------------- - ------------------------------ 15 AU-r--r-r--r----r----r--'r -'r-r--'r-r--r----r----r - ---r-- 0.00 cfs 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 11 24-hr 25-yr Rainfall=9.30" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 9 Summary for Subcatchment 1S: Post-Development [49] Hint: Tc<2dt may require smaller dt Runoff = 59.19 cfs @ 11.95 hrs, Volume= 2.970 af, Depth> 7.47" Routed to Pond 1 P : Stormwater Wetland Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 25-yr Rainfall=9.30" Area (sf) CN Description 133,351 98 Paved parking, HSG B 74,516 61 >75% Grass cover, Good, HSG B 207,867 85 Weighted Average 74,516 35.85% Pervious Area 133,351 64.15% Impervious Area Tc Length Slope Velocity Capacity Description (min) (feet) (ft/ft) (ft/sec) (cfs) 5.0 Direct Entry, 5-min Subcatchment 1S: Post-Development Hydrograph ---------- -- ---------------- --;-- ------------------- -- -----I--- 65 ■Runoff -- -- -- -- -- - -- 59.19 cfs -- ---------;-- - - 60 --1---1---1-- 1-- 1 --------1---1---1 ---1 -- 1--------1---1---11Type-N'2 -h;�-- 55 1 1 1 1 1 1 -- -- -- -- -- - -- -- -- 25r r-Rainfal[T9 07 - 50 p�1 ,1 45 --------'i-- --1-- Ir--iL--1il-----1I-- ---'R] of ATiia"iLViTN S1 ' /� 40 M Q Q Li =2. 1 35 Runoff'1D�pth�7.471" 0 30 -TcT5.0 M i h --r--1---1--r--t--r--r--r--1---1--r --r--r--r--r--r--1--r--r--t--r--r-- 25 --r--1---1--r--t--r--r--r--1---1--r --r--r--r--r--r--1--r--r-��r�r-- 20 --r--1---1--r--r--r--r-----1---1--r --r--r--r--r--r--1--r--r--r--r--r-- 15 --1---1---1--r--r--r--r--r--1---1--r --r--r--r--r--1---1--r--r--r--r--r-- 10 1 1 1 1 1 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 11 24-hr 25-yr Rainfall=9.30" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 10 Summary for Pond 1 P: Stormwater Wetland Inflow Area = 4.772 ac, 64.15% Impervious, Inflow Depth > 7.47" for 25-yr event Inflow = 59.19 cfs @ 11.95 hrs, Volume= 2.970 of Outflow = 54.29 cfs @ 11.99 hrs, Volume= 2.725 af, Atten= 8%, Lag= 2.1 min Primary = 54.29 cfs @ 11.99 hrs, Volume= 2.725 of Secondary = 0.00 cfs @ 0.00 hrs, Volume= 0.000 of Routing by Stor-Ind method, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Peak Elev= 2,335.83' @ 11.99 hrs Surf.Area= 12,471 sf Storage= 27,358 cf Plug-Flow detention time= 83.8 min calculated for 2.725 of(92% of inflow) Center-of-Mass det. time= 39.9 min ( 820.7 - 780.8 ) Volume Invert Avail.Storage Storage Description #1 2,333.00' 42,807 cf Custom Stage Data (Prismatic)Listed below Elevation Surf.Area Inc.Store Cum.Store (feet) (sq-ft) (cubic-feet) (cubic-feet) 2,333.00 6,381 0 0 2,334.00 7,747 7,064 7,064 2,334.25 10,203 2,244 9,308 2,335.00 11,257 8,048 17,355 2,336.00 12,712 11,985 29,340 2,337.00 14,223 13,468 42,807 Device Routing Invert Outlet Devices #1 Primary 2,331.00' 24.0" Round Culvert X 2.00 L= 86.3' RCP, square edge headwall, Ke= 0.500 Inlet / Outlet Invert= 2,331.00' / 2,331.00' S= 0.0000 T Cc= 0.900 n= 0.011 Concrete pipe, straight & clean, Flow Area= 3.14 sf #2 Device 1 2,333.00' 1.5" Vert. Orifice/Grate C= 0.600 Limited to weir flow at low heads #3 Device 1 2,334.25' 36.0" W x 3.0" H Vert. Slots C= 0.600 Limited to weir flow at low heads #4 Device 1 2,335.00' 72.0" x 48.0" Horiz. Top of OCS C= 0.600 Limited to weir flow at low heads #5 Secondary 2,336.00' 10.0' long x 1.00' rise Emergency Spillway Cv= 2.62 (C= 3.28) Primary OutFlow Max=52.70 cfs @ 11.99 hrs HW=2,335.82' (Free Discharge) L1=Culvert (Passes 52.70 cfs of 56.17 cfs potential flow) 12=Orifice/Grate (Orifice Controls 0.10 cfs @ 7.99 fps) 3=Slots (Orifice Controls 4.33 cfs @ 5.78 fps) 4=Top of OCS (Weir Controls 48.27 cfs @ 2.96 fps) Secondary OutFlow Max=0.00 cfs @ 0.00 hrs HW=2,333.00' (Free Discharge) L5=Emergency Spillway ( Controls 0.00 cfs) 19.00124 - Stormwater Wetland Type 1124-hr 25-yr Rainfall=9.30" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 11 Pond 1 P: Stormwater Wetland Hydrograph 59.19 CfS ■Inflow -+--r-+--+----+----+--I -+--r-+--r----+----+----+-- ■outflow I I I I I I I I I I I I I I I I I I I I�w n ■Primary 65 ■Secondary 60 54.29 cfs tolta„ =-277 358- 50 I I I I I I I I I I I I-- -Y--Y-Y--r--I--Y--I--Y--I-- --Y-Y--Y-Y--Y--I--r--I--Y--I--Y-- 4s u 35 �I ,i - --'i--'I-- --'I-- --'I-- --'I-- --'i- --'i--'Ii--i--i-- --i-- --i-- -- 0 30 LL - -- - -- ----+----+--- -- - -- - -- ---- ----+---- -- 25 - T--T-T--r--I--T----T --I- --T- -- - --T----r----T----T-- 20 - --L-J--L--1--1--1--1--'- -L-I--L-J--L--1--L--1--1--1--1- 1s 10 0.00 cfs 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 11 24-hr 50-yr Rainfall=10.50" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 12 Summary for Subcatchment 1S: Post-Development [49] Hint: Tc<2dt may require smaller dt Runoff = 67.80 cfs @ 11.95 hrs, Volume= 3.435 af, Depth> 8.64" Routed to Pond 1 P : Stormwater Wetland Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 50-yr Rainfall=10.50" Area (sf) CN Description 133,351 98 Paved parking, HSG B 74,516 61 >75% Grass cover, Good, HSG B 207,867 85 Weighted Average 74,516 35.85% Pervious Area 133,351 64.15% Impervious Area Tc Length Slope Velocity Capacity Description (min) (feet) (ft/ft) (ft/sec) (cfs) 5.0 Direct Entry, 5-min Subcatchment 1S: Post-Development Hydrograph I I I I I I I I I I I I I I I I I I I I I I I 75 p ■Runoff --1---1---1--r--r--r--r-----1 67.8� CfS -- -- --r--1---1--r-- -- --i--r-- 70 ' I I I I I I I I I I I 11 n _ Type '12- = 65 hl-r- 60 -- -- ' _50-vr_Ra',infa11=10.,150'7 55 -------+--+--+--+--+--+--1---i--+ --+ RUnoff Arta=207;867-0 - 50 -- -- -- -- -- Rtjnpffl-Vplpmle=14-3 - 45 � 40 w Runpff'IDepth>8.184�" I I I I I I I I I I I I 1 -----I---I--7--T--T--7--I-----I--� --7- T- 7--7- ---1--7 -7--T�--T--F-- 0 35 TLya7.lJ �� lL ---------- --1--L--L--------'--J --1--1--L--L-----'-- T 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 30 w'1 Q --r--1---1--r--r--r--r--r--1---1--r --r--r--r--r--r--1--r--r-C�Id�8�r 25 20 15 10 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 11 24-hr 50-yr Rainfall=10.50" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 13 Summary for Pond 1 P: Stormwater Wetland Inflow Area = 4.772 ac, 64.15% Impervious, Inflow Depth > 8.64" for 50-yr event Inflow = 67.80 cfs @ 11.95 hrs, Volume= 3.435 of Outflow = 58.16 cfs @ 11.98 hrs, Volume= 3.188 af, Atten= 14%, Lag= 1.7 min Primary = 58.16 cfs @ 11.98 hrs, Volume= 3.188 of Secondary = 0.00 cfs @ 0.00 hrs, Volume= 0.000 of Routing by Stor-Ind method, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Peak Elev= 2,335.97' @ 11.99 hrs Surf.Area= 12,667 sf Storage= 28,970 cf Plug-Flow detention time= 77.3 min calculated for 3.181 of(93% of inflow) Center-of-Mass det. time= 38.2 min ( 815.1 - 776.9 ) Volume Invert Avail.Storage Storage Description #1 2,333.00' 42,807 cf Custom Stage Data (Prismatic)Listed below Elevation Surf.Area Inc.Store Cum.Store (feet) (sq-ft) (cubic-feet) (cubic-feet) 2,333.00 6,381 0 0 2,334.00 7,747 7,064 7,064 2,334.25 10,203 2,244 9,308 2,335.00 11,257 8,048 17,355 2,336.00 12,712 11,985 29,340 2,337.00 14,223 13,468 42,807 Device Routing Invert Outlet Devices #1 Primary 2,331.00' 24.0" Round Culvert X 2.00 L= 86.3' RCP, square edge headwall, Ke= 0.500 Inlet / Outlet Invert= 2,331.00' / 2,331.00' S= 0.0000 T Cc= 0.900 n= 0.011 Concrete pipe, straight & clean, Flow Area= 3.14 sf #2 Device 1 2,333.00' 1.5" Vert. Orifice/Grate C= 0.600 Limited to weir flow at low heads #3 Device 1 2,334.25' 36.0" W x 3.0" H Vert. Slots C= 0.600 Limited to weir flow at low heads #4 Device 1 2,335.00' 72.0" x 48.0" Horiz. Top of OCS C= 0.600 Limited to weir flow at low heads #5 Secondary 2,336.00' 10.0' long x 1.00' rise Emergency Spillway Cv= 2.62 (C= 3.28) Primary OutFlow Max=57.34 cfs @ 11.98 hrs HW=2,335.94' (Free Discharge) L1=Culvert (Barrel Controls 57.34 cfs @ 9.13 fps) 12=Orifice/Grate (Passes < 0.10 cfs potential flow) 3=Slots (Passes < 4.51 cfs potential flow) 4=Top of OCS (Passes < 59.14 cfs potential flow) Secondary OutFlow Max=0.00 cfs @ 0.00 hrs HW=2,333.00' (Free Discharge) L5=Emergency Spillway ( Controls 0.00 cfs) 19.00124 - Stormwater Wetland Type 11 24-hr 50-yr Rainfall=10.50" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 14 Pond 1 P: Stormwater Wetland Hydrograph -�--L-J--L--1--1--1--1--�--1--�--�--L-1--L-J--L--1--L--1--1--�--1-- i I I I I I I I I I I I I I I I I I I - 67.80 CfS - -- ■inflow ■Outflow --I- -- - ---- -- ----- -1flonr Ar=e �4:7?2-a - ■Primary 75 -+--r-+--+----+----+----+--I --+-+--+-+--r----+----+----+-- ■Secondary 70 - -- - -- ----+---- CC'' �- I 7 6s - 58.16 cfs 60 - --; ---;---- ---- --; Stoea a=28'97a d I--, -,-- --I-- --I-- + ---- ----- - V - - -`� - --- 55 - --+- -- - ---+----+--I-- --+- --+- --+----+----+--I-- -- 50 - -- - -- ----+----+---- - - -- - -- ---- ----+---- - 45 u 40 /I - --r--1--r----+----+--r- r----r--1--r----r----+----+-- 3 35 � -r--r-r--r--I--+--I--r--I - --r-r--r-r--r--I--r--I--+--I--r-- LL I 30 - -- - -- ----+----+--- - - -- - -- ---- ----+---- - 25 20 -- -i-- --i-- --i--+--i- -i-- -i-- --i-- 15 --i--+ 10 0.00 cfs 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 1124-hr 100-yr Rainfall=11.70" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 15 Summary for Subcatchment 1S: Post-Development [49] Hint: Tc<2dt may require smaller dt Runoff = 76.38 cfs @ 11.95 hrs, Volume= 3.902 af, Depth> 9.81" Routed to Pond 1 P : Stormwater Wetland Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 100-yr Rainfall=11.70" Area (sf) CN Description 133,351 98 Paved parking, HSG B 74,516 61 >75% Grass cover, Good, HSG B 207,867 85 Weighted Average 74,516 35.85% Pervious Area 133,351 64.15% Impervious Area Tc Length Slope Velocity Capacity Description (min) (feet) (ft/ft) (ft/sec) (cfs) 5.0 Direct Entry, 5-min Subcatchment 1S: Post-Development Hydrograph 85 ------- -- --+--L--L--I-------- -- -- --L-- --+--1----- -- --+--L--+-- ■Runoff 801 76.38 cfs 75 - _ Ty'pe HY2-4-b',r I 70 --65 -1f001 r-Ra1nfaH=19-.7ff 60 ---------- -- -- -- ----------- -- RUn',off Area 207,867-tf - 55 ------- -- -- --------------'�--� --1R-pnpff-Vpl1 e=3 00 Of- m 50 -------L--L- -L--L--------�--L --L--L--L--L--- --L--L +- L--L-- w ----I --- Run----Depth>9.8t `° 40 --------i--li--li --+--i--i-----i--- --li--+--i--i-------l�Ta7.i -177fr1-- 35 6 _ 30 ------- --L--L--L--L-- -----'--L --L--L--L--L-------L--L-- -L--L-- 25 20 15 --------i-- --+-- -- --------i-- - -- -- -- -----i-- -- --+-- -- -- 10 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type 1124-hr 100-yr Rainfall=11.70" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 16 Summary for Pond 1 P: Stormwater Wetland Inflow Area = 4.772 ac, 64.15% Impervious, Inflow Depth > 9.81" for 100-yr event Inflow = 76.38 cfs @ 11.95 hrs, Volume= 3.902 of Outflow = 61.51 cfs @ 12.00 hrs, Volume= 3.652 af, Atten= 19%, Lag= 2.9 min Primary = 59.47 cfs @ 12.00 hrs, Volume= 3.643 of Secondary = 2.05 cfs @ 12.00 hrs, Volume= 0.009 of Routing by Stor-Ind method, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Peak Elev= 2,336.16' @ 12.00 hrs Surf.Area= 12,950 sf Storage= 31,460 cf Plug-Flow detention time= 72.9 min calculated for 3.652 of(94% of inflow) Center-of-Mass det. time= 36.8 min ( 810.3 - 773.5 ) Volume Invert Avail.Storage Storage Description #1 2,333.00' 42,807 cf Custom Stage Data (Prismatic)Listed below Elevation Surf.Area Inc.Store Cum.Store (feet) (sq-ft) (cubic-feet) (cubic-feet) 2,333.00 6,381 0 0 2,334.00 7,747 7,064 7,064 2,334.25 10,203 2,244 9,308 2,335.00 11,257 8,048 17,355 2,336.00 12,712 11,985 29,340 2,337.00 14,223 13,468 42,807 Device Routing Invert Outlet Devices #1 Primary 2,331.00' 24.0" Round Culvert X 2.00 L= 86.3' RCP, square edge headwall, Ke= 0.500 Inlet / Outlet Invert= 2,331.00' / 2,331.00' S= 0.0000 T Cc= 0.900 n= 0.011 Concrete pipe, straight & clean, Flow Area= 3.14 sf #2 Device 1 2,333.00' 1.5" Vert. Orifice/Grate C= 0.600 Limited to weir flow at low heads #3 Device 1 2,334.25' 36.0" W x 3.0" H Vert. Slots C= 0.600 Limited to weir flow at low heads #4 Device 1 2,335.00' 72.0" x 48.0" Horiz. Top of OCS C= 0.600 Limited to weir flow at low heads #5 Secondary 2,336.00' 10.0' long x 1.00' rise Emergency Spillway Cv= 2.62 (C= 3.28) Primary OutFlow Max=59.46 cfs @ 12.00 hrs HW=2,336.16' (Free Discharge) L1=Culvert (Barrel Controls 59.46 cfs @ 9.46 fps) 12=Orifice/Grate (Passes < 0.10 cfs potential flow) 3=Slots (Passes < 4.82 cfs potential flow) 4=Top of OCS (Passes < 81.32 cfs potential flow) Secondary OutFlow Max=2.03 cfs @ 12.00 hrs HW=2,336.16' (Free Discharge) L5=Emergency Spillway (Weir Controls 2.03 cfs @ 1.30 fps) 19.00124 - Stormwater Wetland Type 1124-hr 100-yr Rainfall=11.70" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 17 Pond 1 P: Stormwater Wetland Hydrograph -+--r-+--r--i--+--i--+--i -+--r-+--r--i--r--i--+--i--+-- LInflow 76.38 cfs ow -1 nflo Y /�"' re-a#4 f-/2-��-- ary -+--r-+--r----+----+----+--i + +85 ndary 80 -+--r-+--+----+----+----+--i -- +-- -+ r--i-- - -- -i -- 75 +--r-+--r- --+--i--+ 61.51 cfs 70 59.47 cfs StOt-ag6=3'11 60 C# 65 -+--r-+--r----+--i-- --r-+--r-+-- -i--r- -+----+-- 60 -+--r-+--+----+----+--i-- --+-+--r-+--r--i--+--i--+--i--+-- 55 -+--r-+--r----+----+--i-- --r-+--r-+--r--i--r--i--+--i--+-- 50 -+--r-+--+----+----+--i-- --+-+--r-+--r--i--+--i--+--i--+-- w , u ' 45 r--r-r--r----t----r--i-- --r-r--r-r--r- --r----t----r-- 3 0 40 -1--r- --+----+----+--i-- --+- --r- --r----+----+----+-- lL 35 -r--Y-r--r----t----Y--I- --r-r--r-r--Y----r----t----r-- 30 -+--r-+--r----+----+--i- --r-+--r-+--r----r----+----+-- 2S -r--Y-r--r----t----Y--I- --r-r--r-r--Y----r----t----r-- 20 z z -+--r-+--r----+----+--i- r-+--r-+--r--i--r--i--+--i--+-- 15 10 5 2.05 cfs 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Table of Contents Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC TABLE OF CONTENTS Project Reports 1 Routing Diagram 2 Rainfall Events Listing (selected events) 1-inch Event 3 Subcat 1S: Post-Development 4 Pond 1 P: Stormwater Wetland 10-yr Event 6 Subcat 1S: Post-Development 7 Pond 1 P: Stormwater Wetland 25-yr Event 9 Subcat 1 S: Post-Development 10 Pond 1 P: Stormwater Wetland 50-yr Event 12 Subcat 1S: Post-Development 13 Pond 1 P: Stormwater Wetland 100-yr Event 15 Subcat 1S: Post-Development 16 Pond 1 P: Stormwater Wetland mcgill Discrete NRCS Curve Number Method for Runoff Depth Project Description: etzer (Procedure and Calculations taken from NCDEQ Stormwater BMP Manual.3/15/17 Revision) Project Number: 9.00124 Date: 1/21/2023 NOR:This calalatl®is R be used m lieu of the 9unp@ Metlrotl when cmnbinetl wRh any HyticoCAD motlelmg Step 1:Determine Hydrologic Souls Group for the drainage area. Step 2:Divide the drainage area into land uses and assign appropriate curve numbers. Proposed Condition Step 3:Deteumine the precipitation depth,P.P is location specific. Step 4:Compute runoffdepth,Q,for my built upon area. Step 5:Compute runoff depth,Q*,for the remainder of the drainage area. Step 6:Compute runoffvolume from Q(built upon areas). Step 7:Compute ranoffvolume from Q*(remainder of drainage area). Step 8:Computer total ranoffvolume. Step 1:Determine Hydrologic Soils Group for the drainage area. Using the USDA Web Soil Survey website below,locate project area and determine best fit HSG. https://websoilsuwey.sc.egov.usda.gov/App/HomePage.htm Hydrologic Soils Group: �(A,B,C,or D) Step 2:Divide the drainage area into land uses and assign appropriate curve number(see Table 4 below). Impervious Area I Area(at) ITypeofUse HSG Curve Number Total Built Upon Area 133,35 11 Impervious(paved parking lots,roots,driveways,etc) 98 Pervious Areas Area(at) Type ofUse HSG Curve Number Land Use 1: 74,516 Pasture(>75%ground cover) B 61 Land Use 2: B #N/A Land Use 3: B #N/A Land Use 4: B #N/A Total Pervious Area sf Total Drainage Area sf Table 4:NSGs for North Carolina Soil Types Urbaq areas runoff curve numbers for SCS method(SCS 1986) Fully developed urban area Open Space clowns,parks,guff courses,etc.) Poor—oitipn(<60%grass rover) fib 79 86 89 Faircoudi8on(50%to 75%grass rover) 49 69 79 84 Good condinon(175%grass rover) 39 61 74 8n Impenaous areas Paved parking lots,roofs,driveways,e¢_ 98 98 98 08 Streets and mad.: Paved;curbs and stone sewers 98 98 98 98 Paved;.,an dit h— 83 89 98 98 Gravel 76 05 99 91 Did 72 82 95 88 Oevelcping urban areas Newly graded areas 77 86 91 94 Pasture(<60%ground cover or heavily grazed) fib 79 86 89 Pasture(50%to 75%ground rover or not heavily grazed) 49 69 79 64 Pasture(175%ground rover or lightly grazed) 39 61 74 W Meads Y—.o inmus grass,prolacLad bwrr gr�n9 and 30 56 71 78 generally mowed br hay Brush(<50%ground cover) 49 67 77 83 Brash(50%.75%ground cover) 35 56 70 77 Bms1,(,75%ground rover) 30 48 65 73 Woods(Forest litter, ,all trees,and bush desboyed by 45 66 77 83 heavy grating or regular burning) Woods(Woods are grazed but not burned,and some 36 60 73 79 forest liner rovers the soil) Woods(Woods are protected from grazing,and Meer and 30 55 70 77 brash adequately cover the soil) c mgill Step 3:Determine the precipitation depth,P.P is location specific. Precipitation Depth:�im P is 1.5"in Coastal Counties and P elsewhere.In SA waters,the DV is the difference between runoff volume pre-versus post-development for the 10-year storm(read value from the NOAA web site,using a storm duration equal to the time of concentration). Step 4:Compute runoff depth,Q,for any built upon area directly linked to surface waters(Conveyed through pipe). *All built upon areas should be using a CN of 98 for this step. S=�m Q=0.79 in S = 1000 10 CN Where: 5 = Maximum retention after rainfall begins(in) CN = Curare number(unitless) 4* — (P ) +o s) Where: Q' = Runoff depth(in) to = Rainfall depth(in) Step 5:Compute runoff depth,Q*,for the remainder of the drainage area. Areas CN Type of Use %ofTotal Area Composite CN 74,516 1 61 Pasture(>75 100% 61 #N/A 10 #VALUE! 0 #N/A 10 #VALUE! 0 #N/A 10 #VALUE! 0 Total Composite CN: 61 S=6.39344262 in Q=0.0127 in S= 1000 - 10 CN Where, 5 Maximum retention after rainfall begins(in) CN = Curve number(unitless) Q* = (P-0.28)2 (P+0.8S) Where: Q, Runoff depth(in) p Rainfall depth(in) Step 6:Compute runoff volume from Q(built upon areas). Total Built upon V lumeArca:�sf Total Volume: cf Step 7:Compute runoffvolume from Q*(remainder of drainage area). Total Remaining Area: 74,516 sf Total Volume: 79 cf Step 8:Compute total runoff volume. Total Runoff Volume:�cf 2S is Wetland Post-De lopment Pre-Development (1 -yr) zP Stormwater Wetland Subcat Reach on Link Routing Diagram for 19.00124-Stormwater Wetland Prepared by McGill Associates, Printed 3/21/2024 HydroCADO 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC 19.00124 - Stormwater Wetland Prepared by McGill Associates Printed 3/21/2024 HydroCADO 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 2 Rainfall Events Listing (selected events) Event# Event Storm Type Curve Mode Duration B/B Depth AMC Name (hours) (inches) 1 1-yr Type II 24-hr Default 24.00 1 4.65 2 19.00124 - Stormwater Wetland Type/1 24-hr 1-yr Rainfall=4.65" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 3 Summary for Subcatchment 1S: Post-Development [49] Hint: Tc<2dt may require smaller dt Runoff = 25.45 cfs @ 11.95 hrs, Volume= 1.210 af, Depth> 3.04" Routed to Pond 1 P : Stormwater Wetland Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 1-yr Rainfall=4.65" Area (sf) CN Description 133,351 98 Paved parking, HSG B 74,516 61 >75% Grass cover, Good, HSG B 207,867 85 Weighted Average 74,516 35.85% Pervious Area 133,351 64.15% Impervious Area Tc Length Slope Velocity Capacity Description (min) (feet) (ft/ft) (ft/sec) (cfs) 5.0 Direct Entry, 5-min Subcatchment 1S: Post-Development Hydrograph 28 --i---i---i--i--i-- I---'i--il--i---i---i--i--i-- I---I---il--i---i---i--i--i__I- i- ■Runoff -- -- -- -- ---- 25.45 cfs -- -- -- -----;-- -- -- -- -- -- + I I I I I I I I I 26 _---------y--+--t--r--'r----+--y --rt--+--r--'r-----'Type 24-hr- 24 I I ---------- -- -- -- ----------- 22 -- -- ' --' try Rai--rlfarC- .fi5IF- 20 --------'-- --+-- -- --------'-- -- R�RU� n/offff Are'';;&,2a7,867 i9ff 18 -- I'RO nOff'r1/_Q I P,M -I l. ` -W----r-------r--r--r--r--r-----I--r IN 16 --------i-- --+ --i--i-----i---i --Rtna#IDepth>a M1 41 3 14 o --------'-- --1--L-- --------'-- --1--1--L-- -----'- .�.� y� LL 12 �71 61 --I---I---I--+--+--+--+--I---I---I--+ --+--+--r--+--I---I--+--+- T�=viz 10 8 I I I I I I I I I I I I I I I I I I I I I 6 4 2 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type/1 24-hr 1-yr Rainfall=4.65" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 4 Summary for Subcatchment 2S: Wetland Pre-Development (1-yr) [46] Hint: Tc=O (Instant runoff peak depends on dt) Runoff = 16.99 cfs @ 11.89 hrs, Volume= 0.696 af, Depth> 2.50" Runoff by SCS TR-20 method, UH=SCS, Weighted-CN, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Type II 24-hr 1-yr Rainfall=4.65" Area (sf) CN Description 58,326 98 Paved parking, HSG B 56,217 65 Woods/grass comb., Fair, HSG B 30,886 69 50-75% Grass cover, Fair, HSG B 145,429 79 Weighted Average 87,103 59.89% Pervious Area 58,326 40.11% Impervious Area Subcatchment 2S: Wetland Pre-Development (1-yr) Hydrograph 19 - r r--r--r--' ' r--r--r--r--r--'r----- ' -r-----'-- -- r------- ---- -- -- --i--r-- ■Runoff 18 ----------=--7--r--r-----I- 16.99cfs --t--r--'r--r -- -- 1 --r--r--r-- 17 Tom/ p N �q --r-------y--+--r--r--r-----i--y --rt--+--r--r-----Tyl"I ""i24-hr 15 -- --+-- -- --'r-- -- --+-- 'lryr-Raartfall;;4 651'-- 14 ------'-- -- -- ',--',--',-----'-- -- RiU11off Are'a;1 5-429 S1 - 13 12 ---------- -- -- -- ---------- Ajn4ff'dQ1Me=10-" O- " 10 1--1--Ru_noff'�D� #h*2.50.. - LL -TCT0.0 Infh1 8 6 4 3 2 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Type/1 24-hr 1-yr Rainfall=4.65" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 5 Summary for Pond 1 P: Stormwater Wetland Inflow Area = 4.772 ac, 64.15% Impervious, Inflow Depth > 3.04" for 1-yr event Inflow = 25.45 cfs @ 11.95 hrs, Volume= 1.210 of Outflow = 15.91 cfs @ 12.04 hrs, Volume= 0.980 af, Atten= 37%, Lag= 5.1 min Primary = 15.91 cfs @ 12.04 hrs, Volume= 0.980 of Secondary = 0.00 cfs @ 0.00 hrs, Volume= 0.000 of Routing by Stor-Ind method, Time Span= 0.00-24.00 hrs, dt= 0.05 hrs Peak Elev= 2,335.33' @ 12.04 hrs Surf.Area= 11,735 sf Storage= 21,291 cf Plug-Flow detention time= 136.8 min calculated for 0.980 of(81% of inflow) Center-of-Mass det. time= 58.0 min ( 863.8 - 805.9 ) Volume Invert Avail.Storage Storage Description #1 2,333.00' 42,807 cf Custom Stage Data (Prismatic)Listed below Elevation Surf.Area Inc.Store Cum.Store (feet) (sq-ft) (cubic-feet) (cubic-feet) 2,333.00 6,381 0 0 2,334.00 7,747 7,064 7,064 2,334.25 10,203 2,244 9,308 2,335.00 11,257 8,048 17,355 2,336.00 12,712 11,985 29,340 2,337.00 14,223 13,468 42,807 Device Routing Invert Outlet Devices #1 Primary 2,331.00' 24.0" Round Culvert X 2.00 L= 86.3' RCP, square edge headwall, Ke= 0.500 Inlet / Outlet Invert= 2,331.00' / 2,331.00' S= 0.0000 T Cc= 0.900 n= 0.011 Concrete pipe, straight & clean, Flow Area= 3.14 sf #2 Device 1 2,333.00' 1.5" Vert. Orifice/Grate C= 0.600 Limited to weir flow at low heads #3 Device 1 2,334.25' 36.0" W x 3.0" H Vert. Slots C= 0.600 Limited to weir flow at low heads #4 Device 1 2,335.00' 72.0" x 48.0" Horiz. Top of OCS C= 0.600 Limited to weir flow at low heads #5 Secondary 2,336.00' 10.0' long x 1.00' rise Emergency Spillway Cv= 2.62 (C= 3.28) Primary OutFlow Max=15.40 cfs @ 12.04 hrs HW=2,335.32' (Free Discharge) L1=Culvert (Passes 15.40 cfs of 50.97 cfs potential flow) 12=Orifice/Grate (Orifice Controls 0.09 cfs @ 7.23 fps) 3=Slots (Orifice Controls 3.51 cfs @ 4.68 fps) 4=Top of OCS (Weir Controls 11.81 cfs @ 1.85 fps) Secondary OutFlow Max=0.00 cfs @ 0.00 hrs HW=2,333.00' (Free Discharge) L5=Emergency Spillway ( Controls 0.00 cfs) 19.00124 - Stormwater Wetland Type/1 24-hr 1-yr Rainfall=4.65" Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC Page 6 Pond 1 P: Stormwater Wetland Hydrograph --r+----r+--r+----r+--r--r-r--r-- ■Inflow NOutflo w ■Primary---+ - -+ - - y � I oYA ea=4 / ��ac 28 -- --i-- --i-- --i-- ---- -- --------------------------- I�- 26 �� �' � - --r- --t----t----t----rt--I --'Reak E1 OV-- 33$-3 ' -- 24 - --L-J--L--1--1----L--'--L- -L-L - - cf- 22 /i �/-I r -r--r-r--r--i--r--i--r- -r-r--r-r--r--i--r--i--T--i--r-- 20 18 15.91 cfs 16 u -r--r-r--r--i--t--i--r--i-- --r-r--r-r--r-�--r--i--t--i--r -- 3 14 -L--L-J--L--1--1--'--1--'-- -L-L-- - --L----L--1--L--'--1- LL 12 10 8 4 0.00 cfs 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time (hours) 19.00124 - Stormwater Wetland Table of Contents Prepared by McGill Associates Printed 3/21/2024 HydroCAD® 10.20-4a s/n 04263 ©2023 HydroCAD Software Solutions LLC TABLE OF CONTENTS Project Reports 1 Routing Diagram 2 Rainfall Events Listing (selected events) 1-yr Event 3 Subcat 1 S: Post-Development 4 Subcat 2S: Wetland Pre-Development (1-yr) 5 Pond 1 P: Stormwater Wetland Existing Conditions Proposed Conditions "@ prop HW A existing location" Prop HW A Total DA 201,314 sf Total DA 164,932 1 sf Impervious 41,150 sf Impervious 63,621 sf Pervious 160,164 sf Pervious 101,311 sf „ Increase in Imp 22,471 sf @ prop HW C existing location 0.52 ac Total DA L8279 sf Prop HW C Impervious sf Total DA 112,888 sf Pervious 7 sf Impervious 85,841 sf Pervious 27,047 sf Increase in Imp 5,562 sf 0.13 ac Additional Impervious Area to Project 1.88 acres Treated Impervious 3.06 acres Un-Treated Impervious through Prop HW A and HW C 0.64 acres Tr Appendix F — Ditch Calculations i0i A mcg1ll Project Description: Setzer Fish Hatchery Project Number: 19.00124 Ditch Calculations Date: 9/25/2023 Calculated By:1 NLC Ditch ID Total Area(acres) Total Area(sf) Impervious Wooded Lawns,Sandy Soil,Flat(<2%) C Q10 Q25 Q50 Q100 North Side of Raceways-Worst Case Section 0.742 32316 27842 4474 0.832 4.97 5.67 6.24 6.79 Northeast of Prop Hatchery Building-Roadside 0.125 5455 2480 2975 0.486 0.49 0.56 0.62 0.67 North of Prop EQ Basin 0.200 8700 4163 4537 0.507 0.81 0.93 1.02 1.11 Between Prop Grage&Raceway-L Ditch 0.044 1930 0 1930 0.100 0.041 0.041 0.041 0.05 0.0001 01 1 #DIV/0! #DIV/0! #DIV/0! #DIV/0! #DIV/0! 