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Home My WebLink AboutNC0088749_Engineering Alternatives Analysis_20080218/vzopl�s9�f ENGINEERING ALTERNATIVES ANALYSIS NPDES DISCHARGE PERMIT APPLICATION FOR THE PROPOSED LISSARA WASTEWATER TREATMENT PLANT FORSYfH COUNTY, NC Prepared for: Lissa ra Partners, LLC 2631 Reynolda Road Winston-Salem, NC 27106 February 2008 �`�1; `cARo�- ..does.. moo:: o�ESSIp;�•..y9.,. r • r r IWO wo 10130 �'�� •dodo GIN •dodo••• F PVA\ Prepared by: Diehl & Phillips, P.A. Consulting Engineers 219 E. Chatham Street Cary, NC 27511 No pm TABLE OF CONTENTS o' Engineering Alternatives Analysis A. General EAA-1 to EAA-2 B. Summary of Wastewater Treatment and Disposal EAA-2 to EAA-5 PM Options Considered C. Narrative Description of the Proposed Treatment Works EAA-6 to EAA-8 Im D. General Location Map EAA-8 E. Scale Site Plan EAA-8 F. Special Studies or Modeling Where DWQ Cannot Determine EAA-8 the Impacts of the Discharge G. Financial Qualifications/Substantial Previous Compliance EAA-8 Statement H. Other Possible Combinations of Alternatives EAA-8 I. Potential Acquisition of Additional Land EAA-8 to EAA-9 1. Conclusion EAA-9 Appendix A — Economic Evaluation of Alternatives PW Alternative No. 1— Connection to Publicly Owned Treatment Works Page 1 W Alternative No. 2 — Connection to Privately Owned Treatment Works Page 1 Alternative No. 3 — Individual Subsurface Systems Pages 2 to 10 Alternative No. 4 — Wastewater Collection System and Wastewater Pages 11 to 21 Treatment Plant, with Disposal through Conventional Nitrification Lines in a Community System Alternative No. 5 — Wastewater Collection System and Wastewater Pages 22 to 34 Treatment Plant, with Disposal through Drip Irrigation Lines (Surface Applied) Alternative No. 6 — Wastewater Collection System and Wastewater Pages 35 to 45 Treatment Plant, with Disposal through Spray Irrigation System Alternative No. 7 — Wastewater Collection System and Wastewater Pages 46 to 54 Treatment Plant, with Disposal through Surface Discharge to Yadkin River PM Alternative No. 8 - Wastewater Collection System and Wastewater Pages 55 to 66 Treatment Plant, With Re -Use Quality Effluent Disposal Through Drip Irrigation Lines (Surface Applied) Im am .MM ADaendix B — Re -Examination of Alternatives With the Assumption that Additional Land is Available Summary of Present Worths of Revised Alternatives Pages 1 to 2 Alternative No. 3 — Individual Subsurface Systems Pages 3 to 6 Alternative No. 4 — Wastewater Collection System and Wastewater Pages 7 to 12 Treatment Plant, with Disposal through Conventional Nitrification Lines in a Community System Alternative No. 5 — Wastewater Collection System and Wastewater Pages 13 to 18 Treatment Plant, with Disposal through Drip Irrigation Lines (Surface Applied) Alternative No. 6 — Wastewater Collection System and Wastewater Pages 19 to 24 Treatment Plant, with Disposal through Spray Irrigation System Alternative No.-8 - Wastewater Collection System and Wastewater Pages 25 to 30 Treatment Plant, With Re -Use Quality Effluent Disposal Through Drip Irrigation Lines (Surface Applied) Appendix C — Infrastructure Cost Basis Pages 1 to 3 �+ Appendix D — Preliminary Soils Report Prepared by Soil & Pages 1 to 5 Environmental Consultants, P.A. Appendix E — Letter Regarding the Estimated Market Value of the Lissara Lots OR Appendix F — Letter from Winston-Salem • Fomvth County — City/ County Utilities Regarding the Capacity of the Town of Lewisville to Provide Wastewater Service to Lissara Ow Appendix G - Executed NPDES Application — Form D, with USGS P" Mapping Indicating Location of Requested Discharge Appendix H — Preliminary Water Balances for Alternatives No. 5, 6, and 8 Appendix I — Correspondence Regarding USGS Streamflow Estimates For the Proposed Discharge Point in the Yadkin River am an Appendix 3 — Executed Attachment A. Local Government Form, per EAA Guidance Document ^' Appendix K — Sensitivity Analysis to Examine the Effect of Various Interest Rates on the Relative Rankine of the Alternatives MR I" P" PM m" PM mm FM w Im P" PM ow p" p" PM PM ENGINEERING ALTERNATIVES ANALYSIS TO SUPPORT AN NPDES DISCHARGE PERMIT REQUEST FOR THE PROPOSED LISSARA WASTEWATER TREATMENT PLANT A. GENERAL: 1. Introduction This Engineering Alternatives Analysis (E.A.A.) is submitted in support of an application for a NPDES permit. The proposed permitted flow is 0.108 MGD. This proposal has been prepared in accordance with 15A NCAC 21-1.105(c)(1) through (7) and the Division of Water Quality's (DWQ) "Guidance for the Evaluation of wastewater Disposal Alternatives" (ver. June 251 2005). The proposed permit is for a domestic wastewater treatment plant to serve 225 lots in a new subdivision, identified as Lissara, on approximately 246.3 acres of land. As detailed in Appendix A, the wastewater flows have been estimated in accordance with 15 NCAC 21-1.0219. The wastewater will be domestic in nature. M" 2. Project Identification Information ,M Facility Name: Lissara WWTP County: Forsyth Engineering Alternative Analysis preparer: John F. Phillips, P.E. (919) 467-9972 Diehl & Phillips, P.A. (919) 467-5327 (fax) EAA preparer's address and telephone number: IM Diehl & Phillips, P.A. 219 E. Chatham St. Cary, NC 27511 im 3. Project Description 1W The proposed treatment plant will serve the Lissara subdivision. The proposed plant will serve 224 lots, or 107,520 gpd. The projected wastewater flow from these lots is: "" 224 lots assumed with four bedroom houses: 224 @ 480 gpd = 107,520 gpd A permit flow of 107,52000 gpd is required for this number of lots. This value will be rounded upward to 108,000 gpd (0.108 mgd), and used for the treatment plant/surface discharge alternative in this EEA. Ow EAA-1 MR The locations of the proposed Lissara Subdivision and the potential service area of the Lissara Wastewater Treatment Plant (WWTP) are indicated on Figure No. 1 Vicinity Map and Figure No. 2 Proposed Service Areas. 4. Existina Facilities There are no existing facilities. 0" 5. Phasing 0" P" fW M" P" PM The proposed Lissara Wastewater Treatment Plant will be constructed in one phase, with a wastewater treatment capacity of 0.108 mgd. B. SUMMARY OF WASTEWATER TREATMENT AND DISPOSAL OPTIONS CONSIDERED The results of this study clearly indicate that a new wastewater treatment plant discharging into the Yadkin River is the most economically feasible of all the environmentally feasible options. The various waste treatment and disposal alternatives considered and investigated include: 1. Connection to a publicly owned treatment plant and wastewater collection system. 2. Connection to a privately owned treatment plant and wastewater collection system. 3. Individual subsurface systems on each lot 4. Wastewater Collection System and Wastewater Treatment Plant, with Disposal through Conventional Nitrification Lines 5. Wastewater Collection System and Wastewater Treatment Plant, with Disposal through Drip Irrigation Lines (Surface Applied) 6. Wastewater Collection System and Wastewater Treatment Plant, with Disposal through Spray Irrigation System 7. Wastewater Collection System and Wastewater Treatment Plant, with Disposal through Surface Discharge to the Yadkin River 8. Wastewater Collection System and Wastewater Treatment Plant, With Re -Use Quality Effluent Disposal Through Drip Irrigation Lines (Surface Applied) EAA-2 \\ f -- elf � rl \:/J \.��%- r 1 / \"" � � ■ . ".!"=l i 'ram � -\-� _^` \ 1 �� •�..'1 1 //-- \\ \\`__ �, '-'.i A, p —VI 1.� ' — — �� =_— .r l._,.W-.....:»�....''^"`••+' ",..� .�•,• {I 1 i / \) II 1 \ 1 / / ,,+'� [ ?� ` — /__ —_ �' �\ 1 f , 1 11,' I ! j �\ �` �, J 11/If 1 _ 11 I/ �! \\ ,/ / / / ,r �r J .�fY•'^J 1 I 1 II I , / ,\ \ I I `\ \ \ `•1 , \ \�, , 1 / ,—/ I 1 / i / // i , \ , �t\`l�C-'1 I11 \,11�i,! /� \1 �rl ,� ,1 ♦, \ �/ r / i /„ j/ /' / —�— `J / �_ —' / I r t 1 t ! / ',�': �'/' �'-•"'w�/' i i ' I,,� \ (_ / /� \\ �.l } `I \I i `;\ `\'\\\ l \ _ "�} ' • '.� t ,--- /!\ Q, r I __, r 1� r=��.� I \ .) 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SR 1175 \, _°��J ' I 1 1 __ - �• I fi r TREVOR L /~; , I I _ `,\ \ / r I 1 /. \� / PRIVATE )/f,� FIGURE No. 2 GRAPHIC SCALE.: r '� 600 0 300 600 1200 2400 PROPOSED SERVICE AREA IN FEET 1 inch = 600 ft. 0" For all alternatives, the water supply will be through an extension of public water systems (Winston-Salem • Forsyth Co. — City/County Utility System). All of the alternatives are environmentally feasible options that are routinely permitted in North Carolina although a central sub -surface system of the size described herein would be unusual in the Piedmont area of North Carolina. The ranking of the alternatives, in terms of environmental feasibility, will vary on a case -by -case basis. For example, it is generally agreed that connection to a publicly owned treatment works (POTW) would be the most desirable. A discharge to surface waters is not as environmentally desirable as a connection to a POTW, but a new discharge remains an environmentally feasible option if the receiving stream has sufficient assimilative capacity to accept the projected waste load. If the present worth values of the two alternatives in this example were equal, the POTW connection should be selected, according to 15A NCAC 2H.105(c)(2). However, if the connection to the POTW is not reasonably cost effective when compared to the cost of the new surface discharge, then the POTW connection alternative must be discarded from further consideration. 15A NCAC 2H.105(c)(2) states the selected alternative must be the most environmentally sound alternative as selected from THE REASONABLY COST EFFECTIVE options. (Emphasis added.) PM The present worth values of the eight alternatives are: Ow M, RM M MR PM MR Alt. Description Present Worth Number 1 Connection to Publicly Owned Treatment Works N/A 2 Connection to Privately Owned Treatment Plant N/A 3 Individual Sub -surface Systems $13,103,534 4 Wastewater Collection System and Wastewater Treatment Plant, $14,095,607 with Disposal through Conventional Nitrification Lines 5 Wastewater Collection System and Wastewater Treatment Plant, $12,840,603 with Disposal through Drip Irrigation Lines (Surface Applied) 6 Wastewater Collection System and Wastewater Treatment Plant, $13,305,554 with Disposal through Spray Irrigation System Wastewater Collection System & Wastewater Treatment 7 Plant, with Disposal through Surface Discharge to Yadkin $8,038,626 River Wastewater Collection System and Wastewater Treatment Plant, 8 With Re -Use Quality Effluent Disposal Through Drip Irrigation $12,483,793 Lines (Surface Applied) Appendix A includes a detailed explanation of each alternative, its capital cost and operation/maintenance (0&M) costs, and its present worth. EAA-5 FM P" I, C. NARRATIVE DESCRIPTION OF THE PROPOSED TREATMENT WORKS: PM 1. Design Flows: Proposed Plant: 0.108 MGD = 75 gallons per minute Peaking Factor: 2.5 W1 Peak Flow = 2.5 x 0.108 mgd = 0.270 mgd = 188 gpm 2. Pretreatment: Manually cleaned bar rack MR 3. Treatment Plant: Volumes: Flow Equalization 32,400 (30% of design flow) Aeration Zone 108,000 gallons (24 hrs, hydraulic detention, divided equally into two trains in each phase plant) Sludge Holding 32,400 gallons in plant (30% of daily plant capacity — divided equally into two trains in each plant) Pumps: Flow Equalization duplex submersible pumps with flow control box Return Sludge air-lift pumps with a combined capacity of 112 gpm for the plant (150% of design flow). Flow rate can be varied by throttling the air supply. Aeration: The aeration plant will have its own blower system. The estimated air distribution will be as follows: MM Aeration Zone Volume: 108,000 gallons Air required for mixing (exceeds process requirements). 30 SCFM/1,000 Cu Ft x 108,000 gal./7.48 gal. x 1 Cu Ft = 433 SUM required to mix aeration zone plus 70 SUM allowance for air-lifts, post aeration, etc. 503 SUM air required from blowers. OR Three positive displacement blowers to be provided, each rated for 510 SCFM at 4.5 psi pressure The sludge holding and flow equalization basins are aerated by positive displacement blowers, which are capable of operating with the varying pressures created due to the liquid level fluctuations. MR EAA-6 MR OR �, Sludge Holding Volume: 32,400 gallons total 16,200 Gal/Plant PM Air required: Sludge Holding — 30 SCFM/1000 Cu. Ft. 30 SCFM/1,000 Cu Ft x 32,400 gal (sludge vol.)/7.48 gal. x 1 Cu Ft = 130 SUM Three positive displacement blowers to be provided for sludge -holding, �' each rated for 65 SUM (two in use, one standby) MR Flow Equalization Volume: 32,400 gallons total Air required: Flow Equalization —1.5 CF/1,000 gal to prevent septic MR conditions 32,400 (Flow Eql. Vol.) gal x 1.5 Cu Ft/1,000 gal = 49 SUM rM Two positive displacement blowers to be provide for flow equalization, each rated for 50 SUM 4. Clarifiers: Four @ 101Nx10'L Each Surface Overflow Rate at AN - 270 gallons/day/SF Hydraulic detention time — 6.0 hours r'�' Scum removed to flow equalization basin Weir loading rate —1,350 gallons/LF/Day ran 5. Tertiary Filter: Filter area: Four cells @ 18.75 SF Ea. = 75 SF Total Filtration rate —1.0 gpm/SF at AN Backwash return to the flow equalization basin Backwash rate— up to 20 gpm/SF, w/air scour by dedicated blower Media - 6" anthracite - 1.1-1.2 mm effective size, UC = 1.5 �+ 15" filter sand - .45 — .50 mm effective size, UC = 1.6 12" gravel - various graduations, with upper 3 inches having an effective size of .80 —1.20 mm, UC = 1.7 ^� 6. Post Aeration Unit: Provide 30 minutes for plant at AN 7. U.V. Disinfection Unit: Rated for a peak flow of 270,000 gpd, and have the redundancy required by DWQ's latest policies for U.V. disinfection. 