00001 01 1 1 #DIV/0! #DIV/0! #DIV/0! #DIV/0! #DIV/0! Description Rational Runoff Coefficients Table 3-2 User Input Cell Unimproved Areas 0.35 ]Ratii]rldLrLLiil]ff carfficients(A-ICE,1975;`liemnian,et al.,1496;and Malcom,1999) Calculated Cell Asphalt 0.95 I3esctiptlan of Sulfa-re Itatl-Dnal Runoff Coefficl-ents,C Concrete 0.95 Unimpmved Areas 0.35 Brick 0.85 Asphalt 0.95 Roofs,Inclined 1 Concrete 0.95 Brick 0.85 Roofs,Flat 0.9 Roofs,inclined 1.00 Lawns,Sandy Soil,Flat(<2%) 0.1 ][hoofs,flat 090 Lawns,Sandy Soil,Average(2-7%) 0.15 Lawns.sandy sail,flat!<2%) p.10 Lawns Sandy Soil,Steep(>7%) 0.2 Lawns.sandy soil,average(2-7%) 0.15 Lawns,Heavy Soil,Flat(<2%) 0.15 Lawns.sandy soil,steep(>7%) 0.20 Lawns,Heavy Soil,average(2-7%) 0.2 Lawns.heavy soil,flat(-?-%) 0.15 Lawns,Heavy Soil,Steep(>7%) 0.3 Lawns.heavy sail,average(2-S%6 0.20 Bare Packed Soil 0.6 Iawns,heavy snit,steep(>7%) 0-3n Wooded areas 0.15 Wooded Areas 0.15 10 Year intensity(in/hr) 8.05 Taken From NOAA(10 yr,5 min duration) 25 Year intensity(in/hr) 9.19 Taken From NOAA(25 yr,5 min duration) 50 Year intensity(in/hr) 10.10 Taken From NOAA(50 yr,5 min duration) 100 Year intensity(in/hr) 11.00 Taken From NOAA(100 yr,5 min duration) Channel Report Hydraflow Express Extension for Autodesk®Civil 3D®by Autodesk, Inc. Monday, Sep 25 2023 Ditch Beside Raceways - 25 yr Triangular Highlighted Side Slopes (z:1) = 6.00, 6.00 Depth (ft) = 0.65 Total Depth (ft) = 1.00 Q (cfs) = 5.670 Area (sqft) = 2.53 Invert Elev (ft) = 2340.00 Velocity (ft/s) = 2.24 Slope (%) = 1.00 Wetted Perim (ft) = 7.91 N-Value = 0.030 Crit Depth, Yc (ft) = 0.57 Top Width (ft) = 7.80 Calculations EGL (ft) = 0.73 Compute by: Known Q Known Q (cfs) = 5.67 Elev (ft) Section Depth (ft) 2342.00 2.00 2341.50 1.50 2341.00 1.00 2340.50 0.50 2340.00 0.00 2339.50 -0.50 0 2 4 6 8 10 12 14 16 Reach (ft) Channel Report Hydraflow Express Extension for Autodesk®Civil 3D®by Autodesk, Inc. Monday, Sep 25 2023 Ditch North of Prop EQ Basin (Worst Case)- 25 yr Triangular Highlighted Side Slopes (z:1) = 2.00, 2.00 Depth (ft) = 0.45 Total Depth (ft) = 1.00 Q (cfs) = 0.930 Area (sqft) = 0.40 Invert Elev (ft) = 2357.00 Velocity (ft/s) = 2.30 Slope (%) = 2.00 Wetted Perim (ft) = 2.01 N-Value = 0.030 Crit Depth, Yc (ft) = 0.43 Top Width (ft) = 1.80 Calculations EGL (ft) = 0.53 Compute by: Known Q Known Q (cfs) = 0.93 Elev (ft) Section Depth (ft) 2359.00 2.00 2358.50 1.50 2358.00 1.00 2357.50 0.50 2357.00 0.00 2356.50 -0.50 0 .5 1 1.5 2 2.5 3 3.5 4 4.5 5 Reach (ft) 9/18/23,3:11 PM ECMDS 7.0 NORTH North American Green AMER�CAN 5401 St. Wendel-Cynthiana Rd. Poseyville, Indiana 47633 GREEN Tel. 800.772.2040 >Fax 812.867.0247 www.nagreen.com ECMDS v7.0 CHANNEL ANALYSIS >>>Swale-Worst Case Name Swale-Worst Case Discharge 5 Channel Slope 0.015 Channel Bottom Width 0 Left Side Slope 2 Right Side Slope 2 Low Flow Liner Retardence Class D 2-6 in Vegetation Type Mix(Sod and Bunch) Vegetation Density Good 65-79% Soil Type Sandy Loam(GM) S150 Normal Permissible Calculated Safety Staple Phase Reach Discharge Velocity Mannings N Remarks Depth Shear Stress Shear Stress Factor Pattern 5150 Straight 5 cfs 2.89 ft/s 0.93 ft 0.035 1.8 Ibs/ft2 0.87 Ibs/ft2 2.07 STABLE D Unvegetated Underlying Straight 5 cfs 2.89 ft/s 0.93 ft 0.035 1.7 Ibs/ft2 0.39 Ibs/ft2 4.38 STABLE D Substrate Unreinforced Vegetation Normal Permissible Calculated Safety Staple Phase Reach Discharge Velocity Mannings N Remarks Depth Shear Stress Shear Stress Factor Pattern Unreinforced Straight 5 cfs 2.89 ft/s 0.93 ft 0.035 4 Ibs/ft2 0.87 Ibs/ft2 4.6 STABLE Vegetation Underlying Straight 5 cfs 2.89 ft/s 0.93 ft 0.035 1.91 Ibs/ft2 0.39 Ibs/ft2 4.92 STABLE Substrate https://ecmds.com/project/l 58025/channel-analysis/251990/show 1/1 Appendix G - NOAA Atlas 14 - Precipitation Depth 9/13/2021 Precipitation Frequency Data Server NOAA Atlas 14,Volume 2,Version 3 Location name: Brevard, North Carolina, USA* � '° Latitude:35.2832*, Longitude: -82.7963° Elevation:2380.96 ft* *source:ESRI Maps w,�w,�y� -source:USGS POINT PRECIPITATION FREQUENCY ESTIMATES G.M.Bonnin,D.Martin,B.Lin,T.Parzybok,M.Yekta,and D.Riley NOAA,National Weather Service,Silver Spring,Maryland PF tabular I PF graphical I Maps & aerials PF tabular PDS-based point precipitation frequency estimates with 90% confidence intervals (in inches)1 Average recurrence interval(years) 1 2 5 10 25 50 100 200F 500 1000 5-min 0.419 0.502 0.598 0.671 0.766 0.839 0.914 0.988 1.09 1.17 (0.381-0.464) (0.455-0.556) (0.541-0.661) (0.604-0.741) (0.685-0.847) (0.746-0.929) (0.807-1.01) (0.866-1.10) (0.941-1.22) (1.00-1.32) 10-min 0.670 0.803 0.957 1.07 1.22 1.34 1.45 1.57 1.72 1.84 (0.608-0.742) (0.728-0.890) (0.866-1.06) (0.967-1.19) 1 (1.19-1.48) (1.28-1.61) (1.37-1.75) (1.49-1.93) (1.58-2.08) 15-min 0.837 1.01 1.21 1.36 1.55 1.69 1.84 1.98 2.16 2.31 (0.760-0.927) (0.916-1.12) 1 (1.10-1.34) 1 (1.22-1.50) 1 (1.51-1.87) (1.62-2.04) (1.73-2.20) (1.87-2.43) (1.98-2.61) 30-min 1.15 1.40 1.72 1.97 2.29 2.55 2.81 3.08 3.44 3.74 (1.04-1.27) (1.26-1.55) (1.56-1.90) (1.77-2.17) (2.05-2.53) (2.27-2.82) (2.48-3.12) (2.70-3.43) (2.98-3.86) (3.20-4.22) 60-min 1.43 1.75 2.21 2.56 3.05 3.45 3.87 4.31 4.94 5.46 (1.30-1.59) (1.59-1.94) (2.00-2.44) (2.31-2.83) (2.73-3.37) (3.07-3.82) (3.42-4.30) (3.78-4.81) (4.28-5.54) (4.67-6.16) 2-hr 1.69 2.06 2.58 2.99 3.58 4.06 4.56 5.10 5.87 6.52 (1.53-1.86) (1.87-2.26) (2.34-2.84) (2.70-3.30) (3.21-3.94) (3.62-4.48) (4.03-5.05) (4.47-5.66) (5.08-6.56) (5.58-7.32) 3-hr 1.89 2.29 2.86 3.33 4.00 4.57 5.18 5.85 6.84 7.68 (1.72-2.09) (2.08-2.53) (2.59-3.16) (3.00-3.67) 1 (3.58-4.42) (4.06-5.06) (4.56-5.75) (5.09-6.51) (5.86-7.66) (6.49-8.65) 6-hr 2.61 3.15 3.86 4.47 5.37 6.14 6.98 7.91 9.29 10.5 (2.39-2.88) (2.88-3.47) (3.52-4.26) (4.06-4.93) (4.83-5.92) (5.47-6.78) (6.15-7.74) (6.89-8.81) (7.94-10.4) (8.83-11.9) 12-hr 3.58 4.32 5.29 6.06 7.15 8.05 8.99 10.0 11.5 12.7 (3.30-3.90) 1 (3.97-4.71) 1 (4.86-5.77) 1 (5.55-6.62) 1 (7.28-8.82) 1(8.06-9.89) 1(8.89-11.0) 11(10.0-12.8) (11.0-14.3) 24-h r 4.65 5.57 6.85 7.88 9.30 10.5 11.7 13.0 14.9 16.5 (4.28-5.04) (5.14-6.05) (6.31-7.45) (7.24-8.55) 1 (8.51-10.1) 1 (9.53-11.4) 1(10.6-12.7) 1(11.7-14.1) 11(13.2-16.3) (14.5-18.1) 2-day 5.64 6.74 8.21 9.39 11.0 12.3 13.7 15.2 17.4 19.1 (5.24-6.10) (6.26-7.28) (7.60-8.87) (8.68-10.1) 1 (10.1-11.9) 1 (11.3-13.4) (12.5-14.9) (13.8-16.6) (15.5-19.0) (16.9-21.0) 3-day 6.04 7.20 8.70 9.89 11.5 12.8 14.2 15.6 17.7 19.4 (5.63-6.49) 1 (6.71-7.74) 1 (8.09-9.35) 1 (9.18-10.6) 1 (11.8-13.8) (13.0-15.3) (14.2-16.9) (15.9-19.2) (17.3-21.2) 4-day 6.44 7.66 9.19 10.4 12.0 13.3 14.6 16.0 18.0 19.6 (6.02-6.89) (7.17-8.19) (8.58-9.83) 1 (9.69-11.1) 1 (11.2-12.9) 1 (12.3-14.3) (13.5-15.7) (14.7-17.3) (16.3-19.5) (17.6-21.4) 7-day 7.63 9.06 10.9 12.3 14.3 15.9 17.5 19.3 21.7 23.7 (7.12-8.19) (8.47-9.74) (10.1-11.7) 1 (11.5-13.2) 1 (14.7-17.1) (16.1-18.9) (17.6-20.8) (19.6-23.5) (21.3-25.8) 10tlay 8.83 10.5 12.4 14.0 16.1 17.8 19.5 21.3 23.9 25.9 (8.26-9.47) (9.78-11.2) (11.6-13.3) 1 (13.0-15.0) 1 (15.0-17.3) 1 (16.5-19.1) (18.0-21.0) (19.6-23.0) (21.7-25.8) (23.4-28.1) 20tlay 11.9 14.0 16.3 18.0 20.3 22.0 3.27 25.4 27.7 .4 29 (11.2-12.6) (13.2-14.9) (15.4-17.3) (17.0-19.1) (19.1-21.6) (20.7-23.4) (22.2-25.3) (23.7-27.1) (25.6-29.6) (27.1-31.6) 30tlay 14.5 17.0 19.5 21.4 23.8 25.5 27.2 28.8 30.8 32.4 (13.7-15.4) (16.1-18.0) (18.4-20.7) (20.2-22.7) (22.4-25.2) (24.0-27.0) (25.5-28.8) (26.9-30.6) (28.7-32.9) (30.1-34.6) 45tlay 18.4 21.6 24.3 26.3 28.8 30.5 32.1 33.6 35.5 36.8 (17.5-19.4) (20.5-22.7) (23.1-25.6) (25.0-27.7) (27.2-30.3) (28.9-32.2) (30.3-33.9) (31.7-35.5) (33.3-37.6) (34.5-39.1) 60tlay 22.0 25.6 28.7 30.9 33.5 35.3 37.0 38.5 40.3 41.7 (21.0-23.1) (24.5-26.9) (27.3-30.1) (29.4-32.4) (31.9-35.1) (33.5-37.1) (35.1-38.9) (36.4-40.5) (38.1-42.6) (39.2-44.1) Precipitation frequency(PF)estimates in this table are based on frequency analysis of partial duration series(PDS). Numbers in parenthesis are PF estimates at lower and upper bounds of the 90%confidence interval.The probability that precipitation frequency estimates (for a given duration and average recurrence interval)will be greater than the upper bound(or less than the lower bound)is 5%.Estimates at upper bounds are not checked against probable maximum precipitation(PMP)estimates and may be higher than currently valid PMP values. Please refer to NOAA Atlas 14 document for more information. Back to Top PF graphical https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.html?lat=35.2832&Ion=-82.7963&data=depth&units=english&series=pds 1/4 9/13/2021 Precipitation Frequency Data Server PIDS-based depth-duration-frequency (DDF) curves Latitude: 35.2832', Longitude: -82.7963' 45 40 r r 4- --- verage enc recur e interval _ 35 -- -- --- a{ye ra} c — 1 t 30 --- a 2 di 25 --- -- — 5 25 O 28 — S4 u 15 = = = 100 a — 10 ......• — 544 5 ---;- -.- � — 1040 0 t t Jr t L N N r{4 N rq rq rq N rq O N A lb N C'V f1�1 Vr, O O O Ln O rn w � N rn v Ln Duration 45 40 ----------- - - ------ ------ - ----- -- 35 ---- ------- ----- ........... .................. ---- c Duration t 30 --.- C — 5�riin — 2-day -0 25 ------ -- ------ e — 14-min — 3-day ++ 20 - -- ----' ---- .------ .... -- 1 in aY 49 — 30-min — 7-day a 15 .- ----- — 64anin — i�day a — 2fir — 24 day 10 — 3-fir — 30-oay 5 — Sfir — 45-Jay --------- 12-h r — 60-eay 0 - 24-hr 1 2 5 10 25 50 100 200 500 1000 Average recurrence interval (years) NOAAAtlas 14,Volume 2,Version 3 Created{GMT}: Mon Sep 13 16:24:57 2021 Back to Top Maps & aerials Small scale terrain https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.2832&Ion=-82.7963&data=depth&units=english&series=pds 2/4 9/13/2021 Precipitation Frequency Data Server 8 UR! 3km MOUNTAIN 2mi Large scale terrain KI ng spoitFr Bristol k' EE - J0111150 I City' 0 Winston-`_ Knoxville I'.4IAitrhell •Asl,erllle N 0 R T I- •Ch ttallooga •Greenville + - 1 — 100km 6 mi • Large scale map Johnson City Wins, Knoxville a rr. }Avhevlfle I I I. y Greenville 100km 6 mi hens ^t Large scale aerial https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.2832&Ion=-82.7963&data=depth&units=english&series=pds 3/4 9/13/2021 Precipitation Frequency Data Server Johnson -an++• 100km 6 mi * � Back to Top US Department of Commerce National Oceanic and Atmospheric Administration National Weather Service National Water Center 1325 East West Highway Silver Spring, MD 20910 Questions?: HDSC.Questions noaa.gov Disclaimer https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.2832&Ion=-82.7963&data=depth&units=english&series=pds 4/4 Appendix H — NOAA Atlas 14 — Precipitation Intensity 9/13/2021 Precipitation Frequency Data Server NOAA Atlas 14,Volume 2,Version 3 Location name: Brevard, North Carolina, USA* � '° Latitude:35.2832*, Longitude: -82.7963° Elevation:2380.96 ft* *source:ESRI Maps w,�w,�y� -source:USGS POINT PRECIPITATION FREQUENCY ESTIMATES G.M.Bonnin,D.Martin,B.Lin,T.Parzybok,M.Yekta,and D.Riley NOAA,National Weather Service,Silver Spring,Maryland PF tabular I PF graphical I Maps & aerials PF tabular PDS-based point precipitation frequency estimates with 90% confidence intervals (in inches/hourp Average recurrence interval(years) Duration 1 100 1 2 5 10 25 50 100 200 500 1000 5-min 5.03 6.02 7.18 8.05 9.19 10.1 11.0 11.9 13.0 14.0 (4.57-5.57) (5.46-6.67) (6.49-7.93) (7.25-8.89) (8.22-10.2) (8.95-11.1) (9.68-12.2) (10.4-13.2) (11.3-14.6) (12.0-15.8) 10-min 4.02 4.82 5.74 6.44 7.33 8.02 8.71 9.40 10.3 11.0 (3.65-4.45) (4.37-5.34) (5.20-6.35) (5.80-7.12) (6.55-8.09) (7.13-8.88) (7.70-9.67) (8.24-10.5) (8.93-11.6) (9.45-12.5) 15-min 3.35 4.04 4.84 5.43 6.19 6.76 7.34 7.90 8.65 9.24 (3.04-3.71) (3.66-4.47) (4.38-5.36) (4.89-6.00) (5.54-6.84) (6.02-7.49) (6.49-8.14) (6.93-8.80) (7.49-9.71) (7.91-10.4) 30-min 2.30 2.79 3.44 3.93 4.59 5.09 5.62 6.15 6.88 7.48 (2.08-2.54) (2.53-3.09) (3.11-3.81) (3.54-4.35) (4.10-5.07) (4.53-5.64) (4.97-6.24) (5.39-6.85) (5.96-7.72) (6.40-8.44) 60-min 1.43 1.75 2.21 2.56 3.05 3.45 3.87 4.31 4.94 5.46 (1.30-1.59) (1.59-1.94) (2.00-2.44) (2.31-2.83) (2.73-3.37) (3.07-3.82) (3.42-4.30) (3.78-4.81) (4.28-5.54) (4.67-6.16) 2-hr 0.842 1.03 1.29 1.50 1.79 2.03 2.28 2.55 2.94 3.26 (0.766-0.930) (0.935-1.13) 11 (1.17-1.42) 11 (1.35-1.65) 11 (1.60-1.97) 1 (1.81-2.24) 1 (2.02-2.53) (2.24-2.83) (2.54-3.28) (2.79-3.66) 3-hr 0.628 0.763 0.951 1.11 1.33 1.52 1.73 1.95 2.28 2.56 (0.571-0.696) (0.693-0.843) (0.862-1.05) 1 1 (1.19-1.47) 1 (1.35-1.69) 1 (1.52-1.91) 1 (1.70-2.17) 1 (1.95-2.55) (2.16-2.88) 6-hr 0.436 0.525 0.645 0.747 F 0.897 1.02 1.17 1.32 1.55 1.75 (0.399-0.481) (0.480-0.579) (0.588-0.712) (0.678-0.824) (0.806-0.989) (0.913-1.13) 1 (1.03-1.29) 1 (1.15-1.47) 1 (1.33-1.74) 1 (1.48-1.98) 12-hr 0.297 0.359 0.439 0.503 0.594 0.668 0.747 F 0.831 F 0.953 1.06 (0.273-0.324) (0.330-0.391) (0.403-0.479) (0.461-0.549) (0.540-0.649) (0.604-0.732) (0.669-0.821) (0.738-0.917) (0.833-1.06) (0.913-1.19) 24-hr 0.194 0.232 0.286 0.328 0.387 0.436 0.487 0.542 0.621 0.687 (0.179-0.210) (0.214-0.252) (0.263-0.310) (0.302-0.356) (0.354-0.420) (0.397-0.473) (0.441-0.529) (0.487-0.589) (0.551-0.678) (0.603-0.753) 2-day 0.117 0.140 0.171 0.196 0.230 0.257 0.286 0.317 0.362 0.399 (0.109-0.127) (0.130-0.152) (0.158-0.185) (0.181-0.211) (0.211-0.248) (0.236-0.278) (0.261-0.310) (0.287-0.345) (0.324-0.395) (0.353-0.438) 3-day 0.084 0.100 0.121 0.137 0.160 0.178 0.197 0.217 0.246 0.269 (0.078-0.090) (0.093-0.107) (0.112-0.130) (0.128-0.148) (0.148-0.172) (0.164-0.192) (0.181-0.213) (0.198-0.235) (0.221-0.267) (0.240-0.294) 4-day 0.067 0.080 0.096 0.108 0.125 0.139 0.152 0.167 0.187 0.205 (0.063-0.072) (0.075-0.085) (0.089-0.102) (0.101-0.116) (0.116-0.134) (0.128-0.149) (0.141-0.164) (0.153-0.180) (0.170-0.203) (0.184-0.223) 7-day 0.045 0.054 0.065 0.073 0.085 0.095 0.104 0.115 0.129 0.141 (0.042-0.049) (0.050-0.058) (0.060-0.070) (0.068-0.079) (0.079-0.091) (0.087-0.102) (0.096-0.112) (0.105-0.124) (0.117-0.140) (0.127-0.153) 10-day 0.037 0.044 0.052 0.058 0.067 0.074 0.081 0.089 0.099 0.108 (0.034-0.039) (0.041-0.047) (0.048-0.055) (0.054-0.063) (0.062-0.072) (0.069-0.080) (0.075-0.087) (0.082-0.096) (0.090-0.107) (0.097-0.117) 20-day 0.025 0.029 0.034 0.038 0.042 0.046 0.049 0.053 0.058 0.061 (0.023-0.026) (0.028-0.031) (0.032-0.036) (0.035-0.040) (0.040-0.045) (0.043-0.049) (0.046-0.053) (0.049-0.056) (0.053-0.062) (0.056-0.066) 30-day 0.020 0.024 0.027 0.030 0.033 0.035 0.038 0.040 0.043 0.045 (0.019-0.021) (0.022-0.025) (0.026-0.029) (0.028-0.031) (0.031-0.035) (0.033-0.038) (0.035-0.040) (0.037-0.042) (0.040-0.046) (0.042-0.048) 45-day 0.017 0.020 0.023 0.024 0.027 0.028 0.030 0.031 0.033 0.034 (0.016-0.018) (0.019-0.021) (0.021-0.024) (0.023-0.026) (0.025-0.028) (0.027-0.030) (0.028-0.031) (0.029-0.033) (0.031-0.035) (0.032-0.036) 60-day 0.015 0.018 0.020 0.021 0.023 0.025 0.026 0.027 0.028 0.029 (0.015-0.016) (0.017-0.019) (0.019-0.021) (0.020-0.022) (0.022-0.024) (0.023-0.026) (0.024-0.027) (0.025-0.028) (0.026-0.030) (0.027-0.031) Precipitation frequency(PF)estimates in this table are based on frequency analysis of partial duration series(PDS). Numbers in parenthesis are PF estimates at lower and upper bounds of the 90%confidence interval.The probability that precipitation frequency estimates(for a given duration and average recurrence interval)will be greater than the upper bound(or less than the lower bound)is 5%.Estimates at upper bounds are not checked against probable maximum precipitation(PMP)estimates and may be higher than currently valid PMP values. Please refer to NOAA Atlas 14 document for more information. Back to Top PF graphical https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.html?lat=35.2832&Ion=-82.7963&data=intensity&units=english&series=pds 1/4 9/13/2021 Precipitation Frequency Data Server PD5-based intensity-duration-frequency (IDF) curves Latitude: 35.2832`, Longitude: -32.7963' 100_QO Average recurrence mlerva I 'L {years} 10-QQ --- --- -- - --- — 1 4` 2 � — 5 1_0O - - - ----- — 10 0 — 25 — 50 a — 100 0-10 ---- -- -- -- ...... — 200 — 500 1000 t t Jr t L N N O r{4 N rq rq rq N rq N Alb N C'V r1�1 q r, O O O Ln O rn ro 1-4N rn v Ln Duration 1Q0-QQ L 10-QQ --' — — C — Duration — 6-min — 2-day m ' 1-00 ......... ...--- . ................ 1— 0-min — 3-day— 15-min — d-dmy ° — 30-min — 7-day 41 49 — 60anin — 10 day — — u -- --- ................. 2fir 2i�day 0-1Q — 3-rr — 30-day — Sfir — 45-day 12-h r — 60-day 0-01 - 24-hr 1 2 5 10 25 50 100 200 500 1000 Average recurrence interval (years) NOAAAtlas 14,Volume 2,Version 3 Created{GMT}: Mon Sep 13 16:25:44 2021 Back to Top Maps & aerials Small scale terrain https://hdsc.nws.noaa.gov/hdsc/pfds/pfds—printpage.htmI?Iat=35.2832&Ion=-82.7963&data=intensity&units=english&series=pds 2/4 9/13/2021 Precipitation Frequency Data Server 8 UR! 3km MOUNTAIN 2mi Large scale terrain KI ng spoitFr Bristol k' EE - J0111150 I City' 0 Winston-`_ Knoxville I'.4IAitrhell •Asl,erllle N 0 R T I- •Ch ttallooga •Greenville + - 1 — 100km 6 mi • Large scale map Johnson City Wins, Knoxville a rr. }Avhevlfle I I I. y Greenville 100km 6 mi hens ^t Large scale aerial https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.2832&Ion=-82.7963&data=intensity&units=english&series=pds 3/4 9/13/2021 Precipitation Frequency Data Server Johnson -an++• 100km 6 mi * � Back to Top US Department of Commerce National Oceanic and Atmospheric Administration National Weather Service National Water Center 1325 East West Highway Silver Spring, MD 20910 Questions?: HDSC.Questions noaa.gov Disclaimer https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.2832&Ion=-82.7963&data=intensity&units=english&series=pds 4/4 Appendix I — NRCS Web Soil Survey Report USDA United States A product of the National Custom Soil Resource Department of Cooperative Soil Survey, Agriculture a joint effort of the United Report for States Department of N RCS Agriculture and other Transylvania Federal agencies, State Natural agencies including the �o� n ty, North Resources Agricultural Experiment Conservation Stations, and local Service participants Carolina Bobby N Setzer Fish Hatchery National Fnra5 September 14, 2023 Preface Soil surveys contain information that affects land use planning in survey areas. They highlight soil limitations that affect various land uses and provide information about the properties of the soils in the survey areas. Soil surveys are designed for many different users, including farmers, ranchers, foresters, agronomists, urban planners, community officials, engineers, developers, builders, and home buyers. Also, conservationists, teachers, students, and specialists in recreation, waste disposal, and pollution control can use the surveys to help them understand, protect, or enhance the environment. Various land use regulations of Federal, State, and local governments may impose special restrictions on land use or land treatment. Soil surveys identify soil properties that are used in making various land use or land treatment decisions. The information is intended to help the land users identify and reduce the effects of soil limitations on various land uses. The landowner or user is responsible for identifying and complying with existing laws and regulations. Although soil survey information can be used for general farm, local, and wider area planning, onsite investigation is needed to supplement this information in some cases. Examples include soil quality assessments (http://www.nres.usda.gov/wps/ portal/nres/main/soils/health/) and certain conservation and engineering applications. For more detailed information, contact your local USDA Service Center (https:Hoffices.sc.egov.usda.gov/locator/app?agency=nres) or your NRCS State Soil Scientist (http://www.nres.usda.gov/wps/portal/nres/detail/soils/contactus/? cid=nres142p2_053951). Great differences in soil properties can occur within short distances. Some soils are seasonally wet or subject to flooding. Some are too unstable to be used as a foundation for buildings or roads. Clayey or wet soils are poorly suited to use as septic tank absorption fields. A high water table makes a soil poorly suited to basements or underground installations. The National Cooperative Soil Survey is a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local agencies. The Natural Resources Conservation Service (NRCS) has leadership for the Federal part of the National Cooperative Soil Survey. Information about soils is updated periodically. Updated information is available through the NRCS Web Soil Survey, the site for official soil survey information. The U.S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin, age, disability, and where applicable, sex, marital status, familial status, parental status, religion, sexual orientation, genetic information, political beliefs, reprisal, or because all or a part of an individual's income is derived from any public assistance program. (Not all prohibited bases apply to all programs.) Persons with disabilities who require 2 alternative means for communication of program information (Braille, large print, audiotape, etc.) should contact USDA's TARGET Center at (202) 720-2600 (voice and TDD). To file a complaint of discrimination, write to USDA, Director, Office of Civil Rights, 1400 Independence Avenue, S.W., Washington, D.C. 20250-9410 or call (800) 795-3272 (voice) or(202) 720-6382 (TDD). USDA is an equal opportunity provider and employer. 3 Contents Preface....................................................................................................................2 How Soil Surveys Are Made..................................................................................5 SoilMap.................................................................................................................. 8 SoilMap................................................................................................................9 Legend................................................................................................................10 MapUnit Legend................................................................................................ 11 MapUnit Descriptions.........................................................................................11 Transylvania County, North Carolina.............................................................. 14 12—Rosman-Reddies complex, 0 to 3 percent slopes, rarely flooded....... 14 14—Dellwood-Reddies complex, 0 to 3 percent slopes, occasionally flooded.................................................................................................. 15 82—Toxaway loam, 0 to 2 percent slopes, occasionally flooded................ 17 100C—Tusquitee-Whiteside complex, 8 to 15 percent slopes....................18 101 D—Cullasaja-Tuckasegee complex, 15 to 30 percent slopes, very stony.....................................................................................................20 101 E—Cullasaja-Tuckasegee complex, 30 to 50 percent slopes, very stony.....................................................................................................22 121 C—Saunook loam, high precipitation, 8 to 15 percent slopes...............23 121 D—Saunook loam, high precipitation, 15 to 30 percent slopes, stony..24 125C—Tate loam, high precipitation, 8 to 15 percent slopes......................25 125D—Tate loam, high precipitation, 15 to 30 percent slopes, stony......... 26 393D—Chestnut-Edneyville complex, high precipitation, 15 to 30 percent slopes, stony............................................................................27 393E—Chestnut-Edneyville complex, high precipitation, 30 to 50 percent slopes, stony............................................................................29 761 E—Porters-Unaka complex, 30 to 50 percent slopes, stony.................31 793F—Ashe-Buladean-Rock outcrop complex, 50 to 95 percent slopes, very stony.................................................................................32 References............................................................................................................35 4 How Soil Surveys Are Made Soil surveys are made to provide information about the soils and miscellaneous areas in a specific area. They include a description of the soils and miscellaneous areas and their location on the landscape and tables that show soil properties and limitations affecting various uses. Soil scientists observed the steepness, length, and shape of the slopes; the general pattern of drainage; the kinds of crops and native plants; and the kinds of bedrock. They observed and described many soil profiles. A soil profile is the sequence of natural layers, or horizons, in a soil. The profile extends from the surface down into the unconsolidated material in which the soil formed or from the surface down to bedrock. The unconsolidated material is devoid of roots and other living organisms and has not been changed by other biological activity. Currently, soils are mapped according to the boundaries of major land resource areas (MLRAs). MLRAs are geographically associated land resource units that share common characteristics related to physiography, geology, climate, water resources, soils, biological resources, and land uses (USDA, 2006). Soil survey areas typically consist of parts of one or more MLRA. The soils and miscellaneous areas in a survey area occur in an orderly pattern that is related to the geology, landforms, relief, climate, and natural vegetation of the area. Each kind of soil and miscellaneous area is associated with a particular kind of landform or with a segment of the landform. By observing the soils and miscellaneous areas in the survey area and relating their position to specific segments of the landform, a soil scientist develops a concept, or model, of how they were formed. Thus, during mapping, this model enables the soil scientist to predict with a considerable degree of accuracy the kind of soil or miscellaneous area at a specific location on the landscape. Commonly, individual soils on the landscape merge into one another as their characteristics gradually change. To construct an accurate soil map, however, soil scientists must determine the boundaries between the soils. They can observe only a limited number of soil profiles. Nevertheless, these observations, supplemented by an understanding of the soil-vegetation-landscape relationship, are sufficient to verify predictions of the kinds of soil in an area and to determine the boundaries. Soil scientists recorded the characteristics of the soil profiles that they studied. They noted soil color, texture, size and shape of soil aggregates, kind and amount of rock fragments, distribution of plant roots, reaction, and other features that enable them to identify soils. After describing the soils in the survey area and determining their properties, the soil scientists assigned the soils to taxonomic classes (units). Taxonomic classes are concepts. Each taxonomic class has a set of soil characteristics with precisely defined limits. The classes are used as a basis for comparison to classify soils systematically. Soil taxonomy, the system of taxonomic classification used in the United States, is based mainly on the kind and character of soil properties and the arrangement of horizons within the profile. After the soil 5 Custom Soil Resource Report scientists classified and named the soils in the survey area, they compared the individual soils with similar soils in the same taxonomic class in other areas so that they could confirm data and assemble additional data based on experience and research. The objective of soil mapping is not to delineate pure map unit components; the objective is to separate the landscape into landforms or landform segments that have similar use and management requirements. Each map unit is defined by a unique combination of soil components and/or miscellaneous areas in predictable proportions. Some components may be highly contrasting to the other components of the map unit. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The delineation of such landforms and landform segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, onsite investigation is needed to define and locate the soils and miscellaneous areas. Soil scientists make many field observations in the process of producing a soil map. The frequency of observation is dependent upon several factors, including scale of mapping, intensity of mapping, design of map units, complexity of the landscape, and experience of the soil scientist. Observations are made to test and refine the soil-landscape model and predictions and to verify the classification of the soils at specific locations. Once the soil-landscape model is refined, a significantly smaller number of measurements of individual soil properties are made and recorded. These measurements may include field measurements, such as those for color, depth to bedrock, and texture, and laboratory measurements, such as those for content of sand, silt, clay, salt, and other components. Properties of each soil typically vary from one point to another across the landscape. Observations for map unit components are aggregated to develop ranges of characteristics for the components. The aggregated values are presented. Direct measurements do not exist for every property presented for every map unit component. Values for some properties are estimated from combinations of other properties. While a soil survey is in progress, samples of some of the soils in the area generally are collected for laboratory analyses and for engineering tests. Soil scientists interpret the data from these analyses and tests as well as the field-observed characteristics and the soil properties to determine the expected behavior of the soils under different uses. Interpretations for all of the soils are field tested through observation of the soils in different uses and under different levels of management. Some interpretations are modified to fit local conditions, and some new interpretations are developed to meet local needs. Data are assembled from other sources, such as research information, production records, and field experience of specialists. For example, data on crop yields under defined levels of management are assembled from farm records and from field or plot experiments on the same kinds of soil. Predictions about soil behavior are based not only on soil properties but also on such variables as climate and biological activity. Soil conditions are predictable over long periods of time, but they are not predictable from year to year. For example, soil scientists can predict with a fairly high degree of accuracy that a given soil will have a high water table within certain depths in most years, but they cannot predict that a high water table will always be at a specific level in the soil on a specific date. After soil scientists located and identified the significant natural bodies of soil in the survey area, they drew the boundaries of these bodies on aerial photographs and 6 Custom Soil Resource Report identified each as a specific map unit. Aerial photographs show trees, buildings, fields, roads, and rivers, all of which help in locating boundaries accurately. 7 Soil Map The soil map section includes the soil map for the defined area of interest, a list of soil map units on the map and extent of each map unit, and cartographic symbols displayed on the map. Also presented are various metadata about data used to produce the map, and a description of each soil map unit. 8 • L' g r _ o w j 2 100C AN 35 W 101•D 393E INC 7r611E ti 121.C� ' 121CIL 4F .r k 3 a r.:F 393E � '1 ►- �PIP � �.r r i+' .F. �. � �' err •. 393E ,�,.,, r 121 D 1101 01 3, OOND Gawp marf lffl(M2[bc a&Do ctR RhN@ WAOQo Custom Soil Resource Report MAP LEGEND MAP INFORMATION Area of Interest(A01) Spoil Area The soil surveys that comprise your AOI were mapped at 0 Area of Interest(AOI) Stony Spot 1:12,000. Soils Very Stony Spot 0 Soil Map Unit Polygons Warning:Soil Map may not be valid at this scale. Wet Spot Soil Map Unit Lines Enlargement of maps beyond the scale of mapping can cause Other misunderstanding of the detail of mapping and accuracy of soil � Soil Map Unit Points 9 pp 9 Y �- Special Line Features line placement.The maps do not show the small areas of Special Point Features contrasting soils that could have been shown at a more detailed Iwo Blowout Water Features scale. Streams and Canals Borrow Pit Transportation Please rely on the bar scale on each map sheet for map Clay Spot � Rails measurements. Closed Depression 0 Interstate Highways Source of Map: Natural Resources Conservation Service Gravel Pit US Routes Web Soil Survey URL: Gravelly Spot Coordinate System: Web Mercator(EPSG:3857) Major Roads Landfill Local Roads Maps from the Web Soil Survey are based on the Web Mercator A. Lava Flow Background projection,which preserves direction and shape but distorts distance and area.A projection that preserves area,such as the Marsh or swamp Aerial Photography Albers equal-area conic projection,should be used if more Mine or Quarry accurate calculations of distance or area are required. Miscellaneous Water This product is generated from the USDA-NRCS certified data as Perennial Water of the version date(s)listed below. Rock Outcrop Soil Survey Area: Transylvania County, North Carolina Saline Spot Survey Area Data: Version 22, Sep 12,2022 Sandy spot Soil map units are labeled(as space allows)for map scales Severely Eroded Spot 1:50,000 or larger. Sinkhole Date(s)aerial images were photographed: Apr 1,2022—May 9, Slide or Slip 2022 oa Sodic Spot The orthophoto or other base map on which the soil lines were compiled and digitized probably differs from the background imagery displayed on these maps.As a result,some minor shifting of map unit boundaries may be evident. 10 Custom Soil Resource Report Map Unit Legend Map Unit Symbol Map Unit Name Acres in AOI Percent of AOI 12 Rosman-Reddies complex,0 to 14.6 25.3% 3 percent slopes, rarely flooded 14 Dellwood-Reddies complex,0 20.7 35.7% to 3 percent slopes, occasionally flooded 82 Toxaway loam,0 to 2 percent 2.7 4.6% slopes,occasionally flooded 100C Tusquitee-Whiteside complex,8 1.4 2.4% to 15 percent slopes 101 D Cullasaja-Tuckasegee complex, 2.8 4.9% 15 to 30 percent slopes,very stony 101 E Cullasaja-Tuckasegee complex, 1.0 1.7% 30 to 50 percent slopes,very stony 121 C Saunook loam,high 3.0 5.2% precipitation,8 to 15 percent slopes 121 D Saunook loam,high 6.1 10.6% precipitation, 15 to 30 percent slopes,stony 125C Tate loam, high precipitation,8 1.3 2.2% to 15 percent slopes 125D Tate loam, high precipitation, 15 1.8 3.1% to 30 percent slopes,stony 393D Chestnut-Edneyville complex, 0.2 0.3% high precipitation, 15 to 30 percent slopes,stony 393E Chestnut-Edneyville complex, 2.2 3.8% high precipitation,30 to 50 percent slopes,stony 761 E Porters-Unaka complex,30 to 0.1 0.2% 50 percent slopes,stony 793F Ashe-Buladean-Rock outcrop 0.0 0.1% complex,50 to 95 percent slopes,very stony Totals for Area of Interest 67.9 100.0% Map Unit Descriptions The map units delineated on the detailed soil maps in a soil survey represent the soils or miscellaneous areas in the survey area. The map unit descriptions, along with the maps, can be used to determine the composition and properties of a unit. 11 Custom Soil Resource Report A map unit delineation on a soil map represents an area dominated by one or more major kinds of soil or miscellaneous areas. A map unit is identified and named according to the taxonomic classification of the dominant soils. Within a taxonomic class there are precisely defined limits for the properties of the soils. On the landscape, however, the soils are natural phenomena, and they have the characteristic variability of all natural phenomena. Thus, the range of some observed properties may extend beyond the limits defined for a taxonomic class. Areas of soils of a single taxonomic class rarely, if ever, can be mapped without including areas of other taxonomic classes. Consequently, every map unit is made up of the soils or miscellaneous areas for which it is named and some minor components that belong to taxonomic classes other than those of the major soils. Most minor soils have properties similar to those of the dominant soil or soils in the map unit, and thus they do not affect use and management. These are called noncontrasting, or similar, components. They may or may not be mentioned in a particular map unit description. Other minor components, however, have properties and behavioral characteristics divergent enough to affect use or to require different management. These are called contrasting, or dissimilar, components. They generally are in small areas and could not be mapped separately because of the scale used. Some small areas of strongly contrasting soils or miscellaneous areas are identified by a special symbol on the maps. If included in the database for a given area, the contrasting minor components are identified in the map unit descriptions along with some characteristics of each. A few areas of minor components may not have been observed, and consequently they are not mentioned in the descriptions, especially where the pattern was so complex that it was impractical to make enough observations to identify all the soils and miscellaneous areas on the landscape. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The objective of mapping is not to delineate pure taxonomic classes but rather to separate the landscape into Iandforms or Iandform segments that have similar use and management requirements. The delineation of such segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, however, onsite investigation is needed to define and locate the soils and miscellaneous areas. An identifying symbol precedes the map unit name in the map unit descriptions. Each description includes general facts about the unit and gives important soil properties and qualities. Soils that have profiles that are almost alike make up a soil series. Except for differences in texture of the surface layer, all the soils of a series have major horizons that are similar in composition, thickness, and arrangement. Soils of one series can differ in texture of the surface layer, slope, stoniness, salinity, degree of erosion, and other characteristics that affect their use. On the basis of such differences, a soil series is divided into soil phases. Most of the areas shown on the detailed soil maps are phases of soil series. The name of a soil phase commonly indicates a feature that affects use or management. For example, Alpha silt loam, 0 to 2 percent slopes, is a phase of the Alpha series. Some map units are made up of two or more major soils or miscellaneous areas. These map units are complexes, associations, or undifferentiated groups. A complex consists of two or more soils or miscellaneous areas in such an intricate pattern or in such small areas that they cannot be shown separately on the maps. 12 Custom Soil Resource Report The pattern and proportion of the soils or miscellaneous areas are somewhat similar in all areas. Alpha-Beta complex, 0 to 6 percent slopes, is an example. An association is made up of two or more geographically associated soils or miscellaneous areas that are shown as one unit on the maps. Because of present or anticipated uses of the map units in the survey area, it was not considered practical or necessary to map the soils or miscellaneous areas separately. The pattern and relative proportion of the soils or miscellaneous areas are somewhat similar. Alpha-Beta association, 0 to 2 percent slopes, is an example. An undifferentiated group is made up of two or more soils or miscellaneous areas that could be mapped individually but are mapped as one unit because similar interpretations can be made for use and management. The pattern and proportion of the soils or miscellaneous areas in a mapped area are not uniform. An area can be made up of only one of the major soils or miscellaneous areas, or it can be made up of all of them. Alpha and Beta soils, 0 to 2 percent slopes, is an example. Some surveys include miscellaneous areas. Such areas have little or no soil material and support little or no vegetation. Rock outcrop is an example. 13 Custom Soil Resource Report Transylvania County, North Carolina 12—Rosman-Reddies complex, 0 to 3 percent slopes, rarely flooded Map Unit Setting National map unit symbol: 2g8mx Elevation: 2,120 to 3,470 feet Mean annual precipitation: 65 to 85 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: All areas are prime farmland Map Unit Composition Rosman, rarely flooded, and similar soils:45 percent Reddies, rarely flooded, and similar soils: 30 percent Minor components: 3 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Rosman, Rarely Flooded Setting Landform:Valleys, flood plains Down-slope shape: Linear Across-slope shape: Linear Parent material: Loamy alluvium Typical profile A - 0 to 15 inches: fine sandy loam Bw- 15 to 59 inches: fine sandy loam C-59 to 80 inches: fine sandy loam Properties and qualities Slope: 0 to 3 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Very low Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table:About 42 to 60 inches Frequency of flooding: NoneRare Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.5 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 2w Hydrologic Soil Group: A Ecological site: F130BYO12WV- Non-Hydric Flood plains Hydric soil rating: No Description of Reddies, Rarely Flooded Setting Landform:Valleys, flood plains Down-slope shape: Linear Across-slope shape: Linear 14 Custom Soil Resource Report Parent material: Loamy alluvium over sandy and gravelly alluvium Typical profile Ap-0 to 14 inches: sandy loam Bw- 14 to 26 inches: fine sandy loam C-26 to 80 inches: very gravelly sand Properties and qualities Slope: 0 to 3 percent Depth to restrictive feature:20 to 40 inches to strongly contrasting textural stratification Drainage class: Moderately well drained Runoff class: Very low Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table:About 24 to 42 inches Frequency of flooding: NoneRare Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 3.4 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 2w Hydrologic Soil Group: B Ecological site: F130BYO12VVV- Non-Hydric Flood plains Hydric soil rating: No Minor Components Toxaway, rarely flooded Percent of map unit. 3 percent Landform:Valleys, depressions on flood plains Down-slope shape: Concave Across-slope shape: Concave Hydric soil rating: Yes 14—Dellwood-Reddies complex, 0 to 3 percent slopes, occasionally flooded Map Unit Setting National map unit symbol: 2g8n4 Elevation: 2,120 to 3,670 feet Mean annual precipitation: 65 to 85 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: Farmland of statewide importance Map Unit Composition Dellwood, occasionally flooded, and similar soils: 55 percent 15 Custom Soil Resource Report Reddies, occasionally flooded, and similar soils: 30 percent Minor components: 5 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Dellwood, Occasionally Flooded Setting Landform: Drainageways on flood plains, valleys Down-slope shape: Linear Across-slope shape: Linear Parent material: Sandy and gravelly alluvium Typical profile Ap-0 to 8 inches: gravelly fine sandy loam A2-8 to 16 inches: extremely gravelly sand C- 16 to 80 inches: extremely gravelly coarse sand Properties and qualities Slope: 0 to 3 percent Depth to restrictive feature: More than 80 inches Drainage class: Moderately well drained Runoff class: Very low Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table:About 24 to 48 inches Frequency of flooding: OccasionalNone Frequency of ponding: None Available water supply, 0 to 60 inches: Very low (about 2.9 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3s Hydrologic Soil Group: B Ecological site: F130BY012VVV- Non-Hydric Flood plains Hydric soil rating: No Description of Reddies, Occasionally Flooded Setting Landform: Flood plains on valleys Down-slope shape: Linear Across-slope shape: Linear Parent material: Loamy alluvium over sandy and gravelly alluvium Typical profile Ap-0 to 14 inches: sandy loam Bw- 14 to 26 inches: fine sandy loam C-26 to 80 inches: very gravelly sand Properties and qualities Slope: 0 to 3 percent Depth to restrictive feature:20 to 40 inches to strongly contrasting textural stratification Drainage class: Moderately well drained Runoff class: Very low Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table:About 24 to 42 inches 16 Custom Soil Resource Report Frequency of flooding: OccasionalNone Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 3.4 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 2w Hydrologic Soil Group: B Ecological site: F130BYO12VVV- Non-Hydric Flood plains Hydric soil rating: No Minor Components Ela, occasionally flooded Percent of map unit. 5 percent Landform: Depressions on flood plains, valleys Down-slope shape: Concave Across-slope shape: Concave Hydric soil rating: Yes 82—Toxaway loam, 0 to 2 percent slopes, occasionally flooded Map Unit Setting National map unit symbol: 2g8mz Elevation: 2,130 to 3,200 feet Mean annual precipitation: 65 to 85 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: Prime farmland if drained and either protected from flooding or not frequently flooded during the growing season Map Unit Composition Toxaway, occasionally flooded, and similar soils: 75 percent Minor components: 8 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Toxaway, Occasionally Flooded Setting Landform:Valleys, depressions on flood plains Down-slope shape: Concave Across-slope shape: Concave Parent material: Loamy alluvium Typical profile A - 0 to 23 inches: loam Cgl -23 to 36 inches: loam Cg2-36 to 80 inches: stratified sand to loam 17 Custom Soil Resource Report Properties and qualities Slope: 0 to 2 percent Depth to restrictive feature: More than 80 inches Drainage class:Very poorly drained Runoff class: Negligible Capacity of the most limiting layer to transmit water(Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table:About 0 to 12 inches Frequency of flooding: NoneOccasional Frequency of ponding: Occasional Available water supply, 0 to 60 inches: Moderate (about 8.9 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 7w Hydrologic Soil Group: B/D Ecological site: F130BY011VW- Hydric Floodplains Hydric soil rating: Yes Minor Components Ela, occasionally flooded Percent of map unit. 8 percent Landform:Valleys, depressions on flood plains Down-slope shape: Concave Across-slope shape: Concave Hydric soil rating: Yes 100C—Tusquitee-Whiteside complex, 8 to 15 percent slopes Map Unit Setting National map unit symbol: 2g8n5 Elevation: 2,320 to 4,690 feet Mean annual precipitation: 65 to 95 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: Farmland of statewide importance Map Unit Composition Tusquitee and similar soils:60 percent Whiteside and similar soils: 35 percent Minor components: 5 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Tusquitee Setting Landform: Fans on coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase 18 Custom Soil Resource Report Down-slope shape: Linear Across-slope shape: Linear Parent material: Loamy colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 8 inches: loam Bw- 8 to 48 inches: loam C-48 to 80 inches: gravelly fine sandy loam Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Low Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.7 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3e Hydrologic Soil Group: A Ecological site: F130BY005WV- Mesic Colluvium Cool Aspect Hydric soil rating: No Description of Whiteside Setting Landform: Fans on coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase Down-slope shape: Concave, linear Across-slope shape: Linear Parent material: Loamy colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 11 inches: loam Bt- 11 to 37 inches: loam Cg-37 to 80 inches: fine sandy loam Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Drainage class: Moderately well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table:About 24 to 36 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: High (about 9.5 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3e 19 Custom Soil Resource Report Hydrologic Soil Group: C Ecological site: F130BY005VVV- Mesic Colluvium Cool Aspect Hydric soil rating: No Minor Components Sylva Percent of map unit: 5 percent Landform: Seeps on coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase Down-slope shape: Linear Across-slope shape: Concave Hydric soil rating: Yes 101 D—Cullasaja-Tuckasegee complex, 15 to 30 percent slopes, very stony Map Unit Setting National map unit symbol: 2g8m8 Elevation: 2,120 to 4,810 feet Mean annual precipitation: 65 to 95 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 100 to 150 days Farmland classification: Not prime farmland Map Unit Composition Cullasaja, very stony, and similar soils: 50 percent Tuckasegee, very stony, and similar soils:40 percent Minor components: 1 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Cullasaja,Very Stony Setting Landform: Drainageways on coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase Down-slope shape: Linear Across-slope shape: Concave Parent material: Cobbly and stony colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 18 inches: very cobbly fine sandy loam Bw- 18 to 32 inches: very cobbly fine sandy loam C-32 to 80 inches: very cobbly loamy sand 20 Custom Soil Resource Report Properties and qualities Slope: 15 to 30 percent Surface area covered with cobbles, stones or boulders: 1.6 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 4.3 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6s Hydrologic Soil Group: A Ecological site: F130BY005WV- Mesic Colluvium Cool Aspect Hydric soil rating: No Description of Tuckasegee,Very Stony Setting Landform: Fans on coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase Down-slope shape: Linear Across-slope shape: Linear Parent material: Loamy colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 11 inches: loam Bw- 11 to 40 inches: gravelly fine sandy loam BC-40 to 80 inches: cobbly sandy clay loam Properties and qualities Slope: 15 to 30 percent Surface area covered with cobbles, stones or boulders: 1.6 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.3 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6s Hydrologic Soil Group: A Ecological site: F130BY005WV- Mesic Colluvium Cool Aspect Hydric soil rating: No 21 Custom Soil Resource Report Minor Components Cruso, very stony Percent of map unit. 1 percent Landform: Seeps on coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase Down-slope shape: Linear Across-slope shape: Concave Hydric soil rating: Yes 101 E—Cullasaja-Tuckasegee complex, 30 to 50 percent slopes, very stony Map Unit Setting National map unit symbol: 2g8m9 Elevation: 1,950 to 4,940 feet Mean annual precipitation: 65 to 95 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 100 to 150 days Farmland classification: Not prime farmland Map Unit Composition Cullasaja, very stony, and similar soils: 55 percent Tuckasegee, very stony, and similar soils: 35 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Cullasaja,Very Stony Setting Landform: Drainageways on coves Down-slope shape: Linear Across-slope shape: Concave Parent material: Cobbly and stony colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 18 inches: very cobbly fine sandy loam Bw- 18 to 32 inches: very cobbly fine sandy loam C-32 to 80 inches: very cobbly loamy sand Properties and qualities Slope: 30 to 50 percent Surface area covered with cobbles, stones or boulders: 1.6 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium 22 Custom Soil Resource Report Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 4.3 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6s Hydrologic Soil Group: A Ecological site: F130BY005WV- Mesic Colluvium Cool Aspect Hydric soil rating: No Description of Tuckasegee,Very Stony Setting Landform: Coves Down-slope shape: Concave Across-slope shape: Concave Parent material: Loamy colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 11 inches: gravelly loam Bw- 11 to 40 inches: gravelly fine sandy loam BC-40 to 80 inches: cobbly sandy clay loam Properties and qualities Slope: 30 to 50 percent Surface area covered with cobbles, stones or boulders: 1.6 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.3 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6e Hydrologic Soil Group: A Ecological site: F130BY005WV- Mesic Colluvium Cool Aspect Hydric soil rating: No 121C—Saunook loam, high precipitation, 8 to 15 percent slopes Map Unit Setting National map unit symbol: 2vx58 23 Custom Soil Resource Report Elevation: 1,350 to 4,610 feet Mean annual precipitation: 59 to 88 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: Farmland of statewide importance Map Unit Composition Saunook and similar soils: 85 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Saunook Setting Landform: Drainageways, fans, coves Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase, base slope Down-slope shape: Concave, linear Across-slope shape: Concave, linear Parent material: Colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 10 inches: loam Bt- 10 to 34 inches: clay loam BC-34 to 44 inches: cobbly fine sandy loam C-44 to 80 inches: very cobbly fine sandy loam Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 7.4 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3e Hydrologic Soil Group: B Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No 121 D—Saunook loam, high precipitation, 15 to 30 percent slopes, stony Map Unit Setting National map unit symbol. 