8. Effluent Flow Measurement: fm 450 V-notch weir with flow recorder/totalizer MR EAA-7 MR PM 'M 9. Chemical Feed System: 3,000 gallons storage for 25% NaOH (ph adjustment) 'm 10. Sludge Holdin_ : Volume — 32,400 gallons fm Storage capacity at estimated sludge production — 38 days Decant by air-lift, supernatant returned to flow equalization F" D. GENERAL LOCATION MAP: See Figures 1 and 2. MR E. SCALE SITE PLAN: A site plan for each alternative is included in the appendix. ran F. SPECIAL STUDIES OR MODELING WHERE DWQ CANNOT DETERMINE IMPACTS OF DISCHARGE: FM Not required at this time. G. FINANCIAL QUALIFICATIONS/ SUBSTANTIAL PREVIOUS COMPLIANCE fm STATEMENT: PM Applicant partnership was created for the purpose of developing real property for residential purposes. If the requested permit is issued, the partnership would transfer the ownership of the wastewater facility and NPDES permit to a licensed utility company operating under the rml regulations of the North Carolina Utilities Commission. The utility company will be required to be in sound financial condition and in good standing with the Utilities Commission. RM . H. OTHER POSSIBLE COMBINATIONS OF ALTERNATIVES Alternatives No. 1 through No. 6, No. 8, and all of the variations included in Appendix B "' address the wastewater treatment and disposal alternatives for the subject property, as required by the DWQ Guidance for the Evaluation of Wastewater Disposal Alternatives. M I. POTENTIAL ACQUISITION OF ADDITIONAL LAND: The potential acquisition of land to provide additional treatment capacity for the land based disposal systems (Alternatives No. 3 through No. 6, and No. 8) was considered as a part of this E.A.A. Prior to contacting any adjacent property owners about the possibility of purchasing portions of their land, economic analyses were performed to determine the effect of additional land for each alternative. MR These economic analyses used the infrastructure costs in Alternative No. 7, the treatment plant alternative (serving 224 lots), and then scaled -up the land -based wastewater disposal system in each of the alternatives as required to serve 224 lots. The present worth of the am EAA-8 OW FM FM infrastructure, scaled -up wastewater disposal system, and increased annual 0&M costs was determined for each alternative and compared to the present worth of Alternative No. 7. In each case the present worth of the scaled -up land based treatment alternative exceeded the I present worth of Alternative No. 7, without including any cost for the additional land acquisition or piping to convey the treated wastewater to the disposal site(s). Based on the results of these analyses, it is apparent that acquisition of additional lands would not change the present worth ranking of Alternative No. 7; therefore, no adjacent landowners were contacted regarding the possible sale of their property. The economic analyses that examine the scaled -up alternatives and additional land acquisitions are presented in Appendix B. 1. CONCLUSION: FM As demonstrated in the information included in this E.A.A. and the Appendices, the selection of the Alternative with the treated wastewater discharge to surface waters, Alternative No. 7, was made only after extensive consideration of all the other Alternatives. Of the environmentally sound Alternatives, a treatment plant discharging treated wastewater to the Yadkin River is the only reasonably cost effective Alternative when compared to all of the land based disposal systems. On behalf of the applicant, we request approval of a discharge permit into the Yadkin River at the indicated location, for a total permitted flow of 0.108 MGD of treated wastewater. FM PM FM MR MM P" MR IM APPENDIX A ECONOMIC EVALUATION OF ALTERNATIVES PM MR ALTERNATIVE NO. 1 CONNECTION TO PUBLICLY OWNED TREATMENT WORKS The proposed Lissara development is outside of the extra -territorial jurisdiction (ETJ) of the Town of Lewisville, but is within a five -mile radius of the Town of Lewisville wastewater collection system. The Town of Lewisville is provided wastewater capacity by the Winston- Salem/Forsyth County Utility Commission. A request for sewer service was presented to the Commission by the Lissara developer in April 2006, since the proposed development is not located within the Town's ETJ. The request for service was denied by the Commission, and the developer was notified of this decision by letter dated April 26, 2006 (see Appendix F for a copy of the letter). With no connection to a publicly owned treatment works possible, Alternative No. 1 is dropped �+ from further consideration. "M ALTERNATIVE NO. 2 CONNECTION TO A PRIVATELY OWNED TREATMENT PLANT IM MR W M" M" MR M" am There are not, to the best of the preparer's knowledge, any privately owned treatment plants within a five mile radius that have sufficient capacity to accept a 108,000 gpd flow from the proposed Lissara development. Therefore, any consideration of this option would require an increase in the NPDES permit capacity for an existing facility in the same river basin as the proposed Lissara project. The same considerations would be addressed in the Engineering Alternatives Analysis for the expansion of another facility as are considered in this E.A.A. For these reasons, connection to a privately owned wastewater treatment plant in not considered a viable Alternative for this E.A.A. Appendix A Page 1 No ALTERNATIVE NO. 3 INDIVIDUAL SUB -SURFACE SYSTEMS This Alternative considers the installation of individual septic systems for each single-family lot, rather than reliance on a new wastewater treatment plant for sewer service. The economic benefits of this Alternative include the elimination of the costs of a wastewater collection system and a wastewater treatment plant. The principal economic disadvantage is the individual septic systems require larger lots than those served by a wastewater collection system, thus the number of lots developed will be less under this Alternative. MR The lots must be configured to contain at least 20,000 square feet of soils suitable for a septic system and a 100% repair area, plus an additional 10,000 square feet for the house, driveway, setback areas. The preliminary lot layout for Alternative No. 3 utilizes lots with MR 30,000 SF (minimum) total areas. In some cases, where the lot did not have sufficient suitable soil areas to support a wastewater system and repair area, a remote lot in suitable soils was created for the required disposal/repair area. Using the lot yield from the detailed preliminary subdivision plan, the total number of lots developed under this Alternative will be 83 lots. The suitable subsurface soils were mapped for this project, and the map and description can be found in the Soil & Environmental Consultants report in Appendix D. Figure 3-A presents the location of the soils determined to be suitable for subsurface disposal. The preliminary lot arrangement is illustrated in Figure 3-13. It will be assumed that the majority of the single family wastewater systems will consist of a 1,200 gallon septic tank followed by gravity distribution boxes and conventional nitrification trenches (3 feet wide by 2 feet deep) with a 4" corrugated pipe installed in a 12 inch deep layer of washed stone. The soils report by S&EC indicated the mapped soils would provide an �+ LTAR (Long Term Acceptance Rate) of 0.30 gallons per day per square foot of trench bottom, for conventional nitrification trench systems. For a four -bedroom home and an LTAR of .30 gpd/sf of trench bottom, approximately 533 LF of nitrification trench is required for each �+ single-family home. The typical installed cost for a conventional system of this size is approximately $3,000 to $3,500. Some of the lots would most likely require pump systems due to the topography of the lots, and some might require low-pressure pipe (LPP) systems or subsurface drip irrigation systems due to topography, shallow soils, soil wetness, or other reasons. These pump -to -conventional systems and the LPP/drip systems would have costs ranging from $4,500 to $5,500, or higher in some cases. The proposed plan includes sixteen lots with remote or "satellite" lots for wastewater disposal. The cost of these p systems will vary depending on the distance of the separation from the main lot. For the purposes of this EAA, Table 3-A indicates the types and numbers of wastewater systems assumed for the 83 lots under this Alternative. No Appendix A �, Page 2 k/NS NE, HAUSER SR 1175 TREVOR PRIVATE LEGEND Areas contain soils with 24 inches or more of useable material and have potential 1 for conventional, modified conventional, 1 ultra —shallow conventional, or LPP 1 type septic systems. \ MARGINAL LANDSCAPE POSITION Area contains soils with 24 inches or more UNS of useable material, in a marginal landscape position. See S&EC Report. I <� UNS UNSUITABLE NE NOT EVALUATED f E r UNS UNS �-``1--- UNS UNS UNS UNS UNS UNS 11UNS /--- 1 / NE UNS/ GRAPHIC SCALE 600 0 300 600 1200 I I• ( IN FEET ) 1 inch = 600 ft. UNS �l t FIGURE No. 3-A SOILS SUITABLE FOR SUBSURFACE SYSTEMS COLOR SHADING KEY _ LAKE, STREAM OR OPEN WATER 50' BUFFER ON STREAMS mo HAUSER RD SR 1175 TREVOR PRIVATE r 0 1 9 pPO O� rR,nPxrr. sr,ai,F cjor`� FIGURE No. 3-B INDIVIDUAL SEPTIC TANKS ( Tip T-TT-T ) 1 ;,,c'h Goo ft FM faq FOR P" W TABLE 3-A Type of Single Lot Wastewater System Number Installed Cost Total Costs Lots served with conventional gravity systems 33 $3 250 $107,250 Lots served with pump to conventional gravity systems 20 4 500 90 000 Lots served with Low Pressure Pie systems 13 $5 500 $71 500 Lots served with remote sub -lots — pump to conventional gravity systems 13 $6,500 $84,500 Lots served with remote sub -lots — Low Pressure Pipe stems 4 $7,500 $30,000 Totals 83 $383,250 Other Costs/Savings �► Under this Alternative there would be less infrastructure construction required than under the surface discharge Alternative because there would be fewer lots developed, and because there would not be a wastewater collection system. The infrastructure unit cost developed in Appendix C is $344 per linear foot of street constructed. This cost includes all land clearing, grading, erosion control, storm drainage, water mains, valves, fire hydrants, paving, curb & gutter, turn lane construction on existing road, engineering, and surveying. Alternative No. 3 has 12,152 LF of street. The only items not included in the unit cost factor are the water services for the lots. This cost varies depending upon the number of lots developed, and is therefore calculated for each Alternative. MR MR The infrastructure costs for Alternative No. 3 are: $344/LF of street x 12,152 LF of streets $4,1801,288 Water services: 83 x $700 each 58 100 Total Infrastructure Cost $4,238,388 RM Lost opportunity cost due to developing 83 lots in lieu of the 224 lots possible under the treatment plant/surface discharge Alternative: IM Alternative No. 7, the treatment plant with surface water discharge, has the following number and types of lots: 32 Waterfront lots, sale price of: $137,500 each 70 Garden home lots, sale price of: $ 65,000 each 44 Non -waterfront lots (ave. 0.58 ac.), sale price of: $ 85,000 each 78 Non -waterfront lots (ave. 0.67 ac.), sale price of: $100,000 each «� 224 Total number of lots am Appendix A Page 5 PM FMM Alternative No. 3 has the following number and types of lots: 18 Waterfront lots 0 Garden home lots 0 Non -waterfront lots (ave. 0.58 ac.) 65 Non -waterfront lots (ave. 0.67 ac.) 83 Total number of lots The lost opportunity cost for the lots not included in Alternative No. 3 is: 14 Waterfront lots at: $137,500 each = $11,925,000 70 Garden home lots at: $ 65,000 each = $4,550,000 44 Non -waterfront lots (ave. 0.58 ac.) $ 85,000 each = $3,740,000 13 Non -waterfront lots (ave. 0.67 ac.) $100,000 each = $1,300,000 PM 141 Total number of lots lost, with a combined value of: $11,515,000 For this economic analysis, it is assumed the annual lot sales for Alternative No. 3 will be 32 lots per year, for years 0 and 1, and 19 lots for year 2. The lot sales for Alternative No. 7 are assumed to be 32 per year for years 0 through 6, meaning Alternative No. 3 creates 13 lost opportunity lots in year 2, and 32 lost opportunity lots in each year 3 through 6, for a total of 141 lost opportunity lots. 1W Operation and Maintenance Costs The annual power costs are estimated as follows: Annual power cost for a single family septic system (LPP or pump to conventional nitrification lines) with effluent pump: �+ Design pump rate: 480 GPD, pumped at 30 gpm = 16 minutes per day run time TDH: Will vary with location and separation distance of the pump and the disposal field. Assume 1 BHP required when operating. P" Brake horsepower required: 1.0 BHP KW input to motor: 0.87 KW (85% motor efficiency) Operating time: 16 minutes = 0.27 hours/day MR Power consumption per day: 0.87 KW x 0.27 hours per day= 0.235 kWH per day Power consumption per year: = 85.8 kWH per year MR Power costs per year ($.10/kWH) = $8.58 per house times 50 houses assumed to have pumped systems, or $429 per year pq MR Appendix A Page 6 0" OR F=, MR PW Equipment Repair/Replacement: Assume 15 year life for pumps and motors, and calculate the annual equipment charge based on a Sinking Fund Factor (A/F, 7%, 15 years) of 0.0398. This factor times an effluent pump costs of $650 and 50 lots, yields an annual replacement charge of $1,294. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 650 times 50 lots = $ 1,294 Maintenance at 5.0% of $ 32,500 = 1,62 Total annual equipment replacement/repair charge = $ 21919 Solids Removal and Disposal: Septic tanks are assumed to require pumping once every five years at a cost of $200 per pump -out. It is assumed the lots will be developed over a three-year period. The solids removal/disposal costs for this Alternative are summarized as follows: ` n Pump out of residential septic system: 28 tanks x $200 $ 5,600 in years 5, 10, 15, etc. MR 28 tanks x $200 $ 5,600 in years 6, 11, 16, etc. 27 tanks x $200 $ 5,400 in years 7, 12, 17, etc. P., Summary of the annual O&M costs for Alternative No. 3: Annual power costs $ 429 Equipment repair / replacement 2,919 Sub Total Annual O&M Costs $ 3,348 In addition to the sub -total listed above, there is a Solids Removal and Disposal cost that will be included in the economic analysis to reflect cleaning of the tanks once every five years. Present Worth Analysis PW Based on an average market absorption rate of approximately 32 lots per year, the 83 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-2. The cost of the 141 lost opportunity lots will be applied at a rate of 13 lots in year 2, and 32 lots in years 3-6. The calculated annual power costs are dependent on the number of pump FW systems in place, and will be prorated for the first three years as the development is built out. No MR Appendix A Page 7 fXf MR Year 0 Costs Wastewater System Construction (32/83 of $383,250) $ 147,759 Infrastructure Costs for 32 Lots (32/83 of $4,238,388) $ 1,634,077 f� (No O&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $ 1,781,836 f#1 Year 1 Costs Wastewater System Construction (32/83 of $383,250) $ 147,759 MRWastewater Costs for 32 Lots (32/83 of $4,238,388) $ 1,634,077 Annual O&M Costs: Annual power costs (prorated) $ 165 Equipment repair / replacement t 2 919 Total Annual O&M Costs for Year 1: 3 084 Total Year 1 Costs $1,784,920 M, Year 2 Costs Wastewater System Construction (19/83 of $383,250) $ 87,732 Infrastructure Costs for 19 Lots (19/83 of $4,238,388) $ 970,233 Lost opportunity costs of 13 lots (13/141 of $11,515,000) $1,061,667 Annual 0&M Costs: Annual power costs (prorated) $ 331 Equipment repair / replacement $2,919 Total Annual O&M Costs for Year 2: 3,250 Total Year 2 Costs $2,122,882 F" Year 3 Costs Lost opportunity costs of 32 lots (32/141 of $11,515,000) $2,613,333 Annual O&M Costs: Annual power costs $ 429 Equipment repair / replacement 2 917 Total Annual O&M Costs for Year 3: 3,348 Total Year 3 Costs $2,616,681 I" f" Year 4 Costs Identical to Year 3: $2,616,681 Year 5 (and Year 6) Costs Identical to Year 4, with the addition of solids removal/disposal costs $5,600: $2,622,281 Appendix A Page 8 Pon Years 7, 12, 17, 22, and 27 Costs Annual O&M Costs: Annual power costs $ 429 Equipment repair / replacement $2,919 Total Annual O&M Costs: $3,348 Solids Removal/Disposal Costs: 5 400 Total Costs for Years 7, 12, 17, 22, & 27: $8,748 Years 8-9, 13-144 18-19, 23-24, 28 and 29 Costs Annual O&M Costs: Annual power costs $ 429 Equipment repair / replacement $2,919 Total Annual O&M Costs: $3,348 Total Costs for Years 8-9, 13-14, 18-19, 23-24, 28 and 29: $3,348 Mq Years 10, 15, 20, 25, and 30 Costs Annual O&M Costs: Annual power costs $ 429 MR Equipment repair / replacement $2,919 Total Annual O&M Costs: $3,348 Solids Removal/Disposal Costs: 5 600 Total Costs for Years 10, 15, 20, 25, & 30: $8,948 Years 11, 16, 21, and 26 Costs Annual O&M Costs: Annual power costs $ 429 Equipment repair / replacement $2,919 Total Annual O&M Costs: $3,348 Solids Removal/Disposal Costs: 5 600 Total Costs for Years 11, 16, 21, & 26: $8,948 ram MR FM IM fm The present worth for Alternative No. 3 is presented in Table 3-13 below. Appendix A Page 9 FOR PSI FOR FM MIR FER F" ," MR F" F, m" fwR P" pq Fm Table 3-13 Present Worth of Alternative No. 3 Year Total Annual Cost PIF, 7%, n Present Worth 0 $1,781,836 1.0000 $19781,836 1 $1,784,920 0.9346 $1,668,150 2 $2,122, 882 0.8734 $1, 854, 207 3 $2,616,681 0.8163 $2,135,991 4 $29616,681 0.7629 $1,9969253 5 $2,622,281 0.7130 $19869,650 6 $2,622,281 0.6663 $197479337 7 $89748 0.6227 $5,448 8 $3,348 0.5820 $1, 949 9 $3,348 0.5439 $19821 10 $89948 0.5083 $4, 549 11 $8,948 0.4751 $4,251 12 $8,748 0.4440 $3,884 13 $3,348 0.4150 $1,389 14 $3,348 0.3878 $1,298 15 $89948 0.3624 $3,243 16 $8,948 0.3387 $3,031 17 $8,748 0.3166 $2,769 18 $3,348 0.2959 $991 19 $3,348 0.2765 $926 20 $8,948 0.2584 $2,312 21 $89948 0.2415 $2,161 22 $89748 0.2257 $1, 975 23 $3,348 0.2109 $706 24 $39348 0.1971 $660 25 $89948 0.1842 $1,649 26 $8,948 0.1722 $1, 541 27 $8,748 0.1609 $1,408 28 $3,348 0.1504 $504 29 $3,348 0.1406 $471 30 $8,948 0.1314 $19175 Present Worth of Alternative No. 3 $13,1039534 Appendix A Page 10 FOR M ALTERNATIVE NO.4 WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH DISPOSAL THROUGH CONVENTIONAL NITRIFICATION LINES IN A COMMUNITY SYSTEM This Alternative utilizes a central treatment system consisting of a package treatment plant to achieve secondary treatment and disinfection. The individual lots can be smaller than 30,000 square feet and are not required to contain any suitable soils because there will be no septic systems on the lots created under this Alternative. All wastewater will be collected by a pressure sewer system (each house will have an individual grinder pump system) and Mn delivered to the proposed Lissara Wastewater Treatment Plant. The treated effluent from the plant will be pumped from an effluent holding tank into the nitrification fields proposed in several different areas of the subdivision. Flow will be directed to each of the ten nitrification MM fields by solenoid valves and an irrigation -style valve control system. rM The treatment system proposed for this Alternative is an extended aeration style package plant, which will be located within the Lissara subdivision. The areas of soils suitable for use for subsurface disposal of effluent were identified and mapped by Soil & Environmental Consultants, P.A. A copy of their report is included in Appendix D The Long Term Acceptance Rates (LTAR) for the soils identified as suitable for subsurface disposal using conventional nitrification trenches is estimated to be 0.30 gallons per day per square foot of trench bottom. An illustration of this Alternative is presented in Figure No. 4. MR This Alternative was developed on the concept of maximizing the number of lots developed while leaving sufficient suitable soils areas for the nitrification lines and the required 100% repair areas. The estimated wastewater flow for this Alternative is 59,520 gal/day, based on `M 124 four bedroom houses @ 480 gal/day. Alternative No. 4 uses 38.26 acres of the 74.67 acres of usable soils for nitrification fields and repair areas. The difference in areas, 36.41 acres, is used for lots, associated street rights -of - way, and required setbacks from property line, streams, and lakes. Some of this acreage used for the lots must be taken from the usable soils, due to the location of the soils relative to the site access locations and other site features. The remaining site acreage, mainly unsuitable soils, is not used as the maximum number of lots possible with the available soils has been created. Capacity is calculated as follows: (Area in acres) x (43,560 sf per ac.) / (2 for the nitrification field and repair areas / (1.4 for fam the layout inefficiencies) / (9 ft. trench spacing) x (3 ft. trench width) x LTAR = Capacity in gal/day 'R For this alternative: (38.26 acres x 43,560 sf/acre)/2 (repair)/1.4 (layout ineff.)/(9 feet trench spacing) x 3 feet trench width x 0.30 gpd/sf (LTAR) IM = 59,520 gal/day P" Appendix A Page 11 COLOR SHADING KEY LAKE, STREAM OR OPEN WATER 50' BUFFER ON STREAMS 0 HAUSER SR 1175 TREVOR PRIVATE WWTP GRAPHIC SCALE (IN FT -FT ) 1 iiicli = 600 a. FIGURE No. 4 G� WASTEWATER TREATMENT PLANT WITH DISPOSAL THROUGH CONVENTIONAL NITRIFICATION LINES IN A COMMUNITY SYSTEM P" P" The components of this system and their estimated installed cost are as follows: One 59,520 GPD extended aeration package plant IM with ultraviolet disinfection system, installed (no tertiary filters) $ 176,351 Excavation and construction of concrete base slab $ 42,685 One 30 kW standby generator and automatic transfer switch, installed $ 24,800 66,134 LF of nitrification trenches at $7.00/1-17 $ 462,938 Duplex effluent pumps and control panel, including automatic valve sequencer to rotate nitrification fields being dosed $ 38,000 Ten pressure manifolds for flow distribution at $4,000/each $ 40,000 Ten solenoid zone valve stations at $750 each $ 71500 50,490 LF of 3" PVC supply lines from manifolds to nitrification lines at $2.00/1-F (common trench) $ 100,980 10,150 LF of 6" PVC force main from effluent pumps to pressure manifolds at $14.00/1-F $ 142,100 One automatic dialer, installed $ 31000 Erosion control, clearing, landscaping, seeding, etc. (20.1 acres at $5,000/ac.) $ 100,500 'M Electrical Construction $ 90,935 Subtotal, Estimated Construction Cost $ 1,229,789 Soil Scientist Fees (5%) $ 61,489 Engineering Fees (7%) $ 86,085 rM Total Estimated Wastewater Treatment and Disposal Costs $ 1,377,364 W Other Costs/Savings MR Under this Alternative there would be less infrastructure construction required than under the surface discharge Alternative No. 7 because there would be fewer lots developed. The infrastructure unit cost factor developed in Appendix C is $344 per linear foot of street constructed. This - cost includes all land clearing, grading, erosion control, storm drainage, water mains, valves, fire hydrants, paving, curb & gutter, turn lane construction on existing road, engineering, and surveying. Alternative No. 4 has 14,893 LF of street. The only items not included in the unit cost factor are the individual grinder pump station for each lot, the water service for each lot, and the pressure sewer mains. These costs vary depending upon the number of lots developed, and are therefore calculated separately for each Alternative. The infrastructure costs for Alternative No. 4 are: $344/1-17 of street x 14,893 LF of streets $5,123,192 Water services: 124 x $700 each $86,800 Grinder pump station on each lot, installed: 124 at $5,500 each $682,000 Appendix A Page 13 R" Pressure Sewer: 61800 LF of 2 inch at $6.50/LF $44,200 71650 LF of 3 inch at $9.75/LF $74,588 200 LF of 4 inch at $13.00/LF 2 600 Total Infrastructure Cost $6,0131380 Lost opportunity cost due to developing 124 lots in lieu of the 224 lots possible under the treatment plant/surface discharge Alternative: Alternative No. 7, the treatment plant with surface water discharge has the following number and types of lots: 32 Waterfront lots, sale price of: $137,500 each 70 Garden home lots, sale price of: $ 65,000 each 44 Non -waterfront lots (ave. 0.58 ac.), sale price of: $ 85,000 each 78 Non -waterfront lots (ave. 0.67 ac.), sale price of: $100,000 each 224 Total number of lots Alternative No. 4 has the following number and types of lots: 29 Waterfront lots 37 Garden home lots 18 Non -waterfront lots (ave. 0.58 ac.) 40 Non -waterfront lots (ave. 0.67 ac.) 124 Total number of lots The lost opportunity lot cost for Alternative No. 4 is: 3 Waterfront lots at: $137,500 each = $412,500 33 Garden home lots at: $ 65,000 each = $2,145,000 26 Non -waterfront lots (ave. 0.58 ac.) $ 85,000 each = $2,210,000 38 Non -waterfront lots (ave. 0.67 ac.) $100,000 each = $3,800,000 100 Total number of lots lost, with a combined value of: $8,567,500 For this economic analysis, it is assumed the annual lot sales for Alternative No. 4 will be 32 lots per year, for years 0, 1, 2, and 28 lots for year 3. The lot sales for Alternative No. 7, the treatment plant with a discharge to surface waters, will be assumed to be 32 per year for years 0 through 6, thereby creating four lost opportunity lots in year 3, and 32 lost opportunity lots in each year 4 through 6. Appendix A Page 14 MW FM GQeration and Maintenance Costs The annual power costs are estimated as follows: Annual power cost for a single family grinder pump station: Design pump rate: 480 GPD x 2.5 peaking factor x 1 day/1440 minutes < 1 GPM, use 11 GPM due to nominal capacity of grinder pump TDH: Will vary due to location of station and number of pumps in operation in system. Assume 1 BHP required when operating. Brake horsepower required: 1.0 BHP KW input to motor: 0.87 KW (85% motor efficiency) Operating time: 480 gpd/11 gpm = 43.6 minutes = 0.73 hours/day Power consumption per day: 0.87 KW x 0.73 hours per day= 0.635 kWH per day Power consumption per year: = 233 kWH per year Power costs per year ($.10/kWH) _ $23.30 per house, or $2,889 for 124 houses Flow equalization pumps: Design pump rate: 55 GPM TDH: Static head varies: maximum is 12 feet plus friction losses of 2 feet = 14 feet Due to recycle of excess flow, pump will run an average of 18 hours per day Brake horsepower required: 0.32 BHP (60% efficiency) KW input to motor: 0.28 kW (85% motor efficiency) fan Power consumption per year: 0.28 kW x 18 hours per day x 365 days per year = 1,840 kWH per year fm Power costs per year = $184 Flow Equalization Blower: Design flow rate: 27 CFM at 4.5 PSIG Blower horsepower: 1.1 BHP KW input to motor: 1.0 kW (85% motor efficiency) Equalization blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 1.0 kW x 18 hours per day x 365 days per year = 6,570 kWH per year I" Power costs per year = $657 Sludge Blower Design flow rate: 72 CFM at 4.5 PSIG Blower horsepower: 2:3--BHP KW input to motor: 2.0 kW (85% motor efficiency) Appendix A Page 15 I" �+ Sludge blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 2.0 kW x 18 hours per day x 365 days per year = 13,140 kWH per year Power costs per year = $1,314 Main Plant Blower: Design flow rate: 280 CFM at 4.5 PSIG Blower horsepower: 7.1 BHP kW input to motor: 6.2 kW (85% motor efficiency) �+ Main plant blower typically cycled by time clock; this analysis will assume worst case, i.e. 100% operation. Power consumption per year: 6.2 KW x 24 hours per day x 365 days per year = 54,312 kWH per year I" f" M" W M go OW Power costs per year = $5,431 Ultra -violet Disinfection System: Power consumption = 0.54 kW Power consumption per year = 4,730 kWH Power costs per year = $473 Duplex effluent pumps: 59,520 gal per day/240 gal per min = 248 min pumping per day = 4.13 hours per day TDH estimated at 80 feet (varies depending on zone being dosed) Brake horsepower required: 8.1 BHP (60% efficiency) KW input to motor: 7.1 KW (85% motor efficiency) Power consumption per day: 7.1 KW x 4.1 hours per day = 29.1 kWH per day Power consumption per year = 10,625 kWH per year Power costs per year = $1,062 Summary of annual power costs: Grinder Pumps — all lots $2,889 Flow equalization pumps $ 184 Flow equalization blower $ 657 Sludge blower $ 1,314 Main. plant blowers $ 5,431 Ultra -violet disinfection $ 473 Duplex Effluent Pumps 1062 Total Annual Power Costs $12,010 Appendix A Page 16 FER P" Z2 Lab Analyses: For the purposes of this report, the following tests and testing frequencies will be used: Test Cost Frequency Annual Cost BOD-5 $22 Weekly $ 1,144 NH3-N 17 Weekly 884 TSS $13 Weekly $ 676 Fecal Coliform 18 Weekly 936 Total N $32 Quarterly $ 128 Total P 16 Quarterly $64 Conductivity $12 Weekly 780 Annual Testing Costs 1 $ 4 612 Annual solids (sludge) disposal cost: Sludge production rate for extended aeration is estimated to be 2,000 Ibs of dry solids per million gallons treated. Sludge digestion/holding tank will allow thickening to 3% solids concentration. 