2xpcm Elevation: 1,420 to 4,720 feet Mean annual precipitation: 50 to 67 inches Mean annual air temperature: 46 to 57 degrees F 24 Custom Soil Resource Report Frost-free period: 100 to 150 days Farmland classification: Farmland of local importance Map Unit Composition Saunook, stony, and similar soils: 89 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Saunook, Stony Setting Landform: Coves, drainageways, fans Landform position (two-dimensional): Footslope Landform position (three-dimensional): Mountainbase, base slope Down-slope shape: Concave, linear Across-slope shape: Concave, linear Parent material: Colluvium derived from igneous and metamorphic rock Typical profile A - 0 to 10 inches: loam Bt- 10 to 34 inches: clay loam BC-34 to 44 inches: cobbly fine sandy loam C-44 to 80 inches: very cobbly fine sandy loam Properties and qualities Slope: 15 to 30 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: High Capacity of the most limiting layer to transmit water(Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 7.4 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 4e Hydrologic Soil Group: B Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No 125C—Tate loam, high precipitation, 8 to 15 percent slopes Map Unit Setting National map unit symbol. 2xkfh Elevation: 2,210 to 3,560 feet Mean annual precipitation: 54 to 73 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: Farmland of statewide importance 25 Custom Soil Resource Report Map Unit Composition Tate, high precipitation, and similar soils: 85 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Tate, High Precipitation Setting Landform: Fans, coves Landform position (two-dimensional): Toeslope Landform position (three-dimensional): Mountainbase, base slope Down-slope shape: Linear, concave Across-slope shape: Concave Parent material: Colluvium derived from metamorphic rock Typical profile A - 0 to 7 inches: loam Bt- 7 to 46 inches: clay loam C-46 to 80 inches: cobbly loam Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.5 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3e Hydrologic Soil Group: B Ecological site: F130BY006WV- Mesic Colluvium Warm Aspect Hydric soil rating: No 125D—Tate loam, high precipitation, 15 to 30 percent slopes, stony Map Unit Setting National map unit symbol. 2xkf9 Elevation: 2,220 to 3,780 feet Mean annual precipitation: 54 to 72 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 116 to 170 days Farmland classification: Farmland of local importance Map Unit Composition Tate, high precipitation, and similar soils: 85 percent Estimates are based on observations, descriptions, and transects of the mapunit. 26 Custom Soil Resource Report Description of Tate, High Precipitation Setting Landform: Fans, coves Landform position (two-dimensional): Toeslope Landform position (three-dimensional): Mountainbase, base slope Down-slope shape: Linear, concave Across-slope shape: Concave Parent material: Colluvium derived from metamorphic rock Typical profile A - 0 to 7 inches: loam Bt- 7 to 46 inches: clay loam C-46 to 80 inches: cobbly loam Properties and qualities Slope: 15 to 30 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: High Capacity of the most limiting layer to transmit water(Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.5 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 4e Hydrologic Soil Group: B Ecological site: F130BY006WV- Mesic Colluvium Warm Aspect Hydric soil rating: No 393D—Chestnut-Edneyvilie complex, high precipitation, 15 to 30 percent slopes, stony Map Unit Setting National map unit symbol: 2t2yc Elevation: 2,230 to 4,730 feet Mean annual precipitation: 55 to 84 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 124 to 176 days Farmland classification: Not prime farmland Map Unit Composition Chestnut and similar soils: 50 percent Edneyville and similar soils: 35 percent Estimates are based on observations, descriptions, and transects of the mapunit. 27 Custom Soil Resource Report Description of Chestnut Setting Landform: Ridges Landform position (two-dimensional): Summit Landform position (three-dimensional): Mountaintop, crest Down-slope shape: Linear Across-slope shape: Convex Parent material: Residuum weathered from muscovite-biotite gneiss and/or biotite gneiss Typical profile A - 0 to 5 inches: gravelly fine sandy loam Bw- 5 to 29 inches: fine sandy loam Cr-29 to 80 inches: bedrock Properties and qualities Slope: 15 to 30 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature:20 to 40 inches to paralithic bedrock Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat):Very low to high (0.00 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 3.6 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 4s Hydrologic Soil Group: B Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No Description of Edneyville Setting Landform: Ridges Landform position (two-dimensional): Summit Landform position (three-dimensional): Mountaintop, crest Down-slope shape: Linear Across-slope shape: Convex Parent material: Residuum weathered from muscovite-biotite gneiss and/or biotite gneiss Typical profile A - 0 to 5 inches: gravelly fine sandy loam Bw- 5 to 25 inches: fine sandy loam C-25 to 80 inches: gravelly sandy loam Properties and qualities Slope: 15 to 30 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained 28 Custom Soil Resource Report Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 6.4 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 4e Hydrologic Soil Group: A Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No 393E—Chestnut-Edneyville complex, high precipitation, 30 to 50 percent slopes, stony Map Unit Setting National map unit symbol: 2t2y7 Elevation: 2,120 to 4,920 feet Mean annual precipitation: 52 to 84 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 124 to 176 days Farmland classification: Not prime farmland Map Unit Composition Chestnut and similar soils: 50 percent Edneyville and similar soils:40 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Chestnut Setting Landform: Ridges, mountain slopes Landform position (three-dimensional): Mountaintop, mountainflank, crest, side slope Down-slope shape: Linear, convex Across-slope shape: Convex, linear Parent material: Residuum weathered from muscovite-biotite gneiss and/or biotite gneiss that is affected by soil creep in the upper solum Typical profile A - 0 to 5 inches: gravelly fine sandy loam Bw- 5 to 29 inches: fine sandy loam Cr-29 to 80 inches: bedrock Properties and qualities Slope: 30 to 50 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature:20 to 40 inches to paralithic bedrock 29 Custom Soil Resource Report Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat):Very low to high (0.00 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 3.6 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6s Hydrologic Soil Group: B Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No Description of Edneyville Setting Landform: Ridges, mountain slopes Landform position (three-dimensional): Mountaintop, mountainflank, crest, side slope Down-slope shape: Linear, convex Across-slope shape: Convex, linear Parent material: Residuum weathered from muscovite-biotite gneiss and/or biotite gneiss that is affected by soil creep in the upper solum Typical profile A - 0 to 5 inches: gravelly fine sandy loam Bw- 5 to 25 inches: fine sandy loam C-25 to 80 inches: gravelly sandy loam Properties and qualities Slope: 30 to 50 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature: More than 80 inches Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat): High (1.98 to 5.95 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 6.6 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6e Hydrologic Soil Group: A Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No 30 Custom Soil Resource Report 761 E—Porters-U naka complex, 30 to 50 percent slopes, stony Map Unit Setting National map unit symbol: 2g8kw Elevation: 2,250 to 5,030 feet Mean annual precipitation: 65 to 95 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 100 to 150 days Farmland classification: Not prime farmland Map Unit Composition Porters, stony, and similar soils: 50 percent Unaka, stony, and similar soils: 30 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Porters, Stony Setting Landform: Ridges, mountain slopes Landform position (two-dimensional): Backslope Down-slope shape: Convex Across-slope shape: Convex, linear Parent material: Residuum weathered from muscovite-biotite gneiss and/or biotite gneiss that is affected by soil creep in the upper solum Typical profile A - 0 to 9 inches: loam Bw- 9 to 46 inches: gravelly loam C-46 to 54 inches: gravelly sandy loam R-54 to 80 inches: unweathered bedrock Properties and qualities Slope: 30 to 50 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature:40 to 60 inches to lithic bedrock Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat):Very low to low (0.00 to 0.01 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 8.0 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6e Hydrologic Soil Group: A Ecological site: F130BY003WV- Mesic Residuum Cool Aspect Hydric soil rating: No 31 Custom Soil Resource Report Description of Unaka, Stony Setting Landform: Ridges, mountain slopes Landform position (two-dimensional): Backslope Down-slope shape: Convex Across-slope shape: Convex, linear Parent material: Residuum weathered from muscovite-biotite gneiss and/or biotite gneiss that is affected by soil creep in the upper solum Typical profile A - 0 to 9 inches: loam Bw- 9 to 27 inches: gravelly loam Cr-27 to 31 inches: weathered bedrock R-31 to 80 inches: unweathered bedrock Properties and qualities Slope: 30 to 50 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature:20 to 35 inches to paralithic bedrock; 20 to 40 inches to lithic bedrock Drainage class:Well drained Runoff class: Very high Capacity of the most limiting layer to transmit water(Ksat):Very low to low (0.00 to 0.01 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 4.3 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 6s Hydrologic Soil Group: B Ecological site: F130BY003WV- Mesic Residuum Cool Aspect Hydric soil rating: No 793F—Ashe-Buladean-Rock outcrop complex, 50 to 95 percent slopes, very stony Map Unit Setting National map unit symbol: 2g8kh Elevation: 1,510 to 5,070 feet Mean annual precipitation: 65 to 95 inches Mean annual air temperature: 46 to 57 degrees F Frost-free period: 124 to 176 days Farmland classification: Not prime farmland Map Unit Composition Ashe, very stony, and similar soils: 50 percent 32 Custom Soil Resource Report Buladean, very stony, and similar soils: 20 percent Rock outcrop: 15 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Ashe,Very Stony Setting Landform: Mountain slopes Landform position (two-dimensional): Backslope Landform position (three-dimensional): Side slope Down-slope shape: Convex Across-slope shape: Linear Parent material: Residuum weathered from granite and gneiss that is affected by soil creep in the upper solum Typical profile A - 0 to 5 inches: gravelly sandy loam Bw- 5 to 31 inches: gravelly sandy loam R-31 to 80 inches: unweathered bedrock Properties and qualities Slope: 50 to 95 percent Surface area covered with cobbles, stones or boulders: 1.6 percent Depth to restrictive feature:20 to 40 inches to lithic bedrock Drainage class: Somewhat excessively drained Runoff class: Very high Capacity of the most limiting layer to transmit water(Ksat):Very low to low (0.00 to 0.01 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Low (about 3.2 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 8s Hydrologic Soil Group: B Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No Description of Buladean,Very Stony Setting Landform: Ridges, mountain slopes Landform position (two-dimensional): Backslope Landform position (three-dimensional): Side slope Down-slope shape: Convex Across-slope shape: Linear Parent material: Residuum weathered from granite and gneiss that is affected by soil creep in the upper solum Typical profile A - 0 to 3 inches: loam Bw-3 to 26 inches: loam C-26 to 50 inches: coarse sandy loam Cr-50 to 80 inches: weathered bedrock 33 Custom Soil Resource Report Properties and qualities Slope: 50 to 95 percent Surface area covered with cobbles, stones or boulders: 0.1 percent Depth to restrictive feature:40 to 60 inches to paralithic bedrock Drainage class:Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water(Ksat):Very low to high (0.00 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water supply, 0 to 60 inches: Moderate (about 6.6 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 8e Hydrologic Soil Group: A Ecological site: F130BY004WV- Mesic Residuum Warm Aspect Hydric soil rating: No Description of Rock Outcrop Setting Landform: Mountain slopes Down-slope shape: Convex Across-slope shape: Convex Parent material: Granite and gneiss Typical profile R-0 to 80 inches: bedrock Properties and qualities Depth to restrictive feature: 0 inches to lithic bedrock Runoff class: Very high Capacity of the most limiting layer to transmit water(Ksat):Very low to low (0.00 to 0.01 in/hr) Available water supply, 0 to 60 inches: Very low (about 0.0 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 8s Hydric soil rating: No 34 References American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing. 24th edition. American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes. ASTM Standard D2487-00. Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe. 1979. Classification of wetlands and deep-water habitats of the United States. U.S. Fish and Wildlife Service FWS/OBS-79/31. Federal Register. July 13, 1994. Changes in hydric soils of the United States. Federal Register. September 18, 2002. Hydric soils of the United States. Hurt, G.W., and L.M. Vasilas, editors. Version 6.0, 2006. Field indicators of hydric soils in the United States. National Research Council. 1995. Wetlands: Characteristics and boundaries. Soil Survey Division Staff. 1993. Soil survey manual. Soil Conservation Service. U.S. Department of Agriculture Handbook 18. http://www.nres.usda.gov/wps/portal/ n res/d eta i I/n ati o n a I/s o i Is/?cid=n res 142 p2_0 54262 Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys. 2nd edition. Natural Resources Conservation Service, U.S. Department of Agriculture Handbook 436. http:// www.nres.usda.gov/wps/portal/nres/detail/national/soils/?cid=nres142p2_053577 Soil Survey Staff. 2010. Keys to soil taxonomy. 11th edition. U.S. Department of Agriculture, Natural Resources Conservation Service. http:// www.nres.usda.gov/wps/portal/nres/detail/national/soils/?cid=nres142p2_053580 Tiner, R.W., Jr. 1985. Wetlands of Delaware. U.S. Fish and Wildlife Service and Delaware Department of Natural Resources and Environmental Control, Wetlands Section. United States Army Corps of Engineers, Environmental Laboratory. 1987. Corps of Engineers wetlands delineation manual. Waterways Experiment Station Technical Report Y-87-1. United States Department of Agriculture, Natural Resources Conservation Service. National forestry manual. http://www.nres.usda.gov/wps/portal/nres/detail/soils/ home/?cid=nres142p2_053374 United States Department of Agriculture, Natural Resources Conservation Service. National range and pasture handbook. http://www.nres.usda.gov/wps/portal/nres/ detail/national/landuse/rangepastu re/?cid=stelprdb1043084 35 Custom Soil Resource Report United States Department of Agriculture, Natural Resources Conservation Service. National soil survey handbook, title 430-VI. http://www.nres.usda.gov/wps/portal/ n res/d eta i I/so i Is/scie ntists/?cid=n res 142 p2_054242 United States Department of Agriculture, Natural Resources Conservation Service. 2006. Land resource regions and major land resource areas of the United States, the Caribbean, and the Pacific Basin. U.S. Department of Agriculture Handbook 296. http://www.nres.usda.gov/wps/portal/nres/detail/national/soils/? cid=n res 142 p2_05 3624 United States Department of Agriculture, Soil Conservation Service. 1961. Land capability classification. U.S. Department of Agriculture Handbook 210. http:H www.nrcs.usda.gov/lnternet/FSE—DOCUMENTS/nrcsl 42p2_052290.pdf 36 Appendix J — Report of Geotechnical Exploration REPORT OF GEOTECHNICAL EXPLORATION BOBBY N. SETZER STATE FISH HATCHERY RENOVATION Prepared For: NC WILDLIFE RESOURCES COMMISSION c/o McGill Associates 55 Broad Street Asheville, North Carolina 28801 BLE Project Number J20-14503-02 December 8,2021 111. 10 BUNNELL LAMMONS ENGINEERING 130 Oval Road,Suite 200 I Arden.NC 28704 B28.277,0100 re 828.277,0110 w info@hlerorp.com BLECQRP.CIIM IM I BUNNELL M LAMMONS ENOINEERIN6 December 8,2021 NC Wildlife Resources Commission c/o McGill Associates 55 Broad Street Asheville,North Carolina 28801 Attention: Mr. Kyle Seaman, P.E. Subject: Report of Detailed Geotechnical Exploration Bobby N. Setzer State Fish Hatchery Renovation Transylvania County,North Carolina BLE Project Number J20-14503-02 Dear Mr. Seaman: Bunnell-Lammons Engineering, Incorporated (BLE)is pleased to present this Report of our findings and recommendations for renovations at the subject facility. This exploration was performed generally as described in your Task Order T.O. #2 09-08-21. This report covers multiple structures, but our findings and recommendations have been consolidated into this one report for your convenience. We appreciate the opportunity to provide our professional services on this project. Please feel free to contact the authors with additional questions or comments. \`\Xo\\1I I I I I Ul////�/i i Sincerely, ,�`��o�.�"....A9O BUNNELL LAMMONs ENGINEERING INC. `OFESS�O'•`f� t' Firm Registration: C-1538 SEAL 023614 = Sam C.Interlicchia James e erl,P.E. Project Manager Senior Engineer NC Registration#023614 ' 130 Oval Rood,Suite 200,Arden,NC 28704 L828.277.0100 0828.277.0110 .-+info@blecorp.com BLECORMOM IC 1.11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 TABLE OF CONTENTS SECTION 1. PROJECT INFORMATION..............................................................................................I 1.1 AUTHORIZATION.......................................................................................................................1 1.2 SCOPE OF EXPLORATION.......................................................................................................1 1.3 PROJECT INFORMATION........................................................................................................1 1.4 SITE AND GEOLOGIC FEATURES.........................................................................................2 1.5 LIMITATIONS..............................................................................................................................3 SECTION 2. DAVIDSON RIVER INTAKE............................................................................................3 2.1 DISCUSSION OF FINDINGS......................................................................................................3 2.2 ASSESSMENT...............................................................................................................................4 2.3 RECOMMENDATIONS...............................................................................................................4 SECTION 3. GROGAN CREEK INTAKE..............................................................................................5 3.1 DISCUSSION OF FINDINGS......................................................................................................5 3.2 ASSESSMENT...............................................................................................................................6 3.3 RECOMMENDATIONS...............................................................................................................6 SECTION 4. EQUALIZATION BASIN...................................................................................................6 4.1 DISCUSSION OF FINDINGS......................................................................................................6 4.2 ASSESSMENT...............................................................................................................................7 4.3 RECOMMENDATIONS...............................................................................................................7 SECTION 5. NEW BROODSTOCK RACEWAYS................................................................................8 5.1 DISCUSSION OF FINDINGS......................................................................................................8 5.2 ASSESSMENT...............................................................................................................................8 5.3 RECOMMENDATIONS...............................................................................................................9 SECTION 6. NEW EFFLUENT PUMP STATION................................................................................9 6.1 DISCUSSION OF FINDINGS......................................................................................................9 6.2 ASSESSMENT.............................................................................................................................10 6.3 RECOMMENDATIONS.............................................................................................................10 i of ii IC 1.11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 SECTION 7. PRODUCTION RACEWAYS..........................................................................................11 7.1 DISCUSSION OF FINDINGS....................................................................................................11 7.2 ASSESSMENT.............................................................................................................................12 7.3 RECOMMENDATIONS.............................................................................................................12 SECTION 8. PROPOSED HATCHERY BUILDING...........................................................................12 8.1 DISCUSSION OF FINDINGS....................................................................................................12 8.2 ASSESSMENT.............................................................................................................................12 8.3 RECOMMENDATIONS.............................................................................................................13 SECTION 9. FUTURE DEVELOPMENT.............................................................................................13 9.1 DISCUSSION OF FINDINGS....................................................................................................13 9.2 ASSESSMENT.............................................................................................................................14 9.3 RECOMMENDATIONS.............................................................................................................14 SECTION 10.0 CONSTRUCTION CONSIDERATIONS....................................................................14 10.1 STRUCTURAL FILL..................................................................................................................14 10.2 SUBGRADE ACCEPTANCE.....................................................................................................15 10.3 DIFFICULT EXCAVATION.....................................................................................................15 10.4 GROUNDWATER CONTROL .................................................................................................15 APPENDIX ii of ii IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 SECTION 1. PROJECT INFORMATION 1.1 AUTHORIZATION This exploration was performed as described in Bunnell-Lammons Engineering (BLE) Draft Proposal of April 13, 2021 and authorized by Mr. Kyle Seaman, P.E.by Task Order 42 on September 8, 2021. 1.2 SCOPE OF EXPLORATION This report details the findings and recommendations of the geotechnical exploration performed for the proposed renovations as detailed in Table 1-1. Table 1-1 Exploratory Boring Distribution Boring Number Location B-1 Davidson River Intake B-2 Grogan Creek Intake B-3 Equalization Basin B-4 Broodstock Raceways B-5 Effluent Waste Treatment B-6 Production Raceways B-7 Hatchery Building B-8 Future Development B-9 Future Development In anticipation of the drilling encountering large, impenetrable boulders and cobbles, a specialized drilling unit of the sonic variety was mobilized to the site. This type of drill rig is capable of penetrating the expected boulders and cobbles and is equipped with the tooling to enable collection of Standard Penetration Test(SPT) samples to enable stratification of the encountered soils and collection of SPT N-values to be used as the basis of BLE's design recommendations. Typical geotechnical drilling is conducted with steel augers which are generally not able to penetrate the cobbles and boulders common to this setting. In addition to the SPT testing, McGill had requested the capability of long-term groundwater measurements. BLE recommended the use of simple, inexpensive, standpipe piezometers at the locations requested. Accordingly, hand-slotted, PVC pipes were installed at B-3, B-5, B-8, and B-9 to the bottom of the open borehole before backfilling. The water levels on those boring logs represent the initial reading of the standpipe piezometers. 1.3 PROJECT INFORMATION The Setzer Fish Hatchery property is a mountainous tract located in the Pisgah National Forest in Transylvania County North Carolina off US 276 on a local road known as Government Road (a.k.a. US Forest Service Road 4475). The property is bounded on the north by the aforementioned road and the Davidson River. The site is understood to have been developed by placement of earth fill and straightening a section of the Davidson River near its confluence with Grogan Creek. The development has created a broad, flat section on which prior facilities were built and the new structures and renovated structures are to be constructed. 1 of 15 IC 1.1: Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLR Project No.J20-14503-02 This report includes the following Sections hereinafter: Section 2.0 Davidson River Intake Section 3.0 Grogan Creek Intake Section 4.0 New Equalization Basin Section 5.0 New Broodstock Raceways Section 6.0 New Effluent Treatment Section 7.0 New Production Raceways Section 8.0 Hatchery Building Renovations Section 9.0 Future Development Section 10.0 Construction Considerations 1.4 SITE AND GEOLOGIC FEATURES The site area has typical mountainous characteristics for Western North Carolina with ground elevations ranging from over 3900 feet above msl (Looking Glass Rock) to below 2400 feet above msl in the drainageway of the Davidson River and Grogan Creek. The property is mostly wooded except for those portions which have undergone development for the Fish Hatchery. No additional land clearing is indicated by the provided plans. The site is located in the Blue Ridge Physiographic Province. The bedrock in this region is a complex crystalline formation that has been faulted and contorted by past tectonic movements. A notable shear zone (i.e.the Brevard Fault Zone)gains its name from the nearby Town of Brevard,NC and is considered to be associated with the Appalachian Orogeny,during which the surrounding mountains and folded valleys and ridges to the northwest were formed. The bedrock in the area is mapped as gneissic, metamorphic rock with significant amounts of micaceous minerals. Also mapped within the nearby units are occasional units of mica schist. Finally, intrusive igneous rocks are also present in the region. Looking Glass Rock is one such exposure of the Whiteside Granite, considered to be a volcanic pluton intruded into the older gneissic rocks. Granitic rocks are not expected in the subsurface in the immediate area of the site. The rock has weathered to residual soils which form the mantle for the hillsides and hilltops. The typical residual soil profile in areas not disturbed by erosion or human activities consists of clayey soils near the surface where weathering is more advanced,underlain by sandy silts and silty sands. The boundary between soil and rock is not sharply defined,and there often is a transitional zone,termed"partially weathered rock," overlying the parent bedrock. Partially weathered rock is defined, for engineering purposes, as residual material with a standard penetration resistance of at least 100 blows per foot(bpf). Weathering is facilitated by fractures,joints, and the presence of less resistant rock types. Consequently,the profile of the partially weathered rock and hard rock is quite irregular and erratic,even over short horizontal distances. Also,it is not unusual to find lenses and boulders of hard rock and/or zones of partially weathered rock within the soil mantle,well above the general bedrock level. In addition to the residual profile the Davidson River and its tributaries (Grogan Creek,for instance)have, over many millennia, deposited many layers of alluvial soils of a clastic nature, including the cobbles and boulders described in an earlier paragraph. Finally, the area of prior development has been graded to its current level and slope by the placement of man-placed fill(s)to raise the grade out of the flooding potential 2of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 from the Davidson River. Despite these efforts,we are advised that the crest of the Davidson River exceed the grades at the hatchery site during Tropical Storm Fred in August of 2021. 1.5 LIMITATIONS This exploration is preliminary in nature with widely spaced data points (borings). These data and should be used for general site planning, feasibility evaluation, and general foundation design only. Because of the relatively limited information available at this stage of the project, foundation design and site preparation recommendations may require supplemental exploration and additional analysis. Bunnell-Lammons Engineering should be retained to consult with the designer during design,and construction phases to be sure that the preliminary recommendations are properly interpreted and further developed as necessary. Our evaluation and recommendations for this preliminary geotechnical exploration has been based on our understanding of the project and site information and data obtained in our exploration and provided to us. The general subsurface conditions utilized in our evaluations and analyses are based on interpolation of subsurface data between the widely spaced soil test borings. The assessment of site environmental conditions or presence of pollutants in the soil,rock,and ground water of the site was beyond the scope of this exploration. SECTION 2.DAVIDSON RIVER INTAKE 2.1 DISCUSSION OF FINDINGS The Davidson River Intake is an existing facility which is to be renovated by the addition of a Grit Chamber located about 50 feet to the south of the existing structure and connected by piping. The chamber is a 20-foot diameter concrete unit with a sloping bottom to separate larger fractions from any sediment load. The approximate elevations for the various structural elements are as shown in Table 2-1. Table 2-1 Elevations Element Elevation Floor of Existing Intake 2358.05 Top of Existing Intake 2371.88 Inletto Grit Chamber(centerline) 2353.16 Invert of Grit Chamber 2339.25 Bottom Grit Chamber 2338.75f Subsurface conditions at this structure were evaluated by review of samples from Boring B-1. Boring B-1 encountered approximately 3 to 5 feet of fill underlain by soils BLE interprets to be of residual origin. Residual soils and Partially Weathered Rock extend to the terminal depth of the boring at 25 feet. Based on an approximate ground surface elevation of 2368 at B-1,BLE considers the strata elevations and SPT Resistance (blows per foot)shown in Table 2-2 to be applicable to this location. 3of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLR Project No.J20-14503-02 Table 2-2 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2367 N=12 Top of Residual Soil(bottom of fill) 2362 47<N<66 Top of Partially Weathered Rock 2354 16<N<100+ Bottom of Boring 2342 - Below the shallow stratum of fill, Boring B-1 encountered soils with a relatively high density and strength. Additionally,Boring B-1 did not encounter large,cobbles or boulders but rather rock fragments of fine gravel size that may have been a component ofthe fill or rock fragments created by the drilling. Some of the N-values in this stratum may have been inflated by the gravel or rock fragments. Groundwater was encountered in Boring B-1 at a depth of just over 5 feet(approximate elevation 2362)at the time of drilling 2.2 ASSESSMENT Soils or weathered rock having more than sufficient strength and sufficiently low compressibility are present to the depths drilled in this boring and expected to be present even deeper. Applied stresses from the grit chamber are expected to be less than about 3000 pounds per square foot(psf). The shallow groundwater encountered is of concern from the standpoint of excavation wall and bottom stability for the expected 31-foot excavation. Also, buoyant forces on the sealed structure are expected to exceed the dead load when the structure is in a de-watered condition. Excavation by conventional methods and equipment is considered to be feasible at this location. That is,large rock or fragments of rock are not expected to be encountered above the bearing level. On the other hand,the depth of excavation is substantial and groundwater issues will be substantial. The use of a braced excavation will likely be required for placement of this unit "in the dry". If excavation "in the wet" is planned sloped excavation and tremie placement of concrete will be almost inevitable. 2.3 RECOMMENDATIONS Allowable bearing at the foundation level of in excess of 4,000 psf is available at this location,providing the bottom of the excavation is stable and not subject to disturbance by seepage forces. BLE recommends resistance to buoyant forces be provided by increased mass concrete or by reinforced concrete foundation beyond the perimeter of the structure (i.e., a lip) reacting against the overlying backfill. Anchors bonded into the PWR subgrade are also feasible,but are not considered the most practical solution. Further consideration of the excavation, shoring,and other means and methods of this construction will be required. 4of15 IC 1.1: Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 SECTION 3. GROGAN CREEK INTAKE 3.1 DISCUSSION OF FINDINGS The Grogan Creek Intake is an existing facility which is to be renovated by the addition of a Grit Chamber located about 40 feet to the west of the existing structure and connected by piping. In addition, a wet well structure will attach to the Grit Chamber. The Grit Chamber is a 10-foot diameter,pre-cast concrete unit with a sloping bottom to separate larger fractions from any sediment load. The wet well is also a pre-cast concrete structure with a flat bottom. The approximate elevations for the various structural elements of the renovation are as shown in Table 3-1. Table 3-1 Elevations Element Elevation Floor of Existing Intake 2378.28 Top of Existing Intake 2383.98 Inlet to Grit Chamber(invert) 2372.42 Invert of Grit Chamber 2366.25 Bottom Grit Chamber 2365.25f Subsurface conditions at this structure were evaluated by review of samples from Boring B-2. Boring B-2 encountered approximately 6 feet of fill underlain by soils BLE interprets to be of residual origin. Residual soils and Partially Weathered Rock extend to the terminal depth of the boring at 25 feet. Based on an approximate ground surface elevation of 2379 at B-2,BLE considers the strata elevations and SPT Resistance (blows per foot)shown in Table 3-2 to be applicable to this location. Table 3-2 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2379 2<N<10 Top of Residual Soil(bottom of fill) 2373 N=33 Top of Partially Weathered Rock 2370.5 100<N Bottom of Boring 2366.5 - Below the stratum of fill,Boring B-2 encountered soils with a relatively high density and strength. Additionally Boring B-2 did not encounter large,cobbles or boulders but rather rock fragments or fine gravel size that may have been a component of the fill or rock fragments created by the drilling. Some of the N-values in this stratum may have been inflated by the gravel or rock fragments. Groundwater was encountered in Boring B-2 at a depth of 4 feet(approximate elevation 2375) at the time of drilling. 5of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 3.2 ASSESSMENT Soils or weathered rock having more than sufficient strength and sufficiently low compressibility are present to the depths drilled in this boring and expected to be present even deeper. Applied stresses from the grit chamber are expected to be less than about 1700 pounds per square foot(psf). The shallow groundwater encountered is of concern from the standpoint of excavation wall and bottom stability for the expected 20-foot excavation. Also, buoyant forces on the sealed structure are expected to exceed the dead load when the structure is in a de-watered condition. Excavation by conventional methods and equipment is considered to be feasible at this location. That is,large rock or fragments of rock are not expected to be encountered above the partially weathered rock stratum. On the other hand the depth of excavation is substantial and groundwater issues will be substantial. The use of a braced excavation will likely be required for placement of this unit"in the dry". If excavation"in the wet"is planned sloped excavation and tremie placement of concrete will be almost inevitable. 3.3 RECOMMENDATIONS Allowable bearing at the foundation level of in excess of 5,000 psf is available at this location,providing the bottom of the excavation is stable and not subject to disturbance by seepage forces. BLE recommends resistance to buoyant forces be provided by increased mass concrete or by reinforced concrete foundation beyond the perimeter of the structure (Le a lip) reacting against the overlying backfill. Anchors bonded into the PWR subgrade are also feasible but are not considered the most practical solution. Further consideration of the excavation, shoring,and other means and methods of this construction will be required. SECTION 4. EQUALIZATION BASIN 4.1 DISCUSSION OF FINDINGS The Equalization Basin is new facility which will equalize flow from various elements of the total system. The basin is essentially a shallow concrete box with ten penetrations by pipes of between 4 inches and 30 inches in diameter. The approximate elevations for the various structural elements of the new facility are as shown in Table 4-1. Table 4-1 Elevations Element Elevation Top of Equalization Basin 2356.50 Outlet of Equalization Basin 2355.85 Floor of Equalization Basin 2351.75 Bottom of Equalization Basin 2351.00± Subsurface conditions at this structure were evaluated by review of samples from Boring B-3. Boring B-3 encountered approximately 8 feet of fill underlain by soils BLE interprets to be of alluvial origin,thence soils BLE interprets to be of residual origin. Residual soils extend to the terminal depth of the boring at 20 feet. 6of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 Based on an approximate ground surface elevation of 2355 at B-3,BLE considers the strata elevations and SPT Resistance(blows per foot) shown in Table 4-2 to be applicable to this location. Table 4-2 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2355 4<N<30 Top of Alluvial Soil(bottom of fill) 2347 N=35 Top of Residual Soil 2342.5 8<N<10 Bottom of Boring 2335 - Below the stratum of fill, Boring B-3 encountered soils with a moderately high density and strength. Additionally, Boring B-3 did not encounter large cobbles or boulders but did encounter an alluvial soil with rounded rock fragments. Some of the N-values in this stratum may have been inflated by the gravel or rock fragments. Groundwater was encountered in Boring B-3 at a depth of 7 feet(approximate elevation 2348) at the time of drilling and at a depth of 6 feet(approximate elevation 2349)24 hours after drilling. 4.2 ASSESSMENT Fill soils at this location at the bottom of structure depth are not considered to have sufficient strength or sufficiently low compressibility to support even the low imposed loading at this location. However, soils having sufficient strength and compressibility are present slightly below the plan depth. Applied stresses from the equalization basin are expected to be less than about 500 pounds per square foot(psf). The groundwater encountered at this location is expected to be below the level of excavation, and probable undercut for subgrade stabilization. Buoyant forces,if any, on the sealed structure are not expected to exceed the dead load when the structure is in a de-watered condition. Excavation by conventional methods and equipment is considered to be feasible at this location. 4.3 RECOMMENDATIONS Allowable bearing at the foundation level,after remedial undercut and replacement, of in excess of 2,000 psf will be available at this location,providing the bottom of the excavation is stable and not subject to disturbance by seepage forces. BLE recommends that remedial work consisting of undercut/replacement to at least 2 feet below the bottom ofthe structure be completed and the undercut volume be replaced by select granular material back to the structure subgrade elevation. The granular material may consist of either open-graded stone such as 457 or dense-graded stone such as NC DOT ABC Stone. The selection may be based on the groundwater condition at the time of construction. If groundwater is encountered in the excavation,the open-graded stone will be the preferred option. The granular material should be compacted in lifts not exceeding 12 inches using methods appropriate for the gradation. 7of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 SECTION 5. NEW BROODSTOCK RACEWAYS 5.1 DISCUSSION OF FINDINGS The New Broodstock Raceways are shallow concrete structures with a hydraulic flow caused by a gradient between the inflow end of the structure and the outflow end of the structure. The floor of the structure slopes at 0.5 percent from the inlet end to the effluent end of the structure The approximate elevations for the various structural elements are as shown in Table 5-1. Table 5-1 Elevations Element Elevation (site datum) Top of Side Wall 2358.28 Inlet Control Section 2358.30 Raceway Water Level 2357.26 Raceway Floor(effluent end) 2354.92 Bottom of Structure 2354.00± Subsurface conditions at this structure were evaluated by review of samples from Boring B-4. Boring B-4 encountered approximately 6 feet of fill underlain by soils BLE interprets to be of alluvial origin,thence soils BLE interprets to be of residual origin. Residual materials extend to the terminal depth of the boring at 10 feet. Based on an approximate ground surface elevation of 2357 at B-4,BLE considers the strata elevations and SPT Resistance(blows per foot) shown in Table 5-2 to be applicable to this location. Table 5-2 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2357 44<N<48 Top of Alluvial Soil(bottom of fill) 2351 N=100+ Top of Residual Soil 2348.5 N=100+ Bottom of Boring 2347 - Below the stratum of fill,Boring B-4 encountered soils with a high density and strength. Additionally,Boring B-4 did not encounter large cobbles or boulders but did encounter an alluvial soil with rounded rock fragments. Some of the N-values in this stratum may have been inflated by the gravel or rock fragments. Groundwater was encountered in Boring B-4 at a depth of 5.3 feet approximate elevation 2352) at the time of drilling. The boring caved at a depth of 7 feet at the end of the day. 5.2 ASSESSMENT Fill soils at this location at the bottom of structure depth are not considered to have sufficient strength or sufficiently low compressibility to support even the low imposed loading at this location,despite the relatively 8of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 high N-values. However, soils having sufficient strength and compressibility are present slightly below the plan depth. Applied stresses from the Broodstock Raceways are expected to be less than about 400 pounds per square foot(psf). The groundwater encountered at this location is expected to be below the level of excavation, and probable undercut for subgrade stabilization. Buoyant forces,if any,on the structure are not expected to exceed the dead load when the structure is in a de-watered condition. Excavation by conventional methods and equipment is considered to be feasible at this location. 5.3 RECOMMENDATIONS Allowable bearing at the foundation level,after remedial undercut and replacement, of in excess of 2,000 psf will be available at this location,providing the bottom of the excavation is stable and not subject to disturbance by seepage forces. BLE recommends that remedial work consisting of undercut/replacement to at least 2 feet below the bottom ofthe structure be completed and the undercut volume be replaced by select granular material back to the structure subgrade elevation. The granular material may consist of either open-graded stone such as 457 or dense-graded stone such as NC DOT ABC Stone. The selection may be based on the groundwater condition at the time of construction. If groundwater is encountered in the excavation,the open-graded stone will be the preferred option. The granular material should be compacted in lifts not exceeding 12 inches using methods appropriate for the gradation. SECTION 6. NEW EFFLUENT PUMP STATION 6.1 DISCUSSION OF FINDINGS The New Effluent Pump Station will replace existing facilities for that purpose and will consist of a pre-cast, 10-foot diameter, wet well connected to two pre-cast, rectangular valve vaults by 12-inch diameter piping. The plans for the wet well show an extended mat slab (i.e. a lip) supporting the pre-cast section,presumably for buoyant resistance. The vaults are also precast and the tops of the vaults will match the top of the wet well;however,the bottom elevations are substantially higher than the bottom of the wet well. Vault bottom elevations are not shown on the plans;but BLE estimates the bottom elevations at about 2336±. The approximate elevations for the various structural elements are as shown in Table 6-1. Table 6-1 Elevations Element Elevation (site datum) Top of Wet Well (less lid) 2342.00 Effluent Piping(invert) 2336.87 Influent Piping (invert) 2334.38 Wet Well Floor 2329.17 Bottom of Structure 2328± 9of15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 Subsurface conditions at this structure were evaluated by review of soil samples from Boring B-5. Boring B- 5 encountered approximately 6 feet of fill underlain by soils BLE interprets to be of residual origin. Residual materials extend to the terminal depth of the boring at 10 feet. Based on an approximate ground surface elevation of 2343 at B-5, BLE considers the strata elevations and SPT Resistance (blows per foot) shown in Table 5-2 to be applicable to this location. Table 6-2 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2343 21<N<23 Top of Residual Soil(bottom of fill) 2337 55<N<64 Bottom of Boring 2333 - Below the stratum of fill,Boring B-5 encountered soils with a high density and strength. Additionally,Boring B-5 did not encounter large cobbles or boulders but did encounter rounded rock fragments in the fill stratum. The N-values in this stratum are considered to have been inflated by the gravel or rock fragments. Groundwater was encountered in Boring B-5 at a depth of 6 feet(approximate elevation 2337) at the time of drilling at a depth of 5.5 feet 24 hours after drilling. 