2,000 Ibs/M.G. x 0.059 MG/Day x 365 Days/Year = 43,070 Ibs, dry solids per year = 172,349 gallons/year at 3% solids Contract disposal to application site, including stabilization, at $.10 per gallon = $17,235 Equipment Repair/Replacement: Assume 15 year life for pumps, motors, and generator, yielding an annual replacement charge of $5,015. This is based on a Sinking Fund Factor (A/F, 7%, 15 years) of 0.0398, times the equipment cost of $126,000. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 126,000 = $ 5,015 Maintenance at 5.0% of $ 126,000 = 6.300 ~' Total annual equipment replacement/repair charge $ 11,315 ON WO Fuel Costs: Based on 52 hours per year run time for exercise and power outages, for the 30 kW standby power generator. Fuel consumption is 180 cubic feet per hour of propane (equal to approximately 5 gallons of LP). 52 hours x 5.0 gal./hr LP at $2.47 per gal. _ $ 642 Total = $ 642 Appendix A Page 17 PR Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the plant and file all required reports. Annual Fee: $45,000 Summary of the annual O&M costs for Alternative No. 4: Annual power costs Annual testing cost Sludge disposal Equipment repair / replacement Fuel Costs Licensed contract operations cost Total Annual 0&M Costs M Present Worth Analysis $ 12,010 $ 4,612 $ 17,235 $ 11,315 $ 642 45,000 $ 90,814 Based on an average market absorption rate of approximately 32 lots per year, the 124 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-3. The cost of the 100 lost opportunity lots will be applied at a rate of 4 lots in year 3, and 32 lots in each year 4-6. The wastewater treatment and disposal system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first four years of operation, until the development is built out. Year 0 Costs Wastewater Treatment and Disposal System Construction $ 1,377,364 "M Infrastructure Costs for 32 Lots (32/124 of $6,013,380) $ 1,551,840 (No O&M cost in year 0 — facilities and houses constructed) f" Total Year 0 Cost MR Year 1 Costs Infrastructure Costs for 32 Lots (32/124 of $6,013,380) Annual O&M Costs: Annual power costs (prorated) $ 9,079 Annual testing cost $ 4 612 Sludge disposal (prorated) $ 4,448 Equipment repair/replacement $ 11,315 Fuel Costs $ 642 Licensed contract operations cost 45 000 FM Appendix A Page 18 $ 2,9291204 $ 1,5511840 PM IM Total Annual O&M Costs for Year 1: Total Year 1 Costs Year 2 Costs Infrastructure Costs for 32 Lots (32/124 of $6,013,380) Annual O&M Costs: Annual power costs (prorated) $ 10,098 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 8,895 Equipment repair/replacement $ 11,315 Fuel Costs $ 642 Licensed contract operations cost $45,000 Total Annual 0&M Costs for Year 2: Total Year 2 Costs Year 3 Costs Infrastructure Costs for 28 Lots (28/124 of $6,013,380) Lost opportunity costs of 4 lots (4/100 of $8,567,500) Annual O&M Costs: Annual power costs (prorated) $ 11,118 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 13,342 Equipment repair / replacement $ 11,315 Fuel Costs $ 642 Licensed contract operations cost $45,000 FMM Total Annual O&M Costs for Year 3: 0" Total Year 3 Costs Year 4, 5, and 6 Costs �+ Lost opportunity costs of 32 lots (32/100 of $8,567,500) Annual O&M Costs: Annual power costs $ 12,010 Annual testing cost $ 4,612 Sludge disposal $ 17,235 Equipment repair / replacement $ 11,315 Fuel Costs $ 642 Licensed contract operations cost $45,000 Total Annual O&M Costs Total Year 4, 5, and 6 Costs — (Each year) Appendix A Page 19 75 096 $1,626,936 $ 1,551,840 80 562 $1,632,402 $1,357,860 $ 342,700 86 029 $1,786,589 $2,741,600 90,814 $2,832,414 P" Year 7 through year 30 Costs (24 years) Total Annual O&M Costs OR Total Year 7 through year 30 Costs — (Each Year) The present worth for Alternative No. 4 is presented in Table 4-A below. fm f" P" P" MR m PM W F" P" F" F" aw m" Appendix A Page 20 $ 90,814 $ 90,814 P" A" MR Pq pq P- PM Ow m" an PSI "M mm an No Table 4-A Present Worth of Alternative No. 4 Year Total Annual Cost P/F, 7%, n Present Worth 0 $2,929,204 1.0000 $2,929,204 1 $1,626,936 0.9346 $1,520,501 2 $1,632,402 0.8734 $1,425, 803 3 $1,786,589 0.8163 $1,458,389 4 $2,8329414 0.7629 $2,160,835 5 $21832,414 0.7130 $2, 019,472 6 $2, 832,414 0.6663 $1, 887, 357 7 $90,814 0.6227 $56,554 8 $90,814 0.5820 $52,855 9 $90,814 0.5439 $49,397 10 $90,814 0.5083 $469165 11 $909814 0.4751 $43,145 12 $90,814 0.4440 $40, 323 13 $90,814 0.4150 $37,685 14 $90,814 0.3878 $35,219 15 $90,814 0.3624 $32,915 16 $909814 0.3387 $30,762 17 $90,814 0.3166 $28,749 18 $909814 0.2959 $26,869 19 $90,814 0.2765 $25,111 20 $90,814 0.2584 $23,468 21 $90,814 0.2415 $21,933 22 $90,814 0.2257 $20,498 23 $90,814 0.2109 $19,157 24 $90,814 0.1971 $179904 25 $909814 0.1842 $169732 26 $90,814 0.1722 $15,638 27 $909814 0.1609 $14,615 28 $90,814 0.1504 $13,659 29 $90,814 0.1406 $12,765 30 $90,814 0.1314 $11%930 Present Worth of Alternative No. 4 $14,095,607 Appendix A Page 21 P" I, ALTERNATIVE NO. 5 WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, Ow WITH DISPOSAL THROUGH DRIP IRRIGATION LINES (SURFACE APPLIED) M, In this scenario, the collected wastewater is treated and disinfected in a package treatment plant, stored in a lagoon, and then applied on the land surface. Drip irrigation tubing with constant output emitters system is used to evenly distribute the treated wastewater on the MR application areas. This system allows a slightly higher lot count than conventional spray due to the improved layout efficiency and decreased setbacks from property lines. As with a conventional spray irrigation system, the wastewater cannot be applied when there is a chance of runoff, such as when the ground is saturated by rainfall. To address this problem a storage lagoon is required to provide the storage volume required to meet the demands of a wetter than average winter. For this Alternative, the stored wastewater must be filtered prior to being pumped into the drip tubing, as the drip irrigation emitters are much smaller than those found in conventional sprinkler nozzles. A filtering system mounted on an equipment skid is typically provided as a part of the drip irrigation equipment package. MR The Soil Scientist's report in Appendix D identified the soils that are suitable for surface application of treated wastewater. The location of these soils and their soil series are illustrated on Figure 5-A. The area of each soil unit proposed for irrigation and the recommended application rates are presented in Table No. 5-A. Based on this information and the available area of each soil unit, a total of 168 lots can be developed under this Alternative with sufficient area left for drip irrigation of the treated effluent. See Figure 5-B for the preliminary subdivision plan for this Alternative. The estimated flow for this Alternative is 80,640 gallons per day, using the same flow factors as used in the previous Alternatives: 168 houses @ 480 gpd average = 80,640 gpd P" Total Wastewater Capacity of indicated soil = 80,762 gal/day ", FM MM The design flow for this Alternative is 80,640 gpd. The drip irrigation area utilizes 52.27 acres, based on a layout inefficiency factor of 1.1. The layout inefficiency is due to topography, shape of suitable soil areas and setback requirements. Appendix A Page 22 LEGEND HAUSER SR 1175 TREVOR PRIVATE pED UNIT: l^iL\^iIL-PACVLL T -I IIWASSLE ORANGE UNIT: WILKES-WYNOTT GREEN UNIT: IREDELL PINK UNIT: CONGAREE BLUE UNIT: ALTAVISTA rol GRAPHIC SCALE 600 0 300 600 1200 ( IN FEET ) 1 inch = 600 ft. ti fiWE 'G °P� FIGURE No. 5-A SOILS SUITABLE FOR SURFACE APPLICATION COLOR SHADING KEY LAKE, STREAM OR OPEN WATER 50' BUFFER ON STREAMS was �vo7� 00 0 1W i HAUSER SR 1175 I TREVOR PRIVATE 0 ka c�Ov �av�v vac ►�i�►. ti1� 1rl�y e.r irY.r� pq WET WEATHER STORAGE WWTP GRAPHIC SCALE 600 0 300 600 1200 ( IN FEET } 1 inch = 600 ft. 0 0P� FIGURE No. 5-B „� WASTEWATER TREATMENT PLANT WITH DISPOSAL THROUGH DRIP IRRRIGATION LINES (SURFACE APPLIED) aq on M" PM F" MR M" F" MR M MR TABLE NO. S-A CAPACITY OF SOILS USED FOR SURFACE DRIP IRRIGATION SYSTEM Soil Unit Area, in Acres LTAR, in in/yr Capacity, in GPD Cecil-Pacolet- Hiwassee 34.65 25 58,590 Wilkes-Wynott 4.92 15 41992 Congaree 9.62 20 13,014 Altavista 3.08 20 41166 Total 52.27 80,762 Alternative No. 5 uses 52.27 acres of the 167.87 acres of usable soils for drip irrigation fields (capacity of 80,762 gpd). A total of 115.60 acres will be used for lots, streets, setbacks, a recreational lake, and the wastewater treatment plant and effluent storage pond area. Some of this acreage used for the lots must be taken from the usable soils, due to the location of the soils relative to the site access locations. The remaining 52.27 acres are used for effluent irrigation to create the maximum number of lots possible. Capacity is calculated as follows: (Areas, in acres) x (43,560 sf per ac.) / (1.1 (layout inefficiency)) x (LTAR) / (12 in. per foot) / (365 days per year) x (7.48 gallons per CF) = Capacity in gal/day The wastewater system components for this Alternative include: One 80,640 GPD extended aeration package plant with ultraviolet disinfection system, and effluent pump station (no filters), installed $ Excavation and construction of concrete base slab $ One 60 kW standby generator and automatic transfer switch, installed $ One lined lagoon (71 days storage, per DWQ Water Balance spreadsheet) with bottom dimensions of 156 Ft x 312 Ft, 3:1 side slopes, 12 foot maximum water level, two feet of freeboard, one foot minimum below required storage volume: 21,425 CY cut to fill at $3.50/CY $ 99,792 SF of 30 mil HDPE liner at $1.55/SF installed $ Drip irrigation system including 1,034,946 LF dripper line, 44 zone valves, 11 return flush valves, supply & return piping, irrigation pump system, pump house, computer controller, 320,110 57,832 37,086 • 154,678 control wiring, electrical, etc. $ 1,772,840 Appendix A Page 25 Electrical Construction $ 168,200 11600 LF of six ft. chain link fence for lagoon and treatment plant area at $12.00/1-F $ 19,200 11,200 LF of barbed wire fencing for application area at $3.50/LF $ 39,200 Erosion control, clearing, landscaping, seeding, etc. (5.3 acres at $5,000/ac.) $ 26,500 Subtotal, Estimated Construction Cost $ 2,670,634 Soil Scientist Fees (5%) $ 133,532 Engineering Fees (7%) $ 186,944 Total Estimated Project Cost $ 2,991,110 MR Other Costs/Savings Under this Alternative there is less infrastructure construction required than under the surface MR discharge Alternative because there are fewer lots developed. The infrastructure unit cost developed in Appendix C is $344 per linear foot of street constructed. This cost includes all land clearing, grading, erosion control, storm drainage, water mains, valves, fire hydrants, paving, curb & gutter, turn lane construction on existing road, engineering, and surveying. Alternative No. 5 has 12,515 LF of street. The only items not included in this unit cost factor are the individual grinder pump station for each lot, the water service for each lot, and the pressure sewer mains. These costs vary depending upon the number of lots developed, and are therefore calculated separately for each Alternative. The infrastructure costs for Alternative No. 5 are: $344/LF of street x 12,515 LF of streets $4,305,160 Water services: 168 x $700 each $117 600 Grinder pump station on each lot, installed: 168 at $5,500 each $924,000 Pressure Sewer: 4,800 LF of 2 inch at $6.50/LF $31,200 7,100 LF of 3 inch at $9.75/1-F $69,225 500 LF of 4 inch at $13.00/LF 6 500 MR Total Infrastructure Cost $5,453,685 IM The lost opportunity cost due to developing 168 lots in lieu of the 224 lots possible under the treatment plant/surface discharge Alternative is calculated as follows: FM Alternative No. 7, the treatment plant with surface water discharge has the following number and types of lots: MR Appendix A No Page 26 P" 32 Waterfront lots, sale price of: $137,500 each 70 Garden home lots, sale price of: $ 65,000 each 44 Non -waterfront lots (ave. 0.58 ac.), sale price of: $ 85,000 each 78 Non -waterfront lots (ave. 0.67 ac.), sale price of: $100,000 each "M 224 Total number of lots R" Alternative No. 5 has the following number and types of lots: 32 Waterfront lots FM 70 Garden home lots 44 Non -waterfront lots (ave. 0.58 ac.) 22 Non -waterfront lots (ave. 0.67 ac.) MR 168 Total number of lots FM The lost opportunity cost for Alternative No. 5 is: 56 Non -waterfront lots (ave. 0.67 ac.) $100,000 each = $5,600,000 I, For this economic analysis, it is assumed the annual lot sales for Alternative No. 5 will be 32 Im lots per year, for years 0, 1, 2, 3, and 4, and 8 lots for year 5. The lot sales for Alternative No. 7, the treatment plant with a discharge to surface waters, is assumed to be 32 per year for years 0 through 6, thereby creating 24 lost opportunity lots in year 5, and 32 lost lots in year 6 ,M for Alternative No. 5. ram MR No MR Operation and Maintenance Costs The annual power costs are estimated as follows: Annual power cost for a single family grinder pump station: Design pump rate: 480 GPD x 2.5 peaking factor x 1 day/1440 minutes < 1 GPM, use 11 GPM due to nominal capacity of grinder pump TDH: Will vary due to location of station and number of pumps in operation in system. Assume 1 BHP required when operating. Brake horsepower required: 1.0 BHP KW input to motor: 0.87 KW (85% motor efficiency) Operating time: 480 gpd/11 gpm = 43.6 minutes = 0.73 hours/day Power consumption per day: 0.87 KW x 0.73 hours per day= 0.635 kWH per day Power consumption per year: = 233 kWH per year Power costs per year ($.10/kWH) _ $23.30 per house, or $3,914 for 168 houses Appendix A Page 27 Om �., Flow Equalization pumps: Design pump rate: 75 GPM TDH: Static head varies:_ maximum is 12 feet plus friction losses of 2 feet = 14 feet Due to recycle of excess flow, pump will run an average of 18 hours per day Brake horsepower required: 0.44 BHP (60% efficiency) KW input to motor: 0.39 kW (85% motor efficiency) Power consumption per year: 0.39 kW x 18 hours per day x 365 days per year = 2,562 kWH per year Power costs per year = $256 WR Flow Equalization Blower: Design flow rate: 36 CFM at 4.5 PSIG Blower horsepower: 1.52 BHP KW input to motor: 1.33 kW (85% motor efficiency) Equalization blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 1.33 kW x 18 hours per day x 365 days per year = 81738 kWH per year Power costs per year = $874 RM Sludge Blower Design flow rate: 98 CFM at 4.5 PSIG Blower horsepower: 3.2 BHP KW input to motor: 2.8 kW (85% motor efficiency) Sludge blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 2.8 kW x 18 hours per day x 365 days per year = 181,396 kWH per year OUR Power costs per year = $1,840 Mol Main Plant Blower: Design flow rate: 380 CFM at 4.5 PSIG Blower horsepower: 9.6 BHP fm kW input to motor: 8.4 kW (85% motor efficiency) Main plant blower typically cycled by time clock; this analysis will assume worst case, i.e. 100% operation. Power consumption per year: 8.4 KW x 24 hours per day x 365 days per year = 73,584 kWH per year Power costs per year = $7,358 IM Appendix A Page 28 P" �+ Ultra -violet Disinfection System: Power consumption = 0.74 kW Power consumption per year = 61482 kWH °'' Power costs per year = $648 Drip irrigation pumps: fm 80,640 gal per day x 365 days/200 irrigation days = 147,168 gallons per irrigation day. Pump rate is 116 gpm per zone, or with two zones irrigated F, at one time (232 gpm combined rate). Pump TDH is assumed to be 40 feet for static and friction losses to each zone, plus 81 feet (35 psi) at the inlet end of the drip tubing, or 121 feet for TDH. 147,168 gallons per irrigation day/232 gal per min. = 634 min. pumping per irrigation day, or 10.57 hours per irrigation day. Allow an additional 0.43 hours per day for zone flushing requirements Brake horsepower required: 10.1 BHP (70% efficiency) KW input to motor: 8.86 KW (85% motor efficiency) Power consumption per irrigation day: 8.86 KW x 11.0 hours per day = 97.5 kWH per irrigation day Power consumption per year = 97.5 kWH per irrigation day x 200 irrigation days per year = 19,500 kWH per year Power costs per year = $1,950 Summary of annual power costs: Grinder Pumps — all lots $3,914 Flow equalization pumps $ 256 Flow equalization blower $ 874 Sludge blower $ 1,840 Main plant blowers $ 7,358 Ultra -violet disinfection $ 648 Duplex Effluent Pumps i 950 Total Annual Power Costs $16,840 P, W4 Lab Analyses: For the purposes of this report, the following tests and testing frequencies will be used: Test Cost Frequency Annual Cost BQD-5 $22 Weekly 1,144 NH3-N $17 Weekl 884 TSS 13 Weekly 676 Fecal Coliform $18 Weekly 936 Total N $32 Quarterly $128 Total P $16 Quarterly $ 64 Conductivity $12 Weekly $ 780 Annual Testing Costs $ 4,612 Appendix A Page 29 FEM MR Annual solids (sludge) disposal cost: Sludge production rate for extended aeration is estimated to be 2,000 Ibs of dry solids per million gallons treated. Sludge digestion/holding tank will allow thickening to 3% solids concentration. row 2,000 Ibs/M.G. x 0.081 MG/Day x 365 Days/Year IW = 59,130 Ibs dry solids per year = 236,615 gallons/year at 3% solids MR Contract disposal to application site, including stabilization, at $.10 per gallon = $23,662 Equipment Repair/Replacement: Assume 15 year life for pumps, motors, and generator, yielding an annual replacement charge of $6,639. This is based on a Sinking Fund Factor (A/F., 7%, 15 years) of 0.0398, times the equipment cost of $166,800. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 166,800 = $ 6,639 Maintenance at 5.0% of $ 166,800 = 8,340 Total annual equipment replacement/repair charge = $ 14,979 Fuel Costs: Based on 52 hours per year run time for exercise and power outages, for the 60 kW standby power generator. Fuel consumption is 335 cubic feet per hour of propane (equal to approximately 9.3 gallons of LP). 52 hours x 9.3 gal./hr LP at $2.47 per gal. = $ 1,194 Total = $ 1,194 rml Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the plant and file all required reports (assumes drip irrigation areas have low maintenance tree crop cover). W, Annual Fee: Summary of annual O&M costs: pq Annual power costs Annual testing costs Sludge disposal MR Equipment repair/replacement I" Appendix A Page 30 $ 45,000 $ 16,840 $ 4,612 $ 23,662 $ 14,979 MR IM Fuel costs Contract operations Total Annual O&M costs $ 1,194 45,000 $106,287 Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 168 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-5. The cost of the 56 lost opportunity lots will be applied at a rate of 24 lots in year 5, and 32 lots in year 6. The wastewater treatment and disposal system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first five years of operation, until the development is built out. IM Year 0 Costs Wastewater Treatment and Disposal System Construction $2,991,110 PMInfrastructure Costs for 32 Lots (32/168 of $5,453,685) $1,038,797 (No O&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $4,029,907 RM Year 1 Costs Infrastructure Costs for 32 Lots (32/168 of $5,453,685) $1,038,797 FM Annual O&M Costs: Annual power costs (prorated) $ 11,886 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 4,507 Equipment repair/replacement $ 14,979 Fuel Costs $ 11194 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 1: $ 82,178 Total Year 1 Costs $1,120,975 Year 2 Costs Infrastructure Costs for 32 Lots (32/168 of $5,453,685) $1,038,797 Annual O&M Costs: Annual power costs (prorated) $ 13,052 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 9,014 Equipment repair/replacement $ 14,979 Fuel Costs $ 11194 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 2: 87,851 Total Year 2 Costs $1,126,648 Appendix A Am Page 31 P" MR Year 3 Costs Infrastructure Costs for 32 Lots (32/168 of $5,453,685) $1,0381797 OEM Annual O&M Costs: Annual power costs (prorated) $ 14,218 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 13,521 Equipment repair / replacement $ 14,979 Fuel Costs $ 1,194 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 3: $93,524 Total Year 3 Costs $I f132,321 Year 4 Costs Infrastructure Costs for 32 Lots (32/168 of $5,453,685) $1,038,797 Annual O&M Costs: Annual power costs (prorated) $ 15,384 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 18,028 Equipment repair / replacement $ 14,979 Fuel Costs $ 11194 Licensed contract operations cost $45,000 Total Annual O&M Costs $ 99,197 Total Year 4 Costs $1,137,994 Year 5 Costs Infrastructure Costs for 8 Lots (8/168 of $5,453,685) $ . 259,699 Lost opportunity costs of 24 lots (24/56 of $5,600,000) $21400,000 F+ Annual O&M Costs: Annual power costs $ 16,550 Annual testing costs $ 41612 Sludge disposal $ 22,535 Equipment repair/replacement $ 14,979 Fuel costs $ 11194 Contract operations $45,000 Total Annual O&M Costs $ 104,870 Total Year 5 Costs $2,764,569 Appendix A Page 32 Ma Year 6 Costs Lost opportunity costs of 32 lots (32/56 of $5,600,000) $3,200,000 Annual O&M Costs: Annual power costs $ 16,840 Annual testing costs $ 41612 Sludge disposal $ 23,662 Equipment repair/replacement $ 14,979 Fuel costs $ 11194 Contract operations 45 000 Total Annual O&M Costs $ 106,287 Total Year 6 Costs $3,306,287 Year 7 through year 30 Costs (24 years) Total Annual O&M Costs $ 106,287 Total Year 7 through year 30 Costs, (Each Year) $ 106,287 The present worth for Alternative No. 5 is presented in Table 5-13 below. I" P" MR W OR f" r" me MW oft Appendix A Page 33 am FM PER MR 00 ON PM P" 0" I" P" P" mm mw F" Pq am Table 5-B Present Worth of Alternative No. 5 Year Total Annual Cost RF, 7%, n Present Worth 0 $4, 029, 907 1.0000 $4, 029, 907 1 $1,120, 975 0.9346 $19047, 640 2 $19126,648 0.8734 $984,058 3 $19132,321 0.8163 $924,311 4 $1,137, 994 0.7629 $868,170 5 $2,7649569 0.7130 $1,971,099 6 $3,306,287 0.6663 $29203,119 7 $106,287 0.6227 $66,190 8 $106,287 0.5820 $61,860 9 $106,287 0.5439 $57,813 10 $106,287 0.5083 $54, 031 11 $106,287 0.4751 $50,496 12 $106,287 0.4440 $47,193 13 $106,287 0.4150 $44,105 14 $106,287 0.3878 $41,220 15 $106,287 0.3624 $389523 16 $106,287 0.3387 $36,003 17 $106,287 0.3166 $33,648 18 $106,287 0.2959 $31,446 19 $106,287 0.2765 $29, 389 20 $106,287 0.2584 $27,467 21 $106,287 0.2415 $25,670 22 $106,287 0.2257 $23,990 23 $106,287 0.2109 $22,421 24 $1061287 0.1971 $20, 954 25 $1069287 0.1842 $19,583 26 $106,287 0.1722 $18, 302 27 $106,287 0.1609 $17,105 28 $106,287 0.1504 $15, 986 29 $106,287 0.1406 $14,940 30 $1069287 0.1314 $13, 963 Present Worth of Alternative No. 5 $12,8409603 Appendix A Page 34 am ALTERNATIVE NO. 6 WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH DISPOSAL THROUGH SPRAY IRRIGATION SYSTEM �► This Alternative utilizes a central treatment system consisting of a wastewater treatment plant to achieve secondary treatment and disinfection. The disinfected wastewater is then surface applied through solid set sprinkler heads to be further treated by the soils. The wastewater cannot be applied when there is a chance of runoff, such as when the ground is saturated by rainfall. To address this problem a storage lagoon is required to provide the storage volume required to meet the demands of a wetter than average winter. The system operator will generally operate the irrigation system in accordance with the calculated water balance to insure the system's storage needs do not exceed the lagoon volume. ON The recommended application rates and tract capacities for the mapped soil units used for irrigation are presented in Table No. 6-A. Based on this information and the available area of each soil unit, a total of 144 lots can be developed under this Alternative. The wastewater flows for this Alternative are: 144 houses @ 480 gpd = 69,120 gal/day Total Wastewater Capacity of indicated soils = 69,211 gal/day The design flow for this Alternative is 69,120 gpd. The spray irrigation area utilizes 47.65 acres, based on a layout inefficiency factor of 1.2. The layout inefficiency is due to �^ topography, shape of suitable soil areas and setback requirements (see Figure No. 6 for the preliminary subdivision plan for this Alternative). M MR M aM am MR TABLE NO.6-A CAPACITY OF SOILS USED FOR SPRAY IRRIGATION SYSTEM Soil Unit Area, in Acres LTAR, in in/yr Capacity, in GPD Cecil-Pacolet- Hiwassee 35.80 25 55,491 Wilkes-Wynott 3.14 15 21920 Congaree 6.56 20 8,134 Altavista 2.15 20 21666 Total 47.65 69,211 Appendix A Page 35 HAUSER SR 1175 TREVOR PRIVATE COLOR SHADING KEY LAKE, STREAM OR OPEN WATER 50' BUFFER ON STREAMS JIM WET WEATHER STORAGE lum W. RAAA�� M1r�WWTp low —i ©G GC► GG�C,—GpAq— ■ ��'� .`rr!7!�� lC�a►i1w>�1r�frr�irlrl�iri��ir�:rita�ll%i:i� GRAPHIC SCALE 600 0 300 600 1200 I ( IN FEET ) 1 inch = 600 ft. 0 FIGURE No. 6 2400 WASTEWATER TREATMENT PLANT WITH DISPOSAL THROUGH SPRAY IRRRIGATION LINES (SURFACE APPLIED) OR a" on No F" im OR 0" "a ow ow Alternative No. 6 uses 47.65 acres of the 167.87 acres of usable soils for spray irrigation fields (capacity of 69,211 gpd). A total of 120.22 acres will be used for lots, associated streets, a recreational lake, and the wastewater treatment plant and effluent storage pond area. Some of this acreage used for the lots must be taken from the usable soils, due to the location of the soils relative to the site access locations. The remaining 47.65 acres are used for effluent irrigation to create the maximum number of lots possible. Capacity is calculated as follows: (Areas, in acres) x (43,560 sf per ac.) / (1.2 (layout inefficiency)) x (LTAR) / (12 in. per year) / (365 days per year) x (7.48 gallons per CF) = Capacity in gal/day The wastewater system components for this Alternative include: One 69,120 GPD extended aeration package plant with ultraviolet disinfection system, installed (no filters) $ 274,380 Excavation and construction of concrete base slab $ 49,570 One 45 KW standby generator and automatic transfer switch, installed $ 30,849 One lined lagoon (60 days storage, per DWQ Water Balance spreadsheet) with bottom dimensions of 125 Ft x 250 Ft, 3:1 side slopes, 12 foot maximum water level, two feet of freeboard, one foot min. below required storage volume: 15,785 CY cut to fill at $4.00/CY $ 63,140 73,300 SF of 40 mil HDPE liner at $1.85/SF installed $ 135,605 Spray irrigation system including: 24 zones with 49 heads per zone (100' grid spacing): 24 x 49 - 1" risers w/nozzles and support pipe at $100/each $ 117,600 24 x (700 LF of 1" PVC pipe per zone) at $3.00/1-17 $ 50,400 24 x (700 LF of 1 1/2" PVC per zone) at $3.60/LF $ 60,480 24 x (700 LF of 2" PVC per zone) at $4.80/LF $ 80,640 24 x (50 LF of 3" PVC per zone) at $7.00/LF $ 8,400 24 x (50 LF of 4" PVC per zone) at $9.50/1-17 $ 11,400 24x (200 LF of 6" PVC per zone) at $14.00/1-17 $ 67,200 5,600 LF of 6" force main from irrigation pump station to the 24 zones at $14.00/LF $ 78,400 24 solenoid zone valve stations at $1,300 each $ 31,200 Irrigation pump station with duplex 500 ' gpm pumps and zone controllers $ 269,733 Appendix A Page 37 ow 1,600 chain link fence at $12.00/1.F (lagoon and plant area) $ 19,200 16,500 LF barbed wire fence at $3.50/1-F me (spray field area) $ 57,750 One automatic dialer $ 31000 Erosion control, clearing, landscaping, seeding, etc. no (16.6 acres at $5,000/ac.) $ 83,000 Electrical $ 119,000 Subtotal, Estimated Construction Cost $1,610,947 Soil Scientist Fees (5%) $ 80,547 Engineering Fees (7%) $ 112,766 Total Estimated Project Cost $1,804,260 Other Costs/Savings �+ Under this Alternative there would be less infrastructure construction required than under the surface discharge Alternative because there would be fewer lots developed. The infrastructure unit cost developed in Appendix C is $344 per linear foot of street constructed. This cost includes all land clearing, grading, erosion control, storm drainage, water mains, valves, fire hydrants, paving, curb & gutter, turn lane construction on existing road, engineering, and surveying. Alternative No. 6 has 12,515 LF of street. The only items not included in the unit cost factor are the individual grinder pump station for each lot, the water service for each lot, and the pressure sewer mains. These costs vary depending upon the number of lots developed, and are therefore calculated separately for each Alternative. The infrastructure costs for Alternative No. 6 are: $344/LF of street x 12,515 LF of streets $4,3051,160 Water services: 144 x $700 each $100,800 Grinder pump station on each lot, installed: 144 at $5,500 each $792,000 Pressure Sewer: 41100 LF of 2 inch at $6.50/LF $26,650 41200 LF of 3 inch at $9.75/LF $40,950 11800 LF of 4 inch at $13.00/LF 23 400 Total Infrastructure Cost $5,288,960 The lost opportunity cost due to developing 144 lots in lieu of the 224 lots possible under the treatment plant/surface discharge Alternative is calculated as follows: Alternative No. 7, the treatment plant with surface water discharge has the following number and types of lots: Appendix A Page 38 MR MR 32 Waterfront lots, sale price of: $137,500 each 70 Garden home lots, sale price of: $ 65,000 each 44 Non -waterfront lots (ave. 0.58 ac.), sale price of: $ 85,000 each 78 Non -waterfront lots (ave. 0.67 ac.), sale price of: $100,000 each 224 Total number of lots Alternative No. 6 has the following number and types of lots: 32 Waterfront lots 70 Garden home lots 42 Non -waterfront lots (ave. 0.58 ac.) 144 Total number of lots The lost opportunity cost for Alternative No. 6 is: �* 2 Non -waterfront lots (ave. 0.58 ac.), $ 85,000 each = $ 170,000 78 Non -waterfront lots (ave. 0.67 ac.) $100,000 each = $ 7,800,000 �+ 80 Total number of lots lost, with a combined value of: $ 7,970,000 For this economic analysis, it is assumed the annual lot sales for Alternative No. 5 will be 32 lots per year, for years 0, 1, 21 3, and 16 lots for year 4. The lot sales for Alternative No. 7, the treatment plant with a discharge to surface waters, is assumed to be 32 per year for years 0 through 6, thereby creating 16 lost opportunity lots in year 4, and 32 lost lots in each year 5 and 6 for Alternative No. 6. am Operation and Maintenance Costs The annual power costs are estimated as follows: Annual power cost for a single family grinder pump station: Design pump rate: +� 480 GPD x 2.5 peaking factor x 1 day/1440 minutes < i GPM, use 11 GPM due to nominal capacity of grinder pump TDH: Will vary due to location of station and number of pumps in operation in system. Assume 1 BHP required when operating. Brake horsepower required: 1.0 BHP KW input to motor: 0.87 KW (85% motor efficiency) Operating time: 480 gpd/11 gpm = 43.6 minutes = 0.73 hours/day Power consumption per day: 0.87 KW x 0.73 hours per day= 0.635 kWH .per day Power consumption per year: = 233 kWH per year ON I" Power costs per year ($.10/kWH) _ $23.30 per house, or $3,355 for 144 houses Appendix A Page 39 P" Flow Equalization pumps: Design pump rate: 64 GPM TDH: Static head varies: maximum is 12 feet plus friction losses of 2 feet = 14 N. feet Due to recycle of excess flow, pump will run an average of 18 hours per day Brake horsepower required: 0.38 BHP (60% efficiency) ON KW input to motor: 0.32 kW (85% motor efficiency) Power consumption per year: 0.32 kW x 18 hours per day x 365 days per year = 2,102 kWH per year Power costs per year = $210 Flow Equalization Blower: Design flow rate: 31 CFM at 4.5 PSIG Blower horsepower: 1.3 BHP KW input to motor: 1.1 kW (85% motor efficiency) Equalization blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 1.1 kW x 18 hours per day x 365 days per year = 7,227 kWH per year Power costs per year = $723 Sludge Blower Design flow rate: 84 CFM at 4.5 PSIG Blower horsepower: 2.7 BHP KW input to motor: 2.3 kW (85% motor efficiency) Sludge blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 2.3 kW x 18 hours per day x 365 days per year = 15,111 kWH per year p, Power costs per year = $1,511 W Main Plant Blower: Design flow rate: 325 CFM at 4.5 PSIG Blower horsepower: 8.2 BHP kW input to motor: 7.2 kW (85% motor efficiency) Main plant blower typically cycled by time clock; this analysis will assume worst case, i.e. 100% operation. Power consumption per year: 7.2 KW x 24 hours per day x 365 days per year = 63,072 kWH per year Power costs per year = $6,307 Appendix A Page 40 F" am Ultra -violet Disinfection System: Power consumption = 0.63 kW Power consumption per year = 51519 kWH "" Power costs per year = $552 Duplex irrigation pumps: 69,120 gal per day x 365 days/200 irrigation days = 126,144 gallons per irrigation day. Pump rate is 10 gpm per sprinkler head, or 490 gpm per zone. Pump TDH is assumed to be 40 feet for static and friction losses to each zone, plus 127 feet (55 psi) at the sprinkler nozzles, or 167 feet for TDH. 126,144 gallons per irrigation day/490 gal per min. = 257 min. pumping per irrigation day, or 4.28 hours per irrigation day Brake horsepower required: 29.52 BHP (70% efficiency) KW input to motor: 25.91 KW (85% motor efficiency) Power consumption per irrigation day: 25.91 KW x 4.28 hours per day = 110.9 kWH per irrigation day Power consumption per year = 110.9 kWH per irrigation day x 200 irrigation days per year = 22,180 kWH per year Power costs per year = $2,218 Summary of annual power costs: Grinder Pumps — all lots $3,355 Flow equalization pumps $ 210 Flow equalization blower $ 723 Sludge blower $ 1,511 Main plant blowers $ 6,307 Ultra -violet disinfection $ 552 Duplex Effluent Pumps 2 218 Total Annual Power Costs $14,876 0" am No am am Lab Analyses: For the purposes of this report, the following tests and testing frequencies will be used: Test Cost Frequency Annual Cost BOD-5 22 Weekly $ 1 144 NH3-N 17 Weekly 884 TSS 13 Weekly $ 676 Fecal Coliform 18 Weekly 936 Total N 32 Quarterly $ 128 Total P 16 Quarterly $64 Conductivity 12 Weekly $ 780 Annual Testing Costs $ 4,612 Appendix A Page 41 P" PM Annual solids (sludge) disposal cost: Sludge production rate for extended aeration is estimated to be 2,000 Ibs of dry solids per million gallons treated. Sludge digestion/holding tank will allow thickening to 3% an solids concentration. 2,000 Ibs/M.G. x 0.069 MG/Day x 365 Days/Year = 50,370 Ibs dry solids per year = 201,561 gallons/year at 3% solids Contract disposal to application site, including stabilization, at $.10 per gallon = $20,156 Equipment Repair/Replacement: Assume 15 year life for pumps, motors, and generator, yielding an annual replacement charge of $5,691. This is based on a Sinking Fund Factor (A/F, 7%, 15 years) of 0.0398, times the equipment cost of $143,000. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 143,000 = $ 51691 Maintenance at 5.0% of $ 143,000 = 7,150 Total annual equipment replacement/repair charge = $ 12,841 Fuel Costs: Based on 52 hours per year run time for exercise and power outages, for the 45 kw standby power generator. Fuel consumption is 252 cubic feet per hour of propane (equal to approximately 7 gallons of LP). ,M 52- hours x 7.0 gal./hr LP at $2.47 per gal. Total Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the plant and file all required reports (assumes spray irrigation areas have low maintenance tree crop cover, or hay fields mowed at no charge in exchange for hay removal). Annual Fee: $45,000 Summary of annual O&M costs for Alternative No. 6: Annual power costs $ 14,876 Annual testing costs $ 41612 Sludge disposal $ 20,156 Equipment repair/replacement $ 12,841 Fuel costs $ 899 Contract operations 45 000 Total Annual O&M costs $ 98,384 Appendix A Page 42 P" am POR P" Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 144 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-4. The cost of the 80 lost opportunity lots will be applied at a rate of 16 lots in year 4, and 32 lots in years 5-6. The wastewater treatment and disposal system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first four years of operation, until the development is built out. Year 0 Costs �., Wastewater Treatment and Disposal System Construction $1,8041260 Infrastructure Costs for 32 Lots (32/144 of $5,288,960) 1 32 175 4 (No 0&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $2,979,584 Year 1 Costs Infrastructure Costs for 32 Lots (32/144 of $5,288,960) $1,175,324 Annual O&M Costs: Annual power costs (prorated) $ 10,541 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 4,479 Equipment repair/replacement $ 12,841 Fuel Costs $ 899 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 1: $ 78,372 Total Year 1 Costs $1,253,696 Year 2 Costs Infrastructure Costs for 32 Lots (32/144 of $5,288,960) $1,175,324 Annual O&M Costs: Annual power costs (prorated) $ 11,780 MR Annual testing cost $ 4,612 Sludge disposal (prorated) $ 8,958 Equipment repair/replacement $ 12,841 Fuel Costs $ 899 Licensed contract operations cost $45,000 Total Annual 0&M Costs for Year 2: 84,090 Total Year 2 Costs $1,259,414 IM No Appendix A Page 43 MI Year 3 Costs Infrastructure Costs for 32 Lots (32/144 of $5,288,960) $1,175,324 Annual 0&M Costs: Annual power costs (prorated) $ 13,018 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 13,437 Equipment repair / replacement $ 12,841 Fuel Costs $ 899 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 3: $89,807 Total Year 3 Costs $1,265,131 Year 4 Costs Infrastructure Costs for 16 Lots (16/144 of $5,288,960) $ 587,662 Lost opportunity costs of 16 lots (16/80 of $7,970,000) $1,594,000 Annual O&M Costs: Annual power costs (prorated) $ 14,257 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 17,916 Equipment repair / replacement $ 12,841 Fuel Costs $ 899 Licensed contract operations cost $45,000 •+ Total Annual O&M Costs $ 95,525 Total Year 4 Costs $2,277,187 Year 5 and 6 Costs Lost opportunity costs of 32 lots (32/80 of $7,970,000) $3,188,000 Annual O&M Costs: Annual power costs $ 14,876 Annual testing costs $ 41612 Sludge disposal $ 20,156 Equipment repair/replacement $ 12,841 Fuel costs $ 899 Contract operations $45,000 �., Total Annual O&M Costs $ 98,384 Total Year 5 and 6 Costs $3,286,384 Year 7 through year 30 Costs (24 years) Total Annual 0&M Costs $ 98,304 Appendix A am Page 44 P" mm Total Year 7 through year 30 Costs.- (Each Year) $ 98,304 P" P" am MR m" R" FW MR m" MR P, No No The present worth for Alternative No. 6 is presented in Table 6-13 below. Table 6-B Present Worth of Alternative No. 6 Year Total Annual Cost P1F, 7%, n Present Worth 0 $2,9791584 1.0000 $2,979,584 1 $1,2539696 0.9346 $1,1719679 2 $1,259,414 0.8734 $1,100,021 3 $1,265,131 0.8163 $1, 032,724 4 $2,277,187 0.7629 $1,737,255 5 $3,2869384 0.7130 $2,343,146 6 $3,286,384 0.6663 $2,189,856 7 $98,304 0.6227 $619219 8 $98,304 0.5820 $57,214 9 $98,304 0.5439 $53,471 10 $98,304 0.5083 $49,973 11 $98,304 0.4751 $469704 12 $98,304 0.4440 $43,648 13 $98,304 0.4150 $40,793 14 $98,304 0.3878 $38,124 15 $98,304 0.3624 $35,630 16 $98,304 0.3387 $33,299 17 $98,304 0.3166 $31,121 18 $98,304 0.2959 $29,085 19 $98,304 0.2765 $27,182 20 $98,304 0.2584 $25,404 21 $989304 0.2415 $23,742 22 $98,304 0.2257 $229189 23 $98,304 0.2109 $20,737 24 $98,304 0.1971 $19,380 25 $98,304 0.1842 $18,112 26 $98,304 0.1722 $16,928 27 $98,304 0.1609 $159820 28 $989304 0.1504 $14,785 29 $98,304 0.1406 $139818 30 $98,304 0.1314 $12,914 Present Worth of Alternative No. 6 $1393059654 Appendix A Page 45 F" M" ALTERNATIVE NO. 7 WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH DISPOSAL THROUGH SURFACE DISCHARGE TO THE YADKIN RIVER Alternative No. 7 utilizes an extended aeration wastewater treatment plant to treat the wastewater to a level that is suitable for discharge to surface waters. This system does not rely on land area for treatment or disposal, thus its area requirements are minimal when �+ compared to the on -site disposal alternatives. Because this option does not require extensive amounts of land, it allows the development of the maximum number of lots permitted by zoning, or 224 lots. See Figure No. 7 for preliminary subdivision plant. A detailed description of the treatment facilities is presented in Section C. of this Engineering Alternatives Analysis. P" The estimated flow for this Alternative is: 224 Houses at 480 gal. per day = 107,520 gpd This Alternative is illustrated in Figure 7. The wastewater treatment system components for this Alternative and their estimated installed costs are as follows: One 107,520 GPD wastewater treatment plant with tertiary filters and ultraviolet disinfection system, installed $ 543,000 rim Excavation and construction of base slabs $ 96,390 One 75 KW standby generator and automatic transfer switch, installed $ 38,300 480 LF of chain line fence at $12.00/LF $ 51760 Discharge pipe to river (1,400 LF at $25/LF) $ 35,000 One automatic dialer $ 3,000 Electrical construction $ 55,287 Erosion control, clearing, landscaping, 5,000 seeding, etc. (1.0 acre at $5,000/ac.) Subtotal, Estimated Construction Cost $ 781,737 �., Soil Scientist Fees $ 0 Engineering Fees (7%) $ 54,722 �+ Total Estimated Project Cost $ 836,459 Other Costs/Savings The infrastructure unit cost developed in Appendix C is $344 per linear foot of street constructed. This cost includes all land clearing, grading, erosion control, storm drainage, water mains, valves, fire hydrants, paving, curb & gutter, turn lane construction on existing road, engineering, and surveying. Alternative No. 7 has 15,351 LF of street. The only items not Appendix A MR Page 46 Wq included in the unit cost factor are the individual grinder pump station for each lot, the water service for each lot, and the pressure sewer mains. These costs vary depending upon the number of lots developed, and are therefore calculated separately for each Alternative. The infrastructure costs for Alternative No. 7 are: $344/1-F of street x 15,351 LF of streets $5,280,744 Water services: 224 x $700 each $1561,800 Grinder pump station on each lot, installed: 224 at $5,500 each $1,2321000 Pressure Sewer: 5,100 LF of 2 inch at $6.50/1-17 $33,150 5,600 LF of 3 inch at $9.75/LF $54,600 4,600 LF of 4 inch at $13.00/1.F $59,800 Total Infrastructure Cost $6,817094 OR Operation and Maintenance Costs The annual power costs are estimated as follows: fW Annual power cost for a single family grinder pump station: Design pump rate: MR 480 GPD x 2.5 peaking factor x 1 day/1440 minutes < 1 GPM, use 11 GPM due to nominal capacity of grinder pump TDH: Will vary due to location of station and number of pumps in operation in FM system. Assume 1 BHP required when operating. Brake horsepower required: 1.0 BHP M, KW input to motor: 0.87 KW (85% motor efficiency) Operating time: 480 gpd/11 gpm = 43.6 minutes = 0.73 hours/day Power consumption per day: 0.87 KW x 0.73 hours per day= 0.635 kWH per day MR Power consumption per year: = 233 kWH per year Power costs per year ($.10/kWH) _ $23.30 per house, or $5,219 for 224 houses Flow equalization pumps: Design pump rate: 100 GPM '^ TDH: Static head varies: maximum is 12 feet plus friction losses of 2 feet = 14 feet Due to recycle of excess flow, pump will run an average of 18 hours per day Brake horsepower required: 0.59 BHP (60% efficiency) KW input to motor: 0.52 kW (85% motor efficiency) Power consumption per year: 0.52 kW x 18 hours per day x 365 days per year = 3,416 kWH per year ,.