6.2 ASSESSMENT Soils or weathered rock having more than sufficient strength and sufficiently low compressibility are present to the depths drilled in this boring and expected to be present even deeper. Applied stresses from the effluent pump station are expected to be less than about 1000 pounds per square foot (psf). The vault structures are expected to apply very low stresses at the foundation level and are likely to penetrate the fill soils found in Boring B-5. The shallow groundwater encountered is of concern from the standpoint of excavation wall and bottom stability for the expected 14-foot excavation. Also,buoyant forces on the structure are expected to exceed the dead load when the structure is in a de-watered condition. The plans for the station detail an extended base slab that presumably is for the purpose of resisting buoyant forces. Excavation by conventional methods and equipment is considered to be feasible at this location. That is,large rock or fragments of rock are not expected to be encountered. On the other hand the depth of excavation is substantial and groundwater issues may be substantial. Additionally,the unit is close to the existing raceways and a sloped excavation at this location is probably not feasible to avoid undermining the existing structure. The use of a braced excavation will likely be required for placement of this unit"in the dry". 6.3 RECOMMENDATIONS Allowable bearing at the foundation level,after remedial undercut and replacement, of in excess of 4,000 psf will be available at this location,providing the bottom of the excavation is stable and not subject to disturbance by seepage forces. 10 of 15 IC 1.1: Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 SECTION 7. PRODUCTION RACEWAYS 7.1 DISCUSSION OF FINDINGS BLE understands that new Production Raceways may be built to replace the existing raceways due to some damage caused by August 2021 flooding from Tropical Storm Fred. At the time of this report,that decision had not been shared with BLE. New raceways are depicted on the plans, and those, similar to the existing raceways, will be shallow, concrete, rectangular "boxes". The new raceways number eight, each, and may replace the twelve,longer,existing raceways, The approximate elevations for the various structural elements are as shown in Table 7-1. Table 7-1 Elevations Element Elevation Top of Wall(Raceway A-highest) 2355.11 Raceway Floor(Raceway A-highest) 2351.75 Bottom of Slab(Raceway A-highest) 2350± Bottom Outlet Box(Raceway B) 2347± Top of Wall (Raceway H-lowest) 2342.47 Raceway Floor(Raceway H-lowest) 2339.08 Bottom of Slab(Raceway H-lowest) 2338± Bottom Outlet Box(Raceway H) 2336± Subsurface conditions at this structure were evaluated by review of soil samples from Boring B-5,B-6,and B- 8. These boring encountered approximately 6 to 8 feet of fill underlain by soils BLE interprets to be of either alluvial or residual origin. Residual materials extend to the terminal depth of the borings at 10 to 15 feet. Based on ground surface elevations as shown in Table 7-2, BLE considers the strata elevations and SPT Resistance (blows per foot)shown in Table 7-2 to be applicable to this location. Table 7-2 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2348 to 2353 4<N<42 Top of Residual/Alluvial Soil(bottom 12<N<83 of fill) 2336 to 2346 Bottom of Boring 2327 to 2344 - Below the stratum of fill, Borings B-5, B-6, and B-8 encountered soils with a high density and strength. Additionally, these borings did not encounter large cobbles or boulders but did encounter rounded rock fragments in the fill stratum. The N-values in the fill stratum are considered to have been inflated by the gravel or rock fragments. Groundwater was encountered in these borings at depths of 6 to 8 feet at the time of drilling and at similar depths 24 hours after drilling. 11 of 15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLR Project No.J20-14503-02 7.2 ASSESSMENT Fill soils at this location at the bottom of structure depth are not considered to have sufficient strength or sufficiently low compressibility to support even the low imposed loading at this location, despite some relatively high N-values. However, soils having sufficient strength and compressibility are present slightly below the plan depth. Applied stresses from the equalization basin are expected to be less than about 550 pounds per square foot(psf). The groundwater encountered at this location is expected to be below the level of excavation and probable undercut for subgrade stabilization. Buoyant forces,if any,on the structure are not expected to exceed the dead load when the structure is in a de-watered condition. Excavation by conventional methods and equipment is considered to be feasible at this location. 7.3 RECOMMENDATIONS Allowable bearing at the foundation level,after remedial undercut and replacement, of in excess of 2,000 psf will be available at these locations, providing the bottom of the excavation is stable and not subject to disturbance by seepage forces. BLE recommends that remedial work consisting of undercut/replacement to at least 2 feet below the bottom of the structure be completed in a mass grading operation for all production raceways at one time,rather than a piece-meal approach applied to each of the 8 raceways. The undercut should be shaped such that at least 2 feet of select granular material is under the bottom of each raceway. The undercut volume should be replaced by select granular material back to the structure subgrade elevation. The granular material should consist of a dense-graded stone such as NC DOT ABC Stone. The undercut subgrade should be observed for adequate stability and proof rolled as defined in Section 10 of this report. The granular material should be compacted in lifts not exceeding 12 inches using methods appropriate for the gradation. SECTION 8. PROPOSED HATCHERY BUILDING 8.1 DISCUSSION OF FINDINGS New Rearing Tanks are planned for within the building envelope of the existing Hatchery Building. The New Rearing Tanks are shallow concrete structures with a hydraulic flow caused by a gradient between the inflow end of the structure and the outflow end of the structure. The floor of the structure slopes from the inlet end to the effluent end of the structure. Actual water surface elevations and tank elevations are not depicted on the plans; however the tanks are shown to be constructed atop the existing slab of the existing Hatchery Building and impound less than 4 feet of water. Subsurface conditions at this structure were evaluated by review of samples from Boring B-7. Boring B-7 was drilled to the specified depth(5 feet)and encountered fill throughout its depth. Groundwater was not encountered in Boring B-7 at the depth drilled. 8.2 ASSESSMENT The fill soils present at this location are soft,but variable, at the level of bottom of the existing building slab. The addition of the Rearing Tanks to the existing slab would be expected to be stable but could be expected to impact the serviceability of the existing slab. That is, the existing slab could deflect, crack, and shift in 12 of 15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 unpredictable ways. Such cracking and shifting could cause an upset in the hydraulic performance ofthe tanks. Applied stresses from the Rearing Tanks are expected to be less than about 400 pounds per square foot(psf), probably in excess of the original slab design live load. The groundwater encountered at this location is expected to be below the level of excavation, and probable undercut for subgrade stabilization. Buoyant forces,if any,on the structure are not expected to exceed the dead load when the structure is in a de-watered condition. Excavation by conventional methods and equipment,including saw-cutting of the reinforced concrete slab, is considered to be feasible at this location. 8.3 RECOMMENDATIONS BLE recommends additional detailed assessment of the structural condition of the slab. If the slab condition is questionable in any way and if the hydraulic performance of the new tanks is in question, BLE recommends removal of a section of the existing slab by saw cutting the slab and undercutting and replacement of the soft fill immediately beneath the slab. The depth of undercut should be established by inspection at the time of construction. BLE, on the basis of Boring B-7, opines that a 2-foot undercut and replacement would yield a bearing value of at least 2,000 psf. BLE further recommends that the undercut volume be replaced by select granular material back to the structure subgrade elevation. The granular material may consist of either open- graded stone such as 457 or dense-graded stone such as NC DOT ABC Stone. The selection may be based on the groundwater condition at the time of construction. If groundwater is encountered in the excavation,the open-graded stone will be the preferred option. The granular material should be compacted in lifts not exceeding 12 inches using methods appropriate for the gradation. SECTION 9. FUTURE DEVELOPMENT 9.1 DISCUSSION OF FINDINGS The area designated for Potential Future Development is located in an existing parking area to the east of the other developments and east of the existing access bridge. Types of structures planned are unknown to BLE; however,the conditions encountered in Borings B-8 and B-9 are not appreciably different than those in other areas ofthe site. Strata elevations as interpreted by BLE from the borings are shown in Table 9-1. Groundwater was encountered in this area at a depth of about 6 to 7 feet below the ground surface. Table 9-1 Strata Elevations Stratum Elevation (approx.) SPT Resistance(bpf) Ground Surface (top of fill) 2337 to 2342 26<N<42 Top of Residual/Alluvial Soil(bottom 12<N<48 of fill) 2331 to 2336 Bottom of Boring 2327(both) - 13 of 15 IC Im 11 Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLE Project No.J20-14503-02 9.2 ASSESSMENT The fill soils present at this location are loose and their condition is not reflected by the high SPT N-values. Those values are considered to be inflated by the presence of gravels and cobbles in both the fill and alluvial strata. BLE would expect that most foundations related to the future development would be required to penetrate the fill and bear in either firm to dense alluvium or undisturbed residual materials. Potential bearing capacity in these strata would exceed 3500 psf for lightly-loaded structures. The groundwater encountered at these locations is expected to be below the level of excavation, and probable undercut for most-likely subgrade stabilization measures. Excavation by conventional methods and equipment is considered to be feasible at this location. 9.3 RECOMMENDATIONS BLE recommends additional detailed assessment in this area based on final development plans. As noted in the preceding paragraph,reasonably high strength materials are present at expected foundation levels. SECTION 10.0 CONSTRUCTION CONSIDERATIONS 10.1 STRUCTURAL FILL Soil used for backfilling under and around the proposed structures or for raising site grades should be a low plasticity sandy silt or silty sand material that is uniformly compacted in thin lifts to at least 95 percent of the standard Proctor maximum dry density(ASTM D698). The soil to be used in the structural fill should contain no more than 3 percent organic matter by weight and should be free of roots,limbs,other deleterious material and rocks larger than 3 inches in diameter. The moisture content of the compacted new soil fill should be maintained within plus or minus 3 percent of the optimum moisture content as determined from the standard Proctor compaction test during placement and compaction. This provision may require the contractor to dry soils during periods of wet weather or to wet soils during dry periods. Material should be evaluated as it is excavated to determine if suitable for reuse. Before filling operations begin,representative samples of each proposed fill material should be collected and tested to determine the compaction and classification characteristics. The maximum dry density and optimum moisture content should be determined. Once compaction begins, a sufficient number of field density tests should be performed by an experienced engineering technician working under the direction of the BLE geotechnical engineer to measure and document the degree of compaction being obtained. The surface of compacted subgrade soil can deteriorate and lose its support capabilities when exposed to environmental changes and construction activity. Deterioration can occur in the form of freezing, formation of erosion gullies, extreme drying, and exposure for a long period of time or rutting by construction traffic. We recommend that the surfaces of all structure subgrades that have deteriorated or softened be recompacted prior to construction of the structure. Additionally,any excavations through the subgrade soils(such as utility trenches) should be properly backfilled in compacted lifts. Recompaction of subgrade surfaces and compaction of backfill should be checked with a sufficient number of density tests to determine and document that adequate compaction is being achieved. 14 of 15 IC 1.1: Report of'Geotechnical Evaluation December 8, 2021 Setzer Fish Hatchery Renovation—Pisgah Forest,NC BLR Project No.J20-14503-02 The recommendations herein require the use of select granular materials in some undercut/replacement situations. Two gradations are acceptable: First, open graded stone is recommended where the undercut subgrade appears to be experiencing disturbance by seepage forces. Second, a dense graded stone is recommended where dry stable undercut subgrade is present. The open-graded stone should be consistent with 457 stone, while the dense-graded stone should conform to NCDOT Aggregate Base Course (ABC) stone. Select granular material should be compacted to 98 percent of the material's standard Proctor density (ASTM D698). Compaction should be done by methods suitable for the respective gradations. Wherever an open-graded stone is employed adjacent to a fine-grained material, a geosynthetic having appropriate separation properties should be specified. 10.2 SUBGRADE ACCEPTANCE All subgrades that will be subjected to structural loading or which have been undercut for removal of existing fill or deleterious materials should be observed and approved by the Geotechnical Engineer of Record. The acceptance may include probing/testing by mechanical means or, for large areas, by proof rolling using heavily loaded,pneumatic-tired vehicles. 10.3 DIFFICULT EXCAVATION As noted in an earlier paragraph, BLE anticipated that,given the setting of this site,many layers of boulder- laden materials may be encountered. The current configuration of the site suggests that some reorientation of the Davidson River may have occurred leaving original channel ways buried under fill strata. The widely spaced borings made for this exploration did not encounter such materials. Nevertheless,there remains a fair probability that such buried channels and other zones of cobbles and boulders may be encountered in the subsurface during structural excavation. Based on off-site observations such zones will be excavatable by heavy-duty excavator, but problems could arise with pipe-line excavations in maintaining the walls and bottoms of trenches where these zones are encountered. 10.4 GROUNDWATER CONTROL All of the borings encountered groundwater, some within the expected construction depths of the various developments. Excavation for deeper structures or possible deep undercutting operations could encounter groundwater. Excavations could also encounter perched groundwater within the existing fill/residual materials above the general ground water level. None of the materials(fill,alluvium,residuum)encountered by the borings will readily lend themselves to dewatering by conventional (pumped well-points, or similar) methods,but will require pumping from open excavations and stabilization of the walls and bottoms of such excavations by external means. Specifically, both of the Grit Chambers that are a part of these renovations will likely require braced excavations with internal pumping to place the planned units. Additionally, some of the precast units such as the Pump Station at the Effluent Waste Treatment area may require bracing and dewatering or, at least, some specialized techniques to emplace the units "in-the-wet" with dewatering subsequent to emplacement. Other than these three components of the renovation other structural areas all appear to be above the groundwater level with the possible exception of the pipe lines which run throughout the site. Again, groundwater control issues may vary depending on location and may require trench reinforcement and placement of sumps. 15 of 15 APPENDIX Legend • Sonic Drill w/ SIPT Locations Ron 4 83K 3 AUAftCDjuArE I00•EAR FLt)ODPL &ME Imcm—s.(�.Irlj FEEDPROPOSED UM LWL VR ---------- -STNC SrNU 1E'C,F YOM-L14E BWE 5 pmmam rTwEu C%MVIC UeIVSDN IHTIIE YASTE TRE06TWO04T -hc. DEPTH. rW --- �D '14 LEL TAW: -OW 0 015PNG OESE�_? FRMP30 WDW�TZN FMCM 4� d WTV I HOPIEFT ENOUAM Mitt 3 Emsbw -C t�� '��tKL ruTm mnww "�,THO"E�E" 1AA STI WN icr -A NQW-EULL41IC— y F�ING L-r TP4 5-10 F!�'E� -77.77 .. 4. r, 113rA&E ';w Q 05TIrtQ YALU-Fr MUCAMN CENTER OWINC r-AME STT4Dt SULON NC� C, E-isvqr.RESDE4CE VIYOK04ESOLURC E-iL nrti WRAW 97QRAGF L V5. 7. is-r*TED FELT q.. e JF I I r'J k J X m Z: f B'RE FRUQ K CRT 31& EEPT14! EXISTIK GZDCIW Wr? Base Map by McGill Associates, P.A. Boring Locations by BLE ,� ' m SUN NELL Drawn By- JJB Bobby N. Setzer State Fish Hatchery m LAMMONS Figure No. m ENGINIEERINEI Pisgah National Forest, NC Boring Location Plan hM4 Pnffde�Emn I llmmm'Ep SC 2q5Z Date: 8EA�10.rE�5 0 9542RA ATM V .,I,r:!,. BLE Project No. J20-14503-02 02-1 BLECOR?.CUM 11/18/2020 � LAMMQNS ENGINEERING Field Exploration Procedures (Sonic Drilling) At this site, borings were advanced using the Sonic drilling technique. Sonic Drilling is an advanced form of drilling which employs high-frequency resonant energy generated inside a "sonic head" to advance the drilling tools through a wide variety of subsurface formations and conditions. During the drilling,the resonant energy is transferred down the drill string to the bit face, where penetration of the formation is effected. The drill operator controls the vibratory frequency to optimize the penetration for the formation condition. The drill string used at this site and for a wide variety of geotechnical drilling applications consists of a 4-inch diameter core barrel within a 6-inch diameter outer casing (i.e. a 4x6 drill string). Soil sampling and standard penetration testing (SPT) were performed through the drill string in general accordance with ASTM D 1586. At assigned intervals, soil samples were obtained with a standard 1.4-inch L D., 2- inch O. D., split-tube sampler. The sampler was first seated 6 inches to penetrate any loose cuttings, and then driven an additional 12 inches with blows of a 140-pound hammer falling 30 inches. For this project a fully automatic hammer(Auto-Hammer)was used. The number of hammer blows required to drive the sampler the final 12 inches was recorded and is designated the"standard penetration resistance"(SPT). The penetration resistance,when properly evaluated, is an index to the strength of the soil and foundation supporting capability. Representative portions of the soil samples,thus obtained,were placed in glass jars and transported to the laboratory.In the laboratory,the samples were examined by a geotechnical engineer to verify the field classifications of the driller. Boring Logs are attached, showing the soil descriptions and penetration resistance. KEY TO SOIL CLASSIFICATIONS AND CONSISTENCY DESCRIPTIONS BUNNELL-LAMMONS ENGINEERING, INC. GREENVILLE, SOUTH CAROLINA Penetration Resistance* Relative Blows per Foot Density Particle Size Identification SANDS Boulder: Greater than 300 mm Cobble: 75 to 300 mm 0 to 4 Very Loose Gravel: 5 to 10 Loose Coarse-19 to 75 mm 11 to 20 Firm Fine-4.75 to 19 mm 21 to 30 Very Firm Sand: 31 to 50 Dense Coarse-2 to 4.75 mm over 50 Very Dense Medium-0.425 to 2 mm Fine-0.075 to 0.425 mm Silt&Clay:Less than 0.075 mm Penetration Resistance* Consistency Blows per Foot SILTS and CLAYS 0 to 2 Very Soft 3 to 4 Soft 5 to 8 Firm 9 to 15 Stiff 16 to 30 Very Stiff 31 to 50 Hard over 50 Very Hard *ASTM D 1586 KEY TO DRILLING SYMBOLS ® Grab Sample NR=No reaction to HCL Groundwater Table at Time of Drilling ® Split Spoon Sample NA=Not applicable NS=No sample . Undisturbed Sample Groundwater Table 24 Hours after Completion of Drilling KEY TO SOIL CLASSIFICATIONS '�•• Well-graded Gravel Low Plasticity Clayfig Clayey Silt Silty Sand GW CL MH SM Poorly-graded Gravel Sandy Clay Sandy Silt �' •`-'% Topsoil Q ° GP CLS MLS TOPSOIL Partially Weathered Rock Silty Clay Sand Liquid Sludge BLDRCBBL CL-ML SW SLUDGE High Plasticity Clay Silt Clayey Sand Fill CH ML Sc FILL 777-1 . . . . . Poorly Graded Sand Bedrock Waste SP BEDROCK ' ' WOOD -Lee . • .01 ,ILMINC. SOIL BORING NO. B-1 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2367 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 5.3 AFTER 24 HOURS:1 CAVING>777 12 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT 2 5 10 20 30 40 50 70 90 Firm, brown,damp,silty fine to medium SAND(SM)with gravel-(fill) 4 6 2365 • 6 Very dense,and dense, red,tan,silty fine to medium SAND(SM)with 30 rock fragments 27 5 Blowcounts amplified by presence of rock fragments. 2360 17 20 27 Very dense,gray,tan,damp,slightly micaceous,silty fine to medium 28 25 SAND(SM)-(residuum) 41 10 2355 25 :5016 33 15 Partially Weathered Rock which sampled as moist,gray,tan,slightly 50/6 micaceous,silty fine to medium sand 2350 3 6 • 20 10 2345 Firm and very dense,wet,grayish tan, micaceous,silty fine to medium 19 SAND(SM) 2� 25 Boring terminated at 25 feet. Groundwater encountered at 5.3 feet at time of boring. 2340 Boring caved at 12 feet at end of day. 30 2335 a 35 a c� N 2330 0 J J .... ....... W O SOIL BORING NO. B-1 LU Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-2 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2379 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 4 AFTER 24 HOURS:1 CAVING>777 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT y 2 5 10 20 30 40 50 70 90 Very loose to loose,damp,tan, brown,silty fine to medium SAND(SM) with rounded rock fragments-(fill) 6 1 1 2375 5 6 5 4 . Very firm,damp,gray,tan,slightly micaceous,silty fine to medium 13 20 SAND(SM)-(residuum) 13 soiz 2370 Partially Weathered Rock which sampled as damp to moist,gray,white, 50/2 silty fine to medium sand 10 Boring terminated at 12.5 feet. solo 2365 Groundwater encountered at 4 feet at time of boring. 50/0 15 2360 20 2355 25 2350 30 2345 N a 35 a c� N O J w 2340 0 0 I SOIL BORING NO. B-2 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-3 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2355 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 7 AFTER 24 HOURS:1 6 CAVING>777 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT y 2 5 10 20 30 40 50 70 90 Very loose to very firm,damp,tan, brown,silty fine to medium SAND (SM)-(fill) 2 2 4 5 6 2350 5 4 12 14 16 Dense,wet,dark brownish gray,slightly micaceous,silty fine to coarse 20 19 SAND(SM)with rounded rock fragments-(alluvium) 16 • 2345 10 Loose,wet, red,light brown,silty fine to coarse SAND(SM)-(residuum) 11 Piezometer Installed to bottom of hole. 3 • 2340 15 4 4 2335 20 6 • Boring terminated at 20 feet. Groundwater encountered at 7 feet at time of boring. Groundwater encountered at 6 feet 24 hours after drilling. 2330 25 2325 30 a 2320 35 a c� N O J W 0 O SOIL BORING NO. B-3 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-4 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2357 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 5.4 AFTER 24 HOURS:1 CAVING>777 7 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT 2 5 10 20 30 40 50 70 90 Very firm, moist,reddish tan,silty fine to medium SAND(SM)with rounded gravel fragments-(fill) 12 2355 23 i 25 22 23 5 21 5016 2350 Very dense,grayish brown,silty fine to medium SAND(SM)with X 50/6 rounded rock fragments-(alluvium) Very dense,wet,tan,gray,silty fine to medium SAND(SM)with rock 28 sors fragments-(residuum) 50/5 10 Boring terminated at 10 feet. Groundwater encountered at 5.4 feet at time of drilling. 2345 Boring caved at 7 feet at end of day. 15 2340 20 2335 25 2330 30 2325 a 35 a c� N 2320 0 J W 0 O SOIL BORING NO. B-4 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-5 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2343 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 6 AFTER 24 HOURS:1 5.5 CAVING>777 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT 2 5 10 20 30 40 50 70 90 Very firm, moist,tan,gray,fine to coarse SAND(SM)with rounded rock- ( ) 11 12 11 2340 8 9 5 12 Dense to very dense, moist,tannish gray,silty fine to medium SAND 10 19 (SM)with scattered rock fragments-(residuum) 45 2335 Piezometer Installed to bottom of hole. 16 18 10 37 Boring terminated at 10 feet. Groundwater encountered at 6 feet at time of boring. Groundwater measured at 5.5 feet 24 hours after drilling. 2330 15 2325 20 2320 25 2315 30 2310 a 35 a c� N O 2305 J J .... ....... W 0 O SOIL BORING NO. B-5 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-6 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2354 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 8 AFTER 24 HOURS:1 CAVING>777 8.6 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT 2 5 10 20 30 40 50 70 90 2 inches ASPHALT 6 inches CRUSHED STONE 2 ................... ..:....:....:...:...:. Very loose and loose,damp,tan, brown,silty fine to medium SAND(SM) 2 • 2 2350 2 2 5 s • 17 17 Dense,tannish brown,silty fine to medium SAND(SM)with rounded rock fragments 28 • e dense moist grayish brown silty fine to medium SAND SM with37 25 2345 rY ,g Y tY ( ) rock fragments-(residuum) as 10 Boring terminated at 10 feet. Groundwater encountered at 5 feet at time of boring. Boring caved at 8.6 feet 24 hours after drilling. 2340 15 2335 20 2330 25 2325 30 2320 N a 35 a c� N O J w 2315 0 0 I SOIL BORING NO. B-6 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-7 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2353 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD:Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: AFTER 24 HOURS:1 CAVING>777 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT y 2 5 10 20 30 40 50 70 90 Loose to very dense,damp,tan, brown,silty fine to medium SAND(SM) -(fill) 1 :...:...:. ..:....:....:...:...:..:...:.. 1 1 2350 13 soil Rock Fragments 18 5 50/1 Boring terminated at 5 feet. No groundwater encountered at time of boring. 2345 10 2340 15 2335 20 2330 25 2325 30 2320 a 35 a c� N O 2315 J J .... ....... W 0 O SOIL BORING NO. B-7 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-8 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2342 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS DEPTH TO-WATER> INITIAL: 6 AFTER 24 HOURS:1 7 CAVING>777 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT 2 5 10 20 30 40 50 70 90 2.5 inches ASPHALT 6 inches GRAVEL 10 .....:...:....:....:...:. ..:....:....:...:.. 2340 Very firm,damp,dark brown,silty,fine to medium SAND(SM)with 14 • gravel fragments-(fill) 11 Dense,damp,gray brown,silty fine to medium SAND(SM)with rock 12 fragments 3 5 2335 14 15 17 Dense,wet, brown,gray,slightly micaceous,fine to coarse SAND(SM) 18 17 with rounded rock fragments-(alluvium) 31 10 2330 Firm, moist,light tan,silty fine to medium SAND(SM)-(residuum) 3 Piezometer installed to bottom of hole. 7 RX 15 Boring terminated at 15 feet. Groundwater encountered at 6 feet at time of boring. 2325 Groundwater measured at 7 feet 24 hours after drilling. 20 2320 25 2315 30 2310 a 35 a c� N 2305 0 J W 0 O SOIL BORING NO. B-8 Sheet 1 of 1 ,ILMINC. SOIL BORING NO. B-9 PROJECT: Setzer Fish Hatchery PROJECT NO.: J21-14503-02 BUNNELL-LAMMONS CLIENT: McGill Associates,P.A. START:10/25/21 END:10125121 ENGINEERING,INC. LOCATION: Pisgah Forest,North Carolina ELEVATION: 2337 GEOTECHNICALANDENVlRONMENTAL DRILLER: GEOLOGIC EXPLORATION,Kenny LOGGED BY: S.Interlicchia CONSULTANTS DRILLING METHOD: Geoprobe 8150 LS, DEPTH TO-WATER> INITIAL: 7 AFTER 24 HOURS:1 6 CAVING>777 U) w ELEVATION/ SOIL DESCRIPTION SOIL a STANDARD PENETRATION RESULTS DEPTH(FT) TYPE a BLOWS/FOOT 2 5 10 20 30 40 50 70 90 2 inches ASPHALTir 5 inches STONE 10 .....:...:....:....:...:. ..:....:....:...:...:..:...:.. 2335 Very firm to dense,moist,tan brown,silty fine to medium SAND(SM) 10 • with gravel-(fill) 16 13 :5015 50/5 5 2330 Grayish brown,wet,slightly micaceous,fine to coarse SAND(SM)with 22 rounded rock fragments-(alluvium) 25 • 20 Tannish light gray, moist,silty fine to medium SAND(SM)with rock 21 • 13 10 fragments-(possible residuum) Piezometer installed to bottom of hole. onng termina e at I U Teet. 2325 Groundwater encountered at 7 feet at time of boring. Groundwater measured at 6 feet 24 hours after drilling. 15 2320 20 2315 25 2310 30 2305 a 35 a c� N 2300 0 J J .... ....... W 0 O SOIL BORING NO. B-9 LU Sheet 1 of 1 Appendix K - Special Use Permit USDA United States Forest National Forests in North Carolina 1600 Pisgah Highway Department of Service Pisgah Ranger District Pisgah Forest,NC 28768 - Agriculture 828-877-3265 Fax: 828-884-7527 File Code: 2720 Date: NC Wildlife Resources Commission 512 N. Salisbury Street Raleigh NC 27604 Dear Mr. Kleinmaier, Enclosed is a fully executed reissuance of your Special Use Permit,NCS06, for geotechnical boring within the Setzer Fish Hatchery permit area. Thank you for returning the signed permit to us in a timely fashion. Your new permit will expire 12/31/2021. Please reach out to Forest Service archaeologists at least two weeks prior to the boring, as their presence will be required to ensure no cultural resources are disturbed. If you have any questions regarding this permit, please contact John Thompson, Special Uses Program Manager at 828-302-1687 or john.thompsonkusda.gov. Sincerely, a000s "8 moDAVID CASEYe2219; 2o DAVID CASEY District Ranger ENCLOSURE: Permit U�S Caring for the Land and Serving People Printed on Recycled Paper Authorization ID: NCS06 FS-2700-4(VER. 03/17) Contact Name: N.C.WILDLIFE RESOURCES COMM. OMB 0596-0082 Expiration Date: 12/31/2021 Use Code:561 U.S. DEPARTMENT OF AGRICULTURE FOREST SERVICE SPECIAL USE PERMIT Authority: ORGANIC ADMINISTRATION ACT June 4, 1897 N.C. WILDLIFE RESOURCES COMM. of INLAND FISHERIES DIVISION 512 N. SALISBURY STREET RALEIGH NC UNITED STATES 27604 (hereinafter"the holder") is authorized to use or occupy National Forest System lands in the NATIONAL FORESTS IN NORTH CAROLINA or Pisgah Ranger District of the National Forest System, subject to the terms and conditions of this special use permit(the permit). This permit covers 7 locations, ("the permit area"), as shown on the map attached as Appendix A. This and any other appendices to this permit are hereby incorporated into this permit. This permit issued for the purpose of: Geo-boring at the Setzer Fish Hatchery. Boring is approved in 7 locations utilizing a truck mounted drill rig.This project is related to the Setzer Fish Hatchery Renovation Project(PIS105302). Exhibit A: Map Exhibit B: Design Features TERMS AND CONDITIONS L GENERAL TERMS A.AUTHORITY.This permit is issued pursuant to the ORGANIC ADMINISTRATION ACT June 4, 1897 and 36 CFR Part 251, Subpart B, as amended, and is subject to their provisions. B.AUTHORIZED OFFICER.The authorized officer is the Forest or Grassland Supervisor or a subordinate officer with delegated authority. C. TERM.This permit shall expire at midnight on 12/31/2021, 3 months from the date of issuance. D. CONTINUATION OF USE AND OCCUPANCY.This permit is not renewable. Prior to expiration of this permit, the holder may apply for a new permit for the use and occupancy authorized by this permit.Applications for a new permit must be submitted at least 6 months prior to expiration of this permit. Issuance of a new permit is at the sole discretion of the authorized officer.At a minimum, before issuing a new permit, the authorized officer shall ensure that(1)the use and occupancy to be authorized by the new permit is consistent with the standards and guidelines in the applicable land management plan; (2)the type of use and occupancy to be authorized by the new permit is the same as the type of use and occupancy authorized by this permit; and (3)the holder is in compliance with all the terms of this permit. The authorized officer may prescribe new terms and conditions when a new permit is issued. E.AMENDMENT.This permit may be amended in whole or in part by the Forest Service when, at the discretion of the authorized officer, such action is deemed necessary or desirable to incorporate new terms that may be required by law, regulation, directive, the applicable forest land and resource management plan, or projects and activities implementing a land management plan pursuant to 36 CFR Part 215. F. COMPLIANCE WITH LAWS, REGULATIONS,AND OTHER LEGAL REQUIREMENTS. In exercising the rights and privileges granted by this permit, the holder shall comply with all present and future federal laws and regulations and all present and future state, county, and municipal laws, regulations, and other legal requirements that apply to the permit area, to the extent they do not conflict with federal law, regulation, or policy. The Forest Service assumes no responsibility for enforcing laws, regulations, and other legal requirements that fall under the jurisdiction of other governmental entities. G. NON-EXCLUSIVE USE.The use or occupancy authorized by this permit is not exclusive. The Forest Service reserves the right of access to the permit area, including a continuing right of physical entry to the permit area for inspection, monitoring, or any other purpose consistent with any right or obligation of the United States under any law or regulation. The Forest Service reserves the right to allow others to use the permit area in any way that is not inconsistent with the holder's rights and privileges under this permit, after consultation with all parties involved. Except for any restrictions that the holder and the authorized officer agree are necessary to protect the installation and operation of authorized temporary improvements, the lands and waters covered by this permit shall remain open to the public for all lawful purposes. H.ASSIGNABILITY.This permit is not assignable or transferable. II.IMPROVEMENTS A. LIMITATIONS ON USE. Nothing in this permit gives or implies permission to build or maintain any structure or facility or to conduct any activity, unless specifically authorized by this permit.Any use not specifically authorized by this permit must be proposed in accordance with 36 CFR 251.54.Approval of such a proposal through issuance of a new permit or permit amendment is at the sole discretion of the authorized officer. B. PLANS.All plans for development, layout, construction, reconstruction, or alteration of improvements in the permit area, as well as revisions to those plans must be prepared by a professional engineer, architect, landscape architect, or other qualified professional based on federal employment standards acceptable to the authorized officer. These plans and plan revisions must have written approval from the authorized officer before they are implemented. The authorized officer may require the holder to furnish as-built plans, maps, or surveys upon completion of the work. C. CONSTRUCTION.Any construction authorized by this permit shall commence by NA and shall be completed by NA. III. OPERATIONS. A. PERIOD OF USE. Use or occupancy of the permit area shall be exercised at least 1 day each year. B. CONDITION OF OPERATIONS.The holder shall maintain the authorized improvements and permit area to standards of repair, orderliness, neatness, sanitation, and safety acceptable to the authorized officer and consistent with other provisions of this permit. Standards are subject to periodic change by the authorized officer when deemed necessary to meet statutory, regulatory, or policy requirements or to protect national forest resources. The holder shall comply with inspection requirements deemed appropriate by the authorized officer. C. MONITORING BY THE FOREST SERVICE. The Forest Service shall monitor the holder's operations and reserves the right to inspect the permit area and transmission facilities at any time for compliance with the terms of this permit. The holder shall comply with inspection requirements deemed appropriate by the authorized officer. The holder's obligations under this permit are not contingent upon any duty of the Forest Service to inspect the permit area or transmission facilities.A failure by the Forest Service or other governmental officials to inspect is not a justification for noncompliance with any of the terms and conditions of this permit. IV. RIGHTS AND LIABILITIES A. LEGAL EFFECT OF THE PERMIT. This permit,which is revocable and terminable, is not a contract or a lease, but rather a federal license. The benefits and requirements conferred by this authorization are reviewable solely under the procedures set forth in 36 CFR 214 and 5 U.S.C. 704. This permit does not constitute a contract for purposes of the Contract Disputes Act, 41 U.S.C. 601. The permit is not real property, does not convey any interest in real property, and may not be used as collateral for a loan. B.VALID EXISTING RIGHTS. This permit is subject to all valid existing rights. Valid existing rights include those derived under mining and mineral leasing laws of the United States. The United States is not liable to the holder for the exercise of any such right. C.ABSENCE OF THIRD-PARTY BENEFICIARY RIGHTS. The parties to this permit do not intend to confer any rights on any third party as a beneficiary under this permit. D.SERVICES NOT PROVIDED. This permit does not provide for the furnishing of road or trail maintenance,water, fire protection, search and rescue, or any other such service by a government agency, utility, association, or individual. E. RISK OF LOSS. The holder assumes all risk of loss associated with use or occupancy of the permit area, including but not limited to theft, vandalism, fire and any fire-fighting activities (including prescribed burns), avalanches, rising waters, winds, falling limbs or trees, and other forces of nature. If authorized temporary improvements in the permit area are destroyed or substantially damaged, the authorized officer shall conduct an analysis to determine whether the improvements can be safely occupied in the future and whether rebuilding should be allowed. If rebuilding is not allowed, the permit shall terminate. F. _DARAIAGE TO UNITE-D STATES PROPERTY. The held-er has an affirmative d6ity te preteGt fF9M damage the Iand, preperty, andd A-their intereests ef the United States. Damage inr.1--id-es but is net lornited- te fore suppressi9R Gests and damage +e n nt a erd i n+s a rend by this permit. erfermanse bGRGI r rerd i nrder clause IV-..I GXGGnt that liability shall net insli irJe r ahle and errd inan Wear nrd tear affeeted by the ;-;Rd- awtheFized by this peFfflit. The helde.r shall pFemptly abate as Gempletely as pessible existiRg GF GGG61FFiRg OR GGRReGtien w0th thp ;;Oherized -se and GGG6ipaRGY d61FiRg the term ef this permit that .,h;;" Ar SAAR aG PFaGtiGabIG RGtify the a6ithArized AffiAer Af all reriA,- ;;AAidepts that AAA,ir AAPPPAtiAA with there H FIN11MIROIN I1ACA1TA1 DR/'1TC!`TV'lhl as trees, shrubs, and grass), surfaGe water, and gF96IRdwater, d61FiRg the held_e.r's uwse and GGG61paRGY ef the permit area. to the sa+isfaetien of the ai itherizerd r.ffiner anrd at n e to the United States vAmth thp ;;--th ;;Ad GGG61paRGY GF a#erthe term Gfthis permit that Aa—es Arthreatens tA Aae harm tA rFee--sseHFeees.. agaiRSt the 1JRited States; (3)GGStS, eXpeRseS, and damages ORGUrred by the URited States; er(4)the release eir thrp;;tpnpd release ef aRY SOlid waste, hazardews waste, hazardells materials, pellutaRt GORtaMiRaRt, 901 OR aRY fOFM, GF MGRGtaFy iRdGMPifino+inn J. BONDING. The authorized officer may require the holder to furnish a surety bond or other security for any of the obligations imposed by the terms and conditions of this permit or any applicable law, regulation, or order. PFiGF tG Gf thiG PGFMit and GaGh YP;-;p thereafter that this permit On effi;At The Ferest SepziAe. The held-e-F shall send an awthentirate. J ebtaiRed by the helder pursuant te this r-lause-shall narne the United States as an a3d_d_.t_.9RaI ORS61red, and the 0 RS61Fed PF9ViSiGR shall previdpe fA-.r Ons;,_,1ra;nr_--e G9Verage fer the United States as req610red und-p-r this A-.nd- to the exteRt V. RESOURCE PROTECTION A. COMPLIANCE WITH ENVIRONMENTAL LAWS. The holder shall in connection with the use or occupancy authorized by this permit comply with all applicable federal, state, and local environmental laws and regulations, including but not limited to those established pursuant to the Resource Conservation and Recovery Act, as amended, 42 U.S.C. 6901 et seq., the Federal Water Pollution Control Act, as amended, 33 U.S.C. 1251 et seq., the Oil Pollution Act, as amended, 33 U.S.C. 2701 et seq., the Clean Air Act, as amended, 42 U.S.C. 7401 et seq., CERCLA, as amended, 42 U.S.C. 9601 et seq., the Toxic Substances Control Act, as amended, 15 U.S.C. 2601 et seq., the Federal Insecticide, Fungicide, and Rodenticide Act, as amended, 7 U.S.C. 136 et seq., and the Safe Drinking Water Act, as amended, 42 U.S.C. 300f et seq. B.VANDALISM. The holder shall take reasonable measures to prevent and discourage vandalism and disorderly conduct and when necessary shall contact the appropriate law enforcement officer. C. PESTICIDE USE. 1.Authorized Officer Concurrence. Pesticides may not be used outside of buildings in the permit area to control pests, including undesirable woody and herbaceous vegetation (including aquatic plants), insects, birds, rodents, or fish without prior written concurrence of the authorized officer. Only those products registered or otherwise authorized by the U.S. Environmental Protection Agency and appropriate State authority for the specific purpose planned shall be authorized for use within areas on National Forest System lands. 2. Pesticide-Use Proposal. Requests for concurrence of any planned uses of pesticides shall be provided in advance using the Pesticide-Use Proposal (form FS-2100-2).Annually the holder shall, on the due date established by the authorized officer, submit requests for any new, or continued, pesticide usage. The Pesticide-Use Proposal shall cover a 12-month period of planned use. The Pesticide-Use Proposal shall be submitted at least 60 days in advance of pesticide application. Information essential for review shall be provided in the form specified. Exceptions to this schedule may be allowed, subject to emergency request and approval, only when unexpected outbreaks of pests require control measures which were not anticipated at the time a Pesticide-Use Proposal was submitted. 3. Labeling, Laws, and Regulations. Label instructions and all applicable laws and regulations shall be strictly followed in the application of pesticides and disposal of excess materials and containers. No pesticide waste, excess materials, or containers shall be disposed of in any area administered by the Forest Service. D.ARCHAEOLOGICAL-PALEONTOLOGICAL DISCOVERIES. The holder shall immediately notify the authorized officer of all antiquities or other objects of historic or scientific interest, including but not limited to historic or prehistoric ruins, fossils, or artifacts discovered in connection with the use and occupancy authorized by this permit. The holder shall follow the applicable inadvertent discovery protocols for the undertaking provided in an agreement executed pursuant to section 106 of the National Historic Preservation Act, 54 U.S.C. 306108; if there are no such agreed-upon protocols, the holder shall leave these discoveries intact and in place until consultation has occurred, as informed, if applicable, by any programmatic agreement with tribes. Protective and mitigation measures developed under this clause shall be the responsibility of the holder. However, the holder shall give the authorized officer written notice before implementing these measures and shall coordinate with the authorized officer for proximate and contextual discoveries extending beyond the permit area. E. NATIVE AMERICAN GRAVES PROTECTION AND REPATRIATION ACT(NAGPRA). In accordance with 25 U.S.C. 3002(d)and 43 CFR 10.4, if the holder inadvertently discovers human remains, funerary objects, sacred objects, or objects of cultural patrimony on National Forest System lands, the holder shall immediately cease work in the area of the discovery and shall make a reasonable effort to protect and secure the items. The holder shall follow the applicable NAGPRA protocols for the undertaking provided in the NAGPRA plan of action or the NAGPRA comprehensive agreement; if there are no such agreed-upon protocols, the holder shall as soon as practicable notify the authorized officer of the discovery and shall follow up with written confirmation of the discovery. The activity that resulted in the inadvertent discovery may not resume until 30 days after the forest archaeologist certifies receipt of the written confirmation, if resumption of the activity is otherwise lawful, or at any time if a binding written agreement has been executed between the Forest Service and the affiliated Indian tribes that adopts a recovery plan for the human remains and objects. F. PROTECTION OF THREATENED AND ENDANGERED SPECIES,SENSITIVE SPECIES,AND SPECIES OF CONSERVATION CONCERN AND THEIR HABITAT. 1. Threatened and Endangered Species and Their Habitat. The location of sites within the permit area needing special measures for protection of plants or animals listed as threatened or endangered under the Endangered Species Act (ESA) of 1973, 16 U.S.C. 1531 et seq., as amended, or within designated critical habitat shall be shown on a map in an appendix to this permit and may be shown on the ground. The holder shall take any protective and mitigation measures specified by the authorized officer as necessary and appropriate to avoid or reduce effects on listed species or designated critical habitat affected by the authorized use and occupancy. Discovery by the holder or the Forest Service of other sites within the permit area containing threatened or endangered species or designated critical habitat not shown on the map in the appendix shall be promptly reported to the other party and shall be added to the map. 2. Sensitive Species and Species of Conservation Concern and Their Habitat. The location of sites within the permit area needing special measures for protection of plants or animals designated by the Regional Forester as sensitive species or as species of conservation concern pursuant to FSM 2670 shall be shown on a map in an appendix to this permit and may be shown on the ground. The holder shall take any protective and mitigation measures specified by the authorized officer as necessary and appropriate to avoid or reduce effects on sensitive species or species of conservation concern or their habitat affected by the authorized use and occupancy. Discovery by the holder or the Forest Service of other sites within the permit area containing sensitive species or species of conservation concern or their habitat not shown on the map in the appendix shall be promptly reported to the other party and shall be added to the map. G. CONSENT TO STORE HAZARDOUS MATERIALS. The holder shall not store any hazardous materials at the site without prior written approval from the authorized officer. This approval shall not be unreasonably withheld. If the authorized officer provides approval, this permit shall include, or in the case of approval provided after this permit is issued, shall be amended to include specific terms addressing the storage of hazardous materials, including the specific type of materials to be stored, the volume, the type of storage, and a spill plan. Such terms shall be proposed by the holder and are subject to approval by the authorized officer. H. CLEANUP AND REMEDIATION. 1. The holder shall immediately notify all appropriate response authorities, including the National Response Center and the authorized officer or the authorized officer's designated representative, of any oil discharge or of the release of a hazardous material in the permit area in an amount greater than or equal to its reportable quantity, in accordance with 33 CFR Part 153, Subpart B, and 40 CFR Part 302. For the purposes of this requirement, "oil" is as defined by section 311(a)(1)of the Clean Water Act, 33 U.S.C. 1321(a)(1). The holder shall immediately notify the authorized officer or the authorized officer's designated representative of any release or threatened release of any hazardous material in or near the permit area which may be harmful to public health or welfare or which may adversely affect natural resources on federal lands. 2. Except with respect to any federally permitted release as that term is defined under Section 101(10)of CERCLA, 42 U.S.C. 9601(10), the holder shall clean up or otherwise remediate any release, threat of release, or discharge of hazardous materials that occurs either in the permit area or in connection with the holder's activities in the permit area, regardless of whether those activities are authorized under this permit. The holder shall perform cleanup or remediation immediately upon discovery of the release, threat of release, or discharge of hazardous materials. The holder shall perform the cleanup or remediation to the satisfaction of the authorized officer and at no expense to the United States. Upon revocation or termination of this permit, the holder shall deliver the site to the Forest Service free and clear of contamination. VI. LAND USE FEE AND DEBT COLLECTION A. LAND USE FEES. The use or occupancy authorized by this permit is exempt from a land use fee or the land use fee has been waived in full pursuant to 36 CFR 251.57 and Forest Service Handbook 2709.11, Chapter 30. VII. REVOCATION,SUSPENSION,AND TERMINATION A. REVOCATION AND SUSPENSION. The authorized officer may revoke or suspend this permit in whole or in part: 1. For noncompliance with federal, state, or local law. 2. For noncompliance with the terms of this permit. 3. For abandonment or other failure of the holder to exercise the privileges granted. 4. With the consent of the holder. 5. For specific and compelling reasons in the public interest. Prior to revocation or suspension, other than immediate suspension under clause VII.B, the authorized officer shall give the holder written notice of the grounds for revocation or suspension and a reasonable period, typically not to exceed 90 days, to cure any noncompliance. B. IMMEDIATE SUSPENSION. The authorized officer may immediately suspend this permit in whole or in part when necessary to protect public health or safety or the environment. The suspension decision shall be in writing. The holder may request an on-site review with the authorized officer's supervisor of the adverse conditions prompting the suspension. The authorized officer's supervisor shall grant this request within 48 hours. Following the on-site review, the authorized officer's supervisor shall promptly affirm, modify, or cancel the suspension. C.APPEALS AND REMEDIES. Written decisions by the authorized officer relating to administration of this permit are subject to administrative appeal pursuant to 36 CFR Part 214, as amended. Revocation or suspension of this permit shall not give rise to any claim for damages by the holder against the Forest Service. D. TERMINATION. This permit shall terminate when by its terms a fixed or agreed upon condition, event, or time occurs without any action by the authorized officer. Examples include but are not limited to expiration of the permit by its terms on a specified date and termination upon change of control of the business entity. Termination of this permit shall not require notice, a decision document, or any environmental analysis or other documentation. Termination of this permit is not subject to administrative appeal and shall not give rise to any claim for damages by the holder against the Forest Service. E. RIGHTS AND RESPONSIBILITIES UPON REVOCATION OR TERMINATION WITHOUT ISSUANCE OF A NEW PERMIT. Upon revocation or termination of this permit without issuance of a new permit, the holder shall remove all structures and improvements, except those owned by the United States,within a reasonable period prescribed by the authorized officer and shall restore the site to the satisfaction of the authorized officer. If the holder fails to remove all structures and improvements within the prescribed period, they shall become the property of the United States and may be sold, destroyed, or otherwise disposed of without any liability to the United States. However, the holder shall remain liable for all costs associated with their removal, including costs of sale and impoundment, cleanup, and restoration of the site.VIII. MISCELLANEOUS PROVISIONS A. MEMBERS OF CONGRESS. No member of or delegate to Congress or resident commissioner shall benefit from this permit either directly or indirectly, except to the extent the authorized use provides a general benefit to a corporation. B. CURRENT ADDRESSES. The holder and the Forest Service shall keep each other informed of current mailing addresses, including those necessary for billing and payment of land use fees. C.SUPERSEDED PERMIT. This permit is not superseded. D.SUPERIOR CLAUSES. If there is a conflict between any of the preceding printed clauses and any of the following clauses, the preceding printed clauses shall control. IX. INDEMNIFICATION AND INSURARANCE REQUIREMENTS FOR STATES(B-12) A. DAMAGE TO UNITED STATES PROPERTY.-The holder has an affirmative duty to protect from damage the land, property, and other interests of the United States Damage includes but is not limited to fire suppression costs, and all costs and damages associated with or resulting from the release or threatened release of a hazardous material occurring during or as a result of activities of the holder or the holder's heirs, assigns, agents, employees, contractors, or lessees on, or related to, the lands, property, and other interests covered by this permit. For purposes of clauses IV.G and section V, "hazardous material"shall mean (a)any hazardous substance under section 101(14)of the Comprehensive Environmental Response, Compensation, and Liability Act(CERCLA), 42 U.S.C. §9601(14); (b)any pollutant or contaminant under section 101(33)of CERCLA, 42 U.S.C. §9601(33); (c)any petroleum product or its derivative, including fuel oil, and waste oils; and (d)any hazardous substance, extremely hazardous substance, toxic substance, hazardous waste, ignitable, reactive or corrosive materials, pollutant, contaminant, element, compound, mixture, solution or substance that may pose a present or potential hazard to human health or the environment under any applicable environmental laws. 1. The holder shall avoid damaging or contaminating the environment, including but not limited to the soil, vegetation (such as trees, shrubs, and grass), surface water, and groundwater, during the holder's use and occupancy of the permit area. If the environment or any government property covered by this permit becomes damaged during the holder's use and occupancy of the permit area, the holder shall immediately repair the damage or replace the damaged items to the satisfaction of the Authorized Officer and at no expense to the United States. 2. Subject only to the limits on the holder's liability under the North Carolina State Tort Claims Act,the holder shall be liable for all injury, loss, or damage, including fire suppression or other costs associated with rehabilitation or restoration of natural resources, associated with the holder's use and occupancy of the permit area. Compensation shall include but is not limited to the value of resources damaged or destroyed, the costs of restoration, cleanup, or other mitigation, fire suppression or other types of abatement costs, and all associated administrative, legal (including attorney's fees), and other costs. Such costs may be deducted from a performance bond required under clause IV.L. 3. The holder shall be liable for damage caused by use of the holder or the holder's heirs, assigns, agents, employees, contractors, or lessees to all roads and trails of the United States that are open to public use to the same extent as provided under clause IV.G.1, except that liability shall not include reasonable and ordinary wear and tear. B. INDEMNIFICATION OF THE UNITED STATES. Subject only to the limits on the holder's liability under the North Carolina State Tort Claims Act, the holder shall indemnify, defend, and hold harmless the United States for any costs, damages, claims, liabilities, and judgments arising from past, present, and future acts or omissions of the holder in connection with the use and occupancy Authorized by this permit.This indemnification and hold harmless provision includes but is not limited to acts and omissions of the holder or the holder's heirs, assigns, agents, employees, contractors, or lessees in connection with the use and occupancy Authorized by this permit which result in (1)violations of any laws and regulations which are now or which may in the future become applicable, including but not limited to those environmental laws listed in this permit; (2)judgments, claims, demands, penalties, or fees assessed against the United States; (3)costs, expenses, and damages incurred by the United States; or(4)the release or threatened release of any solid waste, hazardous waste, hazardous substance, pollutant, contaminant, oil in any form, or petroleum product into the environment. C. ENVIRONMENTAL AND OTHER LIABILITY. Clauses IV.G and IV.I shall not be interpreted to limit any of the holder's liability for, or prevent the United States from taking any action to address, injury, loss, damages, or costs associated with environmental contamination, injury to natural resources, or other cause of action that arises under other law, including the Resource Conservation and Recovery Act, as amended, 42 U.S.C. §6901 et seq., CERCLA, 42 U.S.C. §9601 et seq., and the Clean Water Act, as amended, 33 U.S.C. § 1251 et seq., in connection with the holder's use and occupancy of federal lands, or to diminish any independent obligation of the holder to indemnify the United States with respect to the same. D. INSURANCE.The Authorized Officer has determined through a risk assessment that the potential liability of the United States for property damage and personal injury or death arising from the holder's use and occupancy Authorized by this permit is the liability limit in State Tort Claims Act or less per incident. Pursuant to the North Carolina State Tort Claims Act, the holder shall provide self-insurance covering claims for personal injury or death up to the liability limit in State Tort Claims Act. The self-insurance documentation shall name the United States as an additional insured. The coverage under the holder's self-insurance shall extend to property damage and personal injury or death arising from the holder's activities under the permit, including use and occupancy of National Forest System lands and the construction, maintenance, and operation of the structures,facilities, or equipment Authorized by the permit. 1.The Forest Service reserves the right to review and approve the self-insurance documentation and the CGL insurance. The holder shall send a copy of the approved self-insurance documentation and an authenticated copy of the CGL insurance to the Forest Service immediately upon approval or issuance.The self-insurance documentation the CGL insurance shall specify that the Forest Service shall be given 30 days prior written notice of cancellation or any modification of the self-insurance documentation or CGL insurance. 2. If there is a conflict between this permit,the certificate of insurance provided by the State risk management division (certificate)and/or State risk management division self-insurance policy manuals(self-insurance policy manuals),the order of precedence among those documents shall be(1)this permit; (2)the certificate; and (3)the self-insurance policy manuals. 3. If a claim is submitted to the United States for property damage and personal injury or death arising from the holder's use and occupancy Authorized by this permit,the Forest Service shall tender the defense of the claim to the respective representatives of the self-insurance and procured insurance provider.The holder understands that tort claims against the United States are governed by the Federal Tort Claims Act,which may result in the administrative denial of a claim.The holder further understands that in litigation the United States is represented by the United States Department of Justice (DOJ)and agrees that representatives of the self-insurance and procured insurance provider will coordinate the defense with DOJ, if a claim is litigated. THIS PERMIT IS ACCEPTED SUBJECT TO ALL ITS TERMS AND CONDITIONS. BEFORE ANY PERMIT IS ISSUED TO AN ENTITY, DOCUMENTATION MUST BE PROVIDED TO THE AUTHORIZED OFFICER OF THE AUTHORITY OF THE SIGNATORY FOR THE ENTITY TO BIND IT TO THE TERMS AND CONDITIONS OF THE PERMIT. ACCEPTED: ✓�- YWi" 7`� Off.�'G �'7 ' J'!' ��.7.,( HOLDER NAME, PRECEDED BY NAME AND TITLE SIGNATURE DATE OF PERSON SIGNING ON BEHALF OF HOLDER, IF HOLDER IS AN ENTITY APPROVED: DAVE CASEY District Ranger NAME AND TITLE OF AUTHORIZED OFFICER SIGNATURE DATE According to the Paperwork Reduction Act of 1995,an agency may not conduct or sponsor,and a person is not required to respond to a collection of information unless it displays a valid OMB control number.The valid OMB control number for this information collection is 0596-0082.The time required to complete this in€ormation collection rs estimated to average one hour per response,including the time far reviewing instructions,searching existing data sources,gathering and maintaining the data needed,and completing and reviewing the collection of information. The U.S.Department of Agriculture(USDA)prohibits discrimination in all its programs and activities on the basis of race,color,national origin,age,disability,and,where applicable, sex,marital status,familial status,parental status,religion,sexual onentation,genetic information,political beliefs,reprisal,or because all or part of an inclMdual's income is derived from any public assistance.(Not all prohibited bases apply to all programs.)Persons with disabilities who require alternative means for communication of program information(Braille, large print,audiotape,etc.)should contact USDA's TARGET Center at 202-720-2600(voice and TDD). To fife a complaint of discrimination,write USDA,Director,Office of Civil Rights,1400 Independence Avenue,SW,Washington,DC 20250-9410 or call toll free(866)632-9992(voice). TDD users can contact USDA through local relay or the Federal relay at(800)877-8339(TDD)or(866)377-8642(relay voice).USDA is an equal opportunity provider and employer. The Privacy Act of 1974(5 U.S.C.552a)and the Freedom of Information Act(5 U.S.C.552)govem the confidentiality to be provided for information received by the Forest Service. Special Use Authorization - Exhibit A j National Forests in North Carolina Created by:John Thompson, Special Uses Program Manager V 8/20/2021 Bore 5: Effluent Waste Treatment Bore 3: EQ Basin -82.792779 35.284644 -82.796095 35.284438 Depth: 10' ,. J Depth: 18' ')b Bore 1: Grit System -82.799402 35.284506 Depth-25' Bore 6: Raceways } -82.795618 35.284406 Depth: 10' n Bore 4: Broodstock - -82.796232 35.284136 Bore 7: Hatchery Building Depth: 10' -82.795530 35.284016 Depth: 5' F� Bore 2: Grit System -82.796366 35.280135 Depth: 20' Legend NC Wildlife Comm NFS Lands �f N r --, Boundary of proposed Authorization ID: TBD r'} W E disturbance S O Boring site Use Code: 512 County- Transylvania 0 0.01250.025 0.05 0.075 Quad Map. Shining Rock Miles Exhibit B: Design Features Archaeology • Bores#3, #5, #6 are considered PA 106 exempt (past archaeological survey or the site is located within an existing roadway) and will not require additional review. No Forest Service monitoring is required for these test sites. • Bores#1, #2, #4, #7 have not had an archaeological review in the past. A Forest Service archaeologist will be required to be on site to monitor the excavation of these bores. At least two weeks prior to boring activities, the permit holder is required to contact Kelsey Schmitz (kelsev.schmitz@usda.gov) and Joel Hardison (loel.hardison@usda.gov)to set up a time for monitoring. o During this monitoring, the archaeologist may request to excavate a 30cm round shovel test in the vicinity to check for any intact cultural stratigraphic layers. o The archaeologist will need to examine the soil column excavated from the boring process down to below any possible cultural habitation levels. • Should cultural resources be discovered, work must halt immediately at the affected bore sites. Additional analysis or consultation may be required prior to the Forest Service allowing the work to proceed. Appendix L — Outlet Protection Calculations User Input Data Calculated Value Reference Data Designed By: NLC Date: 3/19/2024 Checked By: SB Date: 3/19/2024 Company: McGill Associates Project Name: Setzer Fish Hatchery Project No.: 19.00124 Site Location(City/Town) Brevard,NC Culvert Id. Wetland Discharge Total Drainage Area(acres) 4.77 Step 1. Determine the tailwater depth from channel characteristics below the pipe outlet for the design capacity of the pipe. If the tailwater depth is less than half the outlet pipe diameter,it is classified minimum tailwater condition If it is greater than half the pipe diameter,it is classified maximum condition. Pipes that outlet onto wide flat areas with no defined channel are assumed to have a minimwn tailwater condition unless reliable flood stage elevations show otherwise. Outlet pipe diameter, Do(in.) 34 Equivalent Diameter for 2x 24"pipes Tailwater depth(in.) 0 Minimum/Maximum tailwater? Min TW(Fig.8.06a) Discharge(cfs) 44.4 10-year Velocity(ft./s) 7.1 Step 2. Based on the tailwater conditions determined in step 1,enter Figure 8.06a or Figure 8.06b,and determine d,riptap size and minimum apron length (I.J. The d,size is the median stone size in a well-graded nprap apron. Step 3. Determine apron width at the pipe outlet,the apron shape,and the apron width at the outlet end from the same figure used in Step 2. Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d50,(ft.) 0.6 6"minimum Minimum apron length,La(ft.) 18 Apron width at pipe outlet(ft.) 8.5 8.5 Apron shape Trapezoid Apron width at outlet end(ft.) 20.83333333 2.833333333 Step 4. Determine the maxim,—stone diameter. d_=1.5 x d5o Minimum TW Maximum TW Max Stone Diameter,dmax(ft.) 0.9 0 Step S. Determine the apron thickness: Apron thickness=1.5 x d_ Minimum TW Maximum TW Apron Thickness(ft.) 1.35 0 Step 6. Fit the riprap apron to the site by making it level for the minimum length,L, from Figure 8.06a or Figure 806b. Extend the apron farther downstream and along channel banks until stability is assured. Keep the apron as straight as possible and align tt with the flow of the receiving stream. Make any necessary alignment bends near the pipe outlet so that the entrance into the receiving stream is straight. Some locations may require lining of the entire channel cross section to assure stability. It may be necessary to increase the size of riprap where protection of the channel side slopes is necessary(Appand&8.05) Where overfalls exist at pipe outlets or flows are excessive,a plunge pool should be considered see page 8 069 outlet W Do 4 La Pipe diameter(Dof La 80 ........la w ter � 0.50o i i . It ONO E . y l arl Ma id 4 10 ra z o :f: - ii1 } l CL CL = 1s v to 0 3 5 10 20 59 1DD 200 500 l000 Discharge(Olsec) Curves may not be extrapolated. Figure 8.06a Ocsfgn of❑urlet protecl*n protccYcn from a round pipe flowing full•minimum tailwater rondit)on(T.t 0.5 diameter) Re"1:193 8.06J Figure 8.06b: Design of outlet protection from a round pipe flowing full, maximum tailwater condition (Tw>=0.5 diameter) 3Do -:::�]i Outlet i+ = Do + 0.4L8 120 pipe 4�' di ,- diameter 4g71 Le 110 � - i .5Do IWAr 100 90 �~ 80 - A�PQ` 70 ---- - r. 4 - :.ti .. .... I r .. .. tir e � a 50 f _. 3 30 ..r b+� r. -f � C 1 20 V. r �p _ ! �' Y 2 LI? n v�25 b • • Q 0 - - - - • • D _D D D 1 Or 0 3 5 10 20 50 100 200 500 1000 Discharge(ft3fsec) Curves may not be extrapolated. Figure 8.06b Design of outlot protection from a round ppe flowing full.maxxnum tailwalof condition(T.,?0.5 ckameter). 8.06.4 Rw.1Ll3 Velocity of Water in Forebay Bottom Inv 2329.67 ft Forebay Bottom Width 24 ft Forebay Side Slopes 2:1 Cross-Sectional Area @ Permanent Pool 102 SF V= Q/A Pipe System D - Discharge (10-yr) 23.95 cfs Velocity 0.23 ft/s Stabilized Velocity of Bare Soill 1.00 1 ft/s Forebay Proposed Velocity =Stabilized JJ mcgiil, Project Description: Setzer Fish Hatchery Project Number: 19.00124 Drainage Area Calculations Date: 3/15/2024 Calculated By: NLC Drainage Area ID Total Area(acres) Total Area(sf) Impervious Wooded Lawns,Sandy Soil,Flat(<2%) C Q1 Q10 Q25 Q50 Q100 Existing DA @ HW A 4.622 201,314 41,150 50,528 109,636 0.286 6.66 10.65 12.16 13.36 14.55 Existing DA @ HW C 4.014 174,856 80,279 0 94,577 0.490 9.90 15.84 18.09 19.88 21.65 Proposed HW A 3.786 164,9321 63,6211 0 101,311 0.4281 8.151 13.041 14.891 16.361 17.82 Proposed HW C 2.592 112,8881 85,8411 0 27,047 0.7461 9.731 15.571 17.781 19.541 21.28 Description Rational Runoff Coefficients Table 3-2 User Input Cell Unimproved Areas 0.35 Ratiionalrunoff coefficients(,_�E,1975,Viessnnan,etal.,1996;and Malcom,1999} Calculated Cell Asphalt 0.95 Description of Surface Ratioral Runoff Coefficients,C Concrete 0.95 Unimproved Areas 0.35 Brick 0.85 Asphalt 0.95 0. Roofs,Inclined 1 Concrete 95Briek 095 Roofs,Flat 0.9 goofs,inclined 1.00 Lawns,Sandy Soil,Flat(<2%) 0.1 Raafs,flat 0.90 Lawns,Sandy Soil,Average(2-7%) 0.15 Iawns,sander soil,Flat(<2%) 0.16 Lawns Sandy Soil,Steep(>7%) 0.2 Lawns,sandy soil,average(2-79G] 0.15 Lawns,Heavy Soil,Flat(<2%) 0.15 Lawns,sandy soil,steep,(>7%) 0.20 Lawns,Heavy Soil,average(2-7%) 0.2 Lawns.heavy soil,flat 0.15 Lawns,Heavy Soil,Steep(>7%) 0.3 Lawns.•heavy soil average(2-596} 0.20 Bare Packed Soil 0.6 Lawns•heavy soil,steep(P-7%) 0.31D WeA-ded areas 0.15 Wooded Areas 0.15 1 Year intensity(in/hr) 5.03 Taken From NOAA(1 yr,5 min duration) 10 Year intensity(in/hr) 8.05 Taken From NOAA(10 yr,5 min duration) 25 Year intensity(in/hr) 9.19 Taken From NOAA(25 yr,5 min duration) 50 Year intensity(in/hr) 10.1 Taken From NOAA(50 yr,5 min duration) 100 Year intensity(in/hr) 11 Taken From NOAA(100 yr,5 min duration) Culvert Report Hydraflow Express Extension for Autodesk@ Civil 3D@ by Autodesk, Inc. Monday, Mar 18 2024 Exisitng Pipe Discharge into River @ Prop HW A Location Invert Elev Dn (ft) = 2347.75 Calculations Pipe Length (ft) = 202.90 Qmin (cfs) = 10.65 Slope (%) = 1 .04 Qmax (cfs) = 10.65 Invert Elev Up (ft) = 2349.85 Tailwater Elev (ft) _ (dc+D)/2 Rise (in) = 15.0 Shape = Circular Highlighted Span (in) = 15.0 Qtotal (cfs) = 10.65 No. Barrels = 1 Qpipe (cfs) = 9.62 n-Value = 0.012 Qovertop (cfs) = 1 .03 Culvert Type = Circular Corrugate Metal Pipe Veloc Dn (ft/s) = 7.91 Culvert Entrance = Headwall Veloc Up (ft/s) = 7.84 Coeff. K,M,c,Y,k = 0.0078, 2, 0.0379, 0.69, 0.5 HGL Dn (ft) = 2348.96 HGL Up (ft) = 2352.58 Embankment Hw Elev (ft) = 2354.01 Top Elevation (ft) = 2354.00 Hw/D (ft) = 3.33 Top Width (ft) = 200.00 Flow Regime = Outlet Control Crest Width (ft) = 200.00 E1-1{1 Exisitng Pipe Discharge into River @ Prop HW A Location Hw Depth(ft) 2355.00 5.15 2354.00 4.15 2358.00 3.15 '352.00 2.15 2351.00 1.15 2350.00 0.15 2349.00 -0.05 2348.00 -1.85 234700 -2.85 2346.00 -3.85 0 50 100 150 200 250 300 350 400 45D 01-1l,Culvert HGL 1m1-1 Reach(0} Culvert Report Hydraflow Express Extension for Autodesk®Civil 3D®by Autodesk, Inc. Friday, Mar 15 2024 Exisitng Pipe Discharge into River @ Prop HW C Location Invert Elev Dn (ft) = 2336.51 Calculations Pipe Length (ft) = 83.20 Qmin (cfs) = 15.84 Slope (%) = 2.39 Qmax (cfs) = 15.84 Invert Elev Up (ft) = 2338.50 Tailwater Elev (ft) = (dc+D)/2 Rise (in) = 18.0 Shape = Circular Highlighted Span (in) = 18.0 Qtotal (cfs) = 15.84 No. Barrels = 1 Qpipe (cfs) = 11 .33 n-Value = 0.012 Qovertop (cfs) = 4.51 Culvert Type = Circular Corrugate Metal Pipe Veloc Dn (ft/s) = 6.62 Culvert Entrance = Headwall Veloc Up (ft/s) = 7.03 Coeff. K,M,c,Y,k = 0.0078, 2, 0.0379, 0.69, 0.5 HGL Dn (ft) = 2337.90 HGL Up (ft) = 2339.79 Embankment Hw Elev (ft) = 2341 .08 Top Elevation (ft) = 2341 .00 Hw/D (ft) = 1 .72 Top Width (ft) = 81 .00 Flow Regime = Inlet Control Crest Width (ft) = 81 .00 Wetland Outlet Headwall Rectangular Broad-Crested Weir Q (cfs) = 3.09LH1.5 L=crest length of weir, in feet H = head on weir, in feet Length of Weir 11.00 ft 10-yr Flow Rate ^^ ^1 cfs Head on Weir: 1.195 ft V=Q/A Flow Areal 13.15 ft2 Velocity 3.38 ft/s Per"Open Channel Hydraulics", Ven T. Chow, PhD; Pg 165, Table 7-9, The Maximum Permissible Velocity; McGraw Hill, 1959, re-issue 1988. Cobbles and Shingles, Clear Water, Maximum Permissible Velocity 5.00 Recommended ft/s PASS HW A Rectangular Broad-Crested Weir Q (cfs) = 3.09LH1.s L=crest length of weir, in feet H = head on weir, in feet Length of Weir 6.00 ft 10-yr Flow Rate 13.04 cfs Head on Weir: 0.791 ft V=CVA Flow Areal 4.75 ft' Velocity 2.75 ft/s Per"Open Channel Hydraulics", Ven T. Chow, PhD; Pg 165,Table 7-9,The Maximum Permissible Velocity; McGraw Hill, 1959, re-issue 1988. Cobbles and Shingles, Clear Water, Maximum Permissible Velocity 5.00 Recommended ft/s PASS HW C Rectangular Broad-Crested Weir Q (cfs) = 3.09LH1.s L=crest length of weir, in feet H = head on weir, in feet Length of Weir 6.00 ft 10-yr Flow Rate 15.57 cfs Head on Weir: 0.890 ft V=Q/A Flow Area 5.34 ft' Velocity 2.92 ft/s Per"Open Channel Hydraulics", Ven T. Chow, PhD; Pg 165,Table 7-9,The Maximum Permissible Velocity; McGraw Hill, 1959, re-issue 1988. Cobbles and Shingles, Clear Water, Maximum Permissible Velocity 5.00 Recommended ft/s PASS