� Power costs per year = $342 Appendix A ,m Page 47 — —Fk � � " %, %m kllq�!Egom HAUSER SR 1175 TREVOR PRIVATE 9 5 IN r GRAPHIC SCALE 600 0 300 600 1200 ( IN FEET ) 1 inch = 600 ft. EFFLUENT PIPE TO RIVER —� N 'FIGURE No. 7 =w^ WASTEWATER TREATMENT PLANT WITH DISCHARGE TO YADKIN RIVER f" "Pi Flow Equalization Blower: Design flow rate: 48 CFM at 4.5 PSIG Blower horsepower: 2.0 BHP KW input to motor: 1.76 kW (85% motor efficiency) Equalization blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 1.76 kW x 18 hours per day x 365 days per year = 11,563 kWH per year M Power costs per year = $1,156 ,,, Sludge Blower Design flow rate: 131 CFM at 4.5 PSIG Blower horsepower: 4.2 BHP ., KW input to motor: 3.7 kW (85% motor efficiency) Sludge blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 3.7 kW x 18 hours per day x 365 days per year = 24,309 kWH per year Power costs per year = $2,431 Main Plant Blower: Design flow rate: 510 CFM at 4.5 PSIG Blower horsepower: 12.7 BHP kW input to motor: 11.1 kW (85% motor efficiency) Main plant blower typically cycled by time clock; this analysis will assume worst case, i.e. 100% operation. Power consumption per year: 11.1 KW x 24 hours per day x 365 days per year = 97,236 kWH per year Power costs per year = $9,724 Ultra -violet Disinfection System: Power consumption = 0.98 kW Power consumption per year = 8,584 kWH Power costs per year = $858 Filter backwash pumps: Design flow rate: 4 cells @ 18.75 S.F. each. Backwash at 20 gpm/sf, 375 gpm TDH: 25 feet Brake horsepower required: 3.9 BHP (60% efficiency) KW input to motor: 3.4 kW (85% motor efficiency) Assume 10 minutes per day per cell, four cells total. Pump run time is .67 hours per day. Power consumption per year: 3.4 kW x .67 hours per day x 365 days per year = 831 kWH per year �+ Power costs per year = $83 Appendix A Page 49 FM Mudwell pumps: Design flow rate: 60 gpm TDH: 16 feet Brake horsepower required: 0.40 BHP (60% efficiency) KW input to motor: 0.35 kW (85% motor efficiency) Returns water used in filter backwashes (375 gpm x 10 minutes x 4 cells) _ 15,000 gallons per day Pump run time is 15,000 gallons/60 gpm = 250 minutes = 4.17 hours/day Power consumption per year: 0.35 kW x 4.17 hours per day x 365 days per year = 533 kWH per year YAM Power costs per year = $53 Summary of annual power costs: Grinder Pumps — all lots $5,219 Flow equalization pumps $ 342 Flow equalization blower $ 1,156 Sludge blower $ 2,431 Main plant blowers $ 9,724 Ultra -violet disinfection $ 858 Filter Backwash Pumps $ 83 Mudwell Pumps 53 M MT R, P" Total Annual Power Costs $19,866 Lab Analyses: For the purposes of this report, the following tests and testing frequencies will be used: Test Cost Frequency Annual Cost BOD-5 $22 3/Week $3,432 NH3-N 17 3/Week $ 2 652 TSS $13 3/Week 2 028 Fecal Coliform $18 3/Week $2,808 Total N $32 Weekly $ 1 664 Total P $16 Weekly 832 Conductivity $12 Weekly $ 624 Annual Testing Costs $14,040 Annual solids (sludge) disposal cost: Sludge production rate for extended aeration is 2,000 Ibs of dry solids per million gallons treated. Sludge digestion/holding tank will allow thickening to 3% solids concentration. Appendix A Page 50 MR 2,000 Ibs/M.G. x 0.108 MG/Day x 365 Days/Year = 78,840 Ibs dry solids per year = 315,486 gallons/year at 3% solids Contract disposal to application site, including stabilization, at $.10 per gallon = $31,549 Equipment Repair/Replacement: Assume 15 year life for pumps, motors, and generator, yielding an annual replacement charge of $5,910. This is based on a Sinking Fund Factor (A/F, 7%, 15 years) of 0.0398, times the equipment cost of $148,500. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 148,500 = $ 5,910 Maintenance at 5.0% of $ 148,500 = 7,425 Total annual equipment replacement/repair charge = $ 13,335 Fuel Costs: Based on 52 hours per year run time for exercise and power outages, for the 75 kW standby power generator. Fuel consumption is 420 cubic feet per hour of propane (equal to approximately 11.7 gallons of LP). 52 hours x 11.7 gal./hr LPG at $2.47 per gal. _ $ 1,503 Total = $ 1,503 Contract operations by licensed operator: $ 55,000 Summary of annual O&M costs: Annual power costs $ 19,866 Annual testing costs $ 14,040 Sludge disposal $ 31,549 Equipment repair/replacement $ 13,335 Fuel costs $ 11503 Contract operations 55 000 Total Annual O&M costs $135,293 Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 224 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-6. The wastewater treatment system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first seven years of operation, until the development is built out. Appendix A Page 51 PM Year 0 Costs Wastewater Treatment System Construction $ 836,459 Infrastructure Costs for 32 Lots (32/224 of $6,817,094) 973,871 (No 0&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $1,810,330 Year 1 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual 0&M Costs: Annual power costs (prorated) $ 15,393 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 4,507 Equipment repair/replacement $ 13,335 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual 0&M Costs for Year 1: 103,778 Total Year 1 Costs $1,077,649 Year 2 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 16,138 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 9,014 Equipment repair/replacement $13,335 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual O&M Costs for Year 2: $ 109,030 Total Year 2 Costs $1,082,901 .► Year 3 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 9731,871 Annual O&M Costs: Annual power costs (prorated) $ 16,884 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 13,521 Equipment repair/replacement $ 13,335 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual 0&M Costs for Year 3: $ 114,283 Total Year 3 Costs $1,088,153 Appendix A Page 52 PI Year 4 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 17,629 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 18,028 Equipment repair/replacement $ 13,335 Fuel Costs $ 11503 Licensed contract operations cost $55,000 MR Total Annual O&M Costs for Year 4: 119,535 Total Year 4 Costs $1,093,406 Year 5 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 18,375 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 22,535 Equipment repair/replacement $ 13,335 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual O&M Costs for Year 5: 124 788 Total Year 5 Costs $1,098,659 Year 6 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 19,120 Annual testing cost $ 14,040 '" Sludge disposal (prorated) $ 27,042 Equipment repair/replacement $13,335 Fuel Costs $ 11503 MR Licensed contract operations cost 55 000 Total Annual O&M Costs for Year 6: 130,040 Total Year 6 Costs $1,103,911 Year 7 through year 30 Costs (24 years) Total Annual O&M Costs $ 135,293 F Appendix A Page 53 P*1 F" Total Year 7 through year 30 Costs - (Each Year) $ 135,293 P4 P" 0" F" last PSI P" PR m" Pq P" P" The present worth for Alternative No. 7 is presented in Table 7-A below. Table 7-A Present Worth of Alternative No. 7 Year Total Annual Cost P/F, 7%, n Present Worth 0 $1,810,330 1.0000 $1,810,330 1 $1,077,649 0.9346 $10007,149 2 $1,082,901 0.8734 $945,848 3 $1, 088,153 0.8163 $888,257 4 $110939406 0.7629 $834,154 5 $1,098,659 0.7130 $783,329 6 $19103,911 0.6663 $735,583 7 $135,293 0.6227 $84, 254 8 $135,293 0.5820 $78,742 9 $135,293 0.5439 $73,590 10 $135,293 0.5083 $68,776 11 $135,293 0.4751 $64,277 12 $135,293 0.4440 $60,072 13 $135,293 0.4150 $56,142 14 $135,293 0.3878 $52,469 15 $135,293 0.3624 $49, 036 16 $135,293 0.3387 $45, 828 17 $1359293 0.3166 $42,830 18 $135,293 0.2959 $40,028 19 $135,293 0.2765 $37,410 20 $135,293 0.2584 $34,962 21 $1359293 0.2415 $32,675 22 $135,293 0.2257 $30,537 23 $135,293 0.2109 $28,540 24 $135,293 0.1971 $26,673 25 $1351293 0.1842 $24, 928 26 $135,293 0.1722 $230297 27 $135,293 0.1609 $21,773 28 $135,293 0.1504 $20, 348 29 $135,293 0.1406 $19,017 30 $135,293 0.1314 $17,773 Present Worth of Alternative No. 7 $8,0389626 Appendix A Page 54 PER ALTERNATIVE NO.8 WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT Pram LANT, WITH RE -USE QUALITY EFFLUENT DISPOSAL THROUGH DRIP IRRIGATION LINES (SURFACE APPLIEDI This Alternative is similar to Alternative No. 5, except that the wastewater is treated to re -use quality, as defined by 15 NCAC 02T.0906. The treated effluent is stored in a lagoon, and then applied on the land surface through a drip irrigation system. One of the benefits of treating to re -use quality is the effluent may be applied up to the property line, with no setback required. However, the re -use rules require that the wastewater be treated to more stringent limits, that the treatment system have a more thorough disinfection system than utilized under Alternative No. 5, have an effluent turbidimeter, and have a lined "upset pond" with five days of storage. By elimination of the setbacks, additional land is made available for application of wastewater, which translates into more lots that can be served. However, the additional lots that can be served will be located on land that was previously designated as drip irrigation areas under Alternative No. 5. Therefore, the additional irrigation areas recovered from the Alternative No. 5 setback zones are. used to (1) replace the irrigation areas taken by the additional lots created, and (2) to provide irrigation areas sufficient to serve the additional lots. The additional number of lots created under this alternative is 15, making the total number of lots 183. The estimated flow for this Alternative is 89,280 gallons per day, using the same flow factors as used in the previous Alternatives: F" FM MR P" 183 houses @ 480 gpd average = 87,840 gpd Total Wastewater Capacity of indicated soil = 88,075 gal/day The drip irrigation area for this alternative is the 52.27 acres utilized under Alternative No. 5, plus 12.11 acres from the setback zones in Alternative No. 5, less the 6.38 acres of drip irrigation area utilized for the additional lots created. The total area under drip irrigation under. this alternative is 58.00 acres. As in Alternative No. 5, the layout inefficiency factor of 1.1 is utilized due to topography, shape of suitable soil areas and setback requirements that reduce the efficiency of the tubing layout. The area of each soil unit proposed for irrigation and the recommended application rates are presented in Table No. 8-A. TABLE NO.8-A CAPACITY OF SOILS USED FOR SURFACE DRIP IRRIGATION SYSTEM Soil Unit Area, in Acres LTAR, in in/yr Capacity, in GPD Cecil-Pacolet- Hiwassee 34.98 25 59,148 Wilkes-Wynott 6.53 15 61622 Congaree 11.92 20 16,120 Altavista 4.57 20 61185 Total 58.00 88,075 Appendix A Page 55 COLOR SHADING KEY LAKE, STREAM OR OPEN WATER 50' BUFFER ON STREAMS G I7��11►_ 0 1 0 HAUSER RD SR 1175 TREVOR LAP PRIVATE _--- WET WEATHER STORAGE 1 WWTr 5 DAY POND 1!�'1r1�R� L]iu.Z C+ r!!C n 0 ■ Cyy}sw+��•�iL.r�►�ur/lrl�ar�'.rr�`'.lv�r©.r +� � it .•r �`^�^^'r'�r+!�r��►�s.r- �� Vyyy �r�rirt�lir� 2 PRO low F. rwrw GRAPHIC SCALZ IN FEET 600 FIGURE No. 8- WASTEWATER COLLECTION SYSTEM AND o WASTEWATER TREATMENT PLANT, WITH RE —USE QUALITY EFFLUENT DISPOSAL THROUGH DRIP IRRIGATION LINES (SURFACE APPLIED) M" �+ Alternative No. 8 uses 58.00 acres of the 167.87 acres of usable soils for drip irrigation fields (capacity of 88,075 gpd). A total of 109.87 acres will be used for lots, associated streets, a recreational lake, and the wastewater treatment plant and effluent storage pond area. Some of this acreage used for the lots must be taken from the usable soils, due to the location of the soils relative to the site access locations. The remaining 58.00 acres are used for effluent irrigation to create the maximum number of lots possible. Capacity is calculated as follows: (Areas, in acres) x (43,560 sf per ac.) / (1.1(layout inefficiency)) x (LTAR) / (12 in. per foot) / (365 days per year) x (7.48 gallons per CF) M" P" ow MR MR M" P" F" P" ON = Capacity in gal/day The wastewater system components for this Alternative include: One 87,840 GPD extended aeration package plant with ultraviolet disinfection system, tertiery filters and effluent pump station, installed Excavation and construction of concrete base slab One 60 kW standby generator and automatic transfer switch, installed One lined lagoon (71 days storage, per DWQ Water Balance spreadsheet) with bottom dimensions of 163 Ft x 326 Ft, 3:1 side slopes, 12 foot maximum water level, two feet of freeboard, one foot minimum below required storage volume: 23,338 CY cut to fill at $3.50/CY One lined lagoon (5 days storage, per DWQ rules), with bottom dimensions of 18 Ft x 36 Ft, 3:1 side slopes, 12 foot maximum water level, two feet of freeboard, one foot minimum below required storage volume: 1,838 CY cut to fill at $3.50/CY 121,555 SF of 30 mil HDPE liner at $1.55/SF installed (for both storage lagoons) Drip irrigation system including 1,127,352 LF dripper line, 48 zone valves, 12 return flush valves, supply & return piping, irrigation pump system, pump house, computer controller, control wiring, electrical, etc. Electrical Construction 1,750 LF of six ft. chain link fence for lagoon and treatment plant area at $12.00/1-F 12,200 LF of barbed wire fencing for application area at $3.50/LF Erosion control, clearing, landscaping, seeding, etc. (5.77 acres at $5,000/ac.) Subtotal, Estimated Construction Cost Appendix A Page 57 $ 443,611 $ 78,373 $ 37,086 $ 81,683 $ 6,433 $ 188,410 $ 1,931,129 $ 175,700 $ 21,000 $ 42,700 $ 28,850 $ 3,034,975 am Soil Scientist Fees (5%) $ 151,749 Engineering Fees (7%) $ 212.448 Total Estimated Project Cost $ 3,399,172 Other Costs/Savings Under this Alternative there is less infrastructure construction required than under the surface discharge Alternative because there are fewer lots developed. The infrastructure unit cost developed in Appendix C is $344 per linear foot of street constructed. This cost includes all land clearing, grading, erosion control, storm drainage, water mains, valves, fire hydrants, paving, curb & gutter, , turn lane construction on existing road, engineering, and surveying. Alternative No. 8 has 12,515 LF of street. The only items not included in this unit cost factor are the individual grinder pump station for each lot, the water service for each lot, and the pressure sewer mains. These costs vary depending upon the number of lots developed, and are therefore calculated separately for each Alternative. The infrastructure costs for Alternative No. 8 are: $344/1-F of street x 12,515 LF of streets IN" Water services: 183 x $700 each Grinder pump station on each lot, installed: 183 at $5,500 each Pressure Sewer: 41800 LF of 2 inch at $6.50/1.17 7,100 LF of 3 inch at $9.75/LF 500 LF of 4 inch at $13.00/1-17 MR Total Infrastructure Cost $4,305,160 $128,100 $1,006,500 $31,200 $69,225 6 500 $5,546,685 The lost opportunity cost due to developing 183 lots in lieu of the 224 lots possible under the a� treatment plant/surface discharge Alternative is calculated as follows: Alternative No. 7, the treatment plant with surface water discharge has the following number and types of lots: 32 Waterfront lots, sale price of: $137,500 each 70 Garden home lots, sale price of: $ 65,000 each 44 Non -waterfront lots (ave. 0.58 ac.), sale price of: $ 85,000 each 78 Non -waterfront lots (ave. 0.67 ac.), sale price of: $100,000 each 224 Total number of lots P" IM Appendix A Page 58 r" Alternative No. 8 has the following number and types of lots: 32 Waterfront lots 70 Garden home lots 44 Non -waterfront lots (ave. 0.58 ac.) 37 Non -waterfront lots (ave. 0.67 ac.) 183 Total number of lots ,R The lost opportunity cost for Alternative No. 8 is: 41 Non -waterfront lots (ave. 0.67 ac.) $100,000 each = $4,1001000 For this economic analysis, it is assumed the annual lot sales for Alternative No. 8 will be 32 lots per year, for years 0, 1, 2, 3, and 4, and 23 lots for year 5. The lot sales for Alternative No. 7, the treatment plant with a discharge to surface waters, is assumed to be 32 per year for years 0 through 6, thereby creating 9 lost opportunity lots in year 5, and 32 lost lots in year 6 for Alternative No. 8. Operation and Maintenance Costs MR The annual power costs are estimated as follows: Annual power cost for a single family grinder pump station: Design pump rate: 480 GPD x 2.5 peaking factor x 1 day/1440 minutes �., < 1 GPM, use 11 GPM due to nominal capacity of grinder pump TDH: Will vary due to location of station and number of pumps in operation in system. Assume 1 BHP required when operating. Brake horsepower required: 1.0 BHP KW input to motor: 0.87 KW (85% motor efficiency) Operating time: 480 gpd/11 gpm = 43.6 minutes = 0.73 hours/day Power consumption per day: 0.87 KW x 0.73 hours per day= 0.635 kWH per day Power consumption per year: = 233 kWH per year IM Power costs per year ($.10/kWH) _ $23.30 per house, or $4,264 for 183 houses Im Flow Equalization pumps: Design pump rate: 82 GPM TDH: Static head varies: maximum is 12 feet plus friction losses of 2 feet = 14 MR feet Due to recycle of excess flow, pump will run an average of 18 hours per day Brake horsepower required: 0.48 BHP (60% efficiency) MR KW input to motor: 0.42 kW (85% motor efficiency) Power consumption per year: 0.42 kW x 18 hours per day x 365 days per year = 2,759 kWH per year MR Power costs per year = $276 Appendix A No Page 59 ON Flow Equalization Blower: Design flow rate: 39 CFM at 4.5 PSIG Blower horsepower: 1.66 BHP KW input to motor: 1.46 kW (85% motor efficiency) Equalization blower to be cycled on and off by time clock; normal run time to be 18 hours a day or less. Power consumption per year: 1.46 kW x 18 hours per day x 365 days per year = 91592 kWH per year Power costs per year = $959 Sludge Blower Design flow rate: 107 CFM at 4.5 PSIG ►� Blower horsepower: 3.49 BHP KW input to motor: 3.06 kW (85% motor efficiency) Sludge blower to be cycled on and off by time clock; normal run time to be 18 �* hours a day or less. Power consumption per year: 3.06 kW x 18 hours per day x 365 days per year = 20,104 kWH per year Power costs per year = $2,010 Im OR Main Plant Blower: Design flow rate: 414 CFM at 4.5 PSIG Blower horsepower: 10.5 BHP kW input to motor: 9.2 kW (85% motor efficiency) Main plant blower typically cycled by time clock; this analysis will assume worst case, i.e. 100% operation. Power consumption per year: 9.2 KW x 24 hours per day x 365 days per year = 80,592 kWH per year Power costs per year = $8,059 Ultra -violet Disinfection System: Power consumption = 0.81 kW Power consumption per year = 7,096 kWH Power costs per year = $710 Drip irrigation pumps: 87,840 gal per day x 365 days/200 irrigation days = 160,308 gallons per irrigation day. Pump rate is 116 gpm per zone, or with two zones irrigated at one time (232 gpm combined rate). Pump TDH is assumed to be 40 feet for static and friction losses to each zone, plus 81 feet (35 psi) at the inlet end of the drip tubing, or 121 feet for TDH. Appendix A Page 60 R" no 160,308 gallons per irrigation day/232 gal per min. = 691 min. pumping per irrigation day, or 11.52 hours per irrigation day. Allow an additional 0.48 hours per day for zone flushing requirements rw Brake horsepower required: 10.1 BHP (70% efficiency) KW input to motor: 8.86 KW (85% motor efficiency) Power consumption per irrigation day: FW 8.86 KW x 12.0 hours per day = 106.3 kWH per irrigation day Power consumption per year = 106.3 kWH per irrigation day x 200 irrigation IM days per year = 21,260 kWH per year Power costs per year = $2,160 Summary of annual power costs: Grinder Pumps — all lots $4,264 Flow equalization pumps $ 276 Flow equalization blower $ 959 Sludge blower $ 2,010 Main plant blowers $ 8,059 Ultra -violet disinfection $ 710 Duplex Effluent Pumps 2 160 Total Annual Power Costs $18,438 T" MR MR MR No Lab Analyses: For the purposes of this report, the following tests and testing frequencies will be used: Test Cost Frequency Annual Cost BOD-5 22 3/Week $ 3 432 NH3-N 17 3/Week $ 2 652 TSS $13 3/Week $ 2 028 Fecal Coliform 18 3/Week $ 2 808 Total N $32 Weekly $ 1664 Total P $16 Weekly $ 832 Conductivity 12 Weekly $ 624 Annual Testing Costs T $ 14 040 Annual solids (sludge) disposal cost: Sludge production rate for extended aeration is estimated to be 2,000 Ibs of dry solids per million gallons treated. Sludge digestion/holding tank will allow thickening to 3% solids concentration. 2,000 Ibs/M.G. x 0.088 MG/Day x 365 Days/Year = 64,240 lbs dry solids per year = 257,063 gallons/year at 3% solids Appendix A Page 61 Pq MW Contract disposal to application site, including stabilization, at $.10 per gallon _ $25,706 IM Equipment Repair/Replacement: Assume 15 year life for pumps, motors, and generator, yielding an annual replacement charge of $7,315. This is based on a Sinking Fund Factor (A/F, 7%, 15 years) of rM 0.0398, times the equipment cost of $166,800. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 183,800 = $ 71315 Maintenance at 5.0% of $ 183,800 = 9 190 Total annual equipment replacement/repair charge = $ 16,505 MR Fuel Costs: Based on 52 hours per year run time for exercise and power outages, for the 60 kW standby power generator. Fuel consumption is 335 cubic feet per hour of propane Wn (equal to approximately 9.3 gallons of LP). F" 52 hours x 9.3 gal./hr LP at $2.47 per gal. _ $ 1,194 Total = $ 1,194 Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the plant and file all required reports (assumes drip irrigation areas have low maintenance tree crop cover). Annual Fee: $ 55,000 Summary of annual O&M costs: �+ Annual power costs $ 18,438 Annual testing costs $ 14,040 Sludge disposal $ 25,706 FM Equipment repair/replacement $ 16,505 Fuel costs $ 11194 Contract operations 55,000 MR Total Annual O&M costs $130,883 F" Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 183 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-5. The cost of the 41 lost opportunity lots will be applied at a rate of 9 lots in year 5, and 32 lots in year 6. The wastewater treatment and disposal system will be constructed in year 0. Appendix A ,q Page 62 MM Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first five years of operation, until the development is built out. FM Year 0 Costs Wastewater Treatment and Disposal System Construction $3,399,172 FM Infrastructure Costs for 32 Lots (32/183 of $5,546,685) 969.9i2 (No 0&M cost in year 0 — facilities and houses constructed) PM Total Year 0 Cost $4,029,907 Year 1 Costs am Infrastructure Costs for 32 Lots (32/183 of $5,546,685) $ 969,912 Annual O&M Costs: Annual power costs (prorated) $ 13,137 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 4,495 Equipment repair/replacement $ 16,505 Fuel Costs $ 1,194 Licensed contract operations cost $55,000 Total Annual O&M Costs for Year 1: $ 104,371 Total Year 1 Costs $1,074,283 Year 2 Costs Infrastructure Costs for 32 Lots (32/183 of $5,546,685) $ 969,912 Annual O&M Costs: Annual power costs (prorated) $ 14,260 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 8,990 Equipment repair/replacement $ 16,505 Fuel Costs $ 11194 Licensed contract operations cost 55 0.00 Total Annual O&M Costs for Year 2: 109,989 Total Year 2 Costs $1,079,901 Year 3 Costs Infrastructure Costs for 32 Lots (32/183 of $5,546,685) $ 969,912 Annual O&M Costs: Annual power costs (prorated) $ 15,384 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 13,485 Equipment repair / replacement $ 16,505 Fuel Costs $ 11194 Appendix A ,� Page 63 IM Licensed contract operations cost 55 000 Total Annual 0&M Costs for Year 3: MR Total Year 3 Costs ' Year 4 Costs - Infrastructure Costs for 32 Lots (32/183 of $5,546,685) Annual O&M Costs: Annual power costs (prorated) $ 16,507 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 17,980 Equipment repair / replacement $ 16,505 Fuel Costs $ 11194 Licensed contract operations cost $55,000 FM Total Annual O&M Costs for Year 4: Total Year 4 Costs Year 5 Costs Infrastructure Costs for 23 Lots (23/183 of $5,546,685) Lost opportunity costs of 9 lots (9/41 of $4,100,000) Annual O&M Costs: Annual power costs (prorated) $ 17,631 Annual testing costs $ 14,040 Sludge disposal $ 22,475 Equipment repair/replacement $ 16,505 Fuel costs $ 1,194 Contract operations $55,000 Total Annual O&M Costs fm Total Year 5 Costs Year 6 Costs M' Lost opportunity costs of 32 lots (32/41 of $4,100,000) Annual O&M Costs: IM Annual power costs $ 18,438 Annual testing costs $ 14,040 Sludge disposal $ 25,706 Equipment repair/replacement $ 16,505 Fuel costs $ 11194 Contract operations $55,000 Appendix A ,W Page 64 115 608 $1,085,520 $ 969,912 $ 121,226 $1,091,138 $ 697,124 $ 900,000 $ 126,845 $1,723,969 $3,200,000 pq MR Total Annual O&M Costs $ 130,883 Total Year 6 Costs $31330,883 MR Year 7 through year 30 Costs (24 years) Total Annual O&M Costs $ 130,883 MR Total Year 7 through year 30 Costs_ (Each Year) $ 130,883 The present worth for Alternative No. 8 is presented in Table 8-B below. FOR MR Appendix A Page 65 PSI Pm P" FM (PE+ MR MR FM M Fmi PM P" Pq IMR FER mm Table 8-A Present Worth of Alternative No. 8 Year Total Annual Cost PIF, 7%, n Present Worth 0 $4,369,084 1.0000 $4,369,084 1 $19074,283 0.9346 $1,004,003 2 $1,079,901 0.8734 $9439227 3 $1,085,520 0.8163 $886,108 4 $1,091,138 0.7629 $832,424 5 $1,723,969 0.7130 $1,229,166 6 $3,330,883 0.6663 $2,219,508 7 $130,883 0.6227 $81,507 8 $130,883 0.5820 $76,175 9 $130,883 0.5439 $71,192 10 $130,883 0.5083 $66, 534 11 $1309883 0.4751 $62,182 12 $130,883 0.4440 $58,114 13 $130,883 0.4150 $54,312 14 $130,883 0.3878 $50,759 15 $130,883 0.3624 $47,438 16 $1309883 0.3387 $44,335 17 $130,883 0.3166 $419434 18 $130,883 0.2959 $38,724 19 $130,883 0.2765 $36,190 20 $130,883 0.2584 $33,823 21 $130,883 0.2415 $31,610 22 $130,883 0.2257 $29, 542 23 $130,883 0.2109 $279609 24 $130,883 0.1971 $25, 803 25 $130,883 0.1842 $24,115 26 $130,883 0.1722 $22,537 27 $130,883 0.1609 $21,063 28 $130,883 0.1504 $199685 29 $130,883 0.1406 $181397 30 $130,883 0.1314 $17,194 Present Worth of Alternative No. 8 $12,483,793 Appendix A Page 66 PM p" F" Pam! MR Mt PSI MR APPENDIX B PM p" RE-EXAMINATION OF ALTERNATIVES WITH THE ASSUMPTION THAT ADDITIONAL LAND IS AVAILABLE fmm Pm pm ow MR P" Summary of Present Worths of Revised Alternatives: go The land -based treatment and disposal Alternatives No. 3 through No. 6, and No. 8, do not allow as many lots to be developed as Alternative No. 7, which utilizes a wastewater treatment plant and discharge to surface waters. This is because the land based treatment systems use MR some of the developable land for the wastewater disposal systems, unlike the treatment plant alternative discharge. Consequently, the land -based alternatives must include the lost opportunity cost of the undeveloped lots. In this Appendix B Alternatives No. 3 through No. 6, am and No. 8, are re-examined to determine the economic effects of additional land being available for the treatment systems. Additional land is assumed available to allow development of the maximum 224 lots on the original Lissara tract for each of these alternatives. This assumption will eliminate the lost opportunity costs for each of the land -based alternatives. Each re-examined alternative includes the increased infrastructure costs associated with the development of 224 lots, the increased treatment and disposal system costs for the scaled -up facilities to serve 224 lots, and the increased O&M costs for the larger systems. 0" The present worth values of the re-evaluated five alternatives are: FM f" I" F, Ow I" FM F" Alt. Present Minimum Number Description Worth Additional Land Req d 3-R Individual Sub -surface Systems $10,459,104 418 acres Wastewater Collection System and Wastewater 4-R Treatment Plant, with Disposal through $9,440,999 158 acres Conventional Nitrification Lines Wastewater Collection System and Wastewater 5-R Treatment Plant, with Disposal through Drip $10,993,339 71.6 acres Irrigation Lines (Surface Applied) Wastewater Collection System and Wastewater 6-R Treatment Plant, with Disposal through Spray $9,802,982 87.5 acres Irrigation System Alternative No. 7 is included below for reference. Wastewater Collection System & 7 Wastewater Treatment Plant, with Disposal $8,038,626 through Surface Discharge to Yadkin River Wastewater Collection System and Wastewater 8-R Treatment Plant With Re -Use Quality Effluent $10,772,670 64.1 acres Disposal Through Drip Irrigation Lines (Surface Applied) Appendix B Page 1 Iry MR The estimated minimum additional land areas included in the Table above represent property that the Lissara developers would have to acquire to develop 224 lots using one of the land - based wastewater disposal systems evaluated in the EAA. The above summary of the Present Worths of the revised Alternatives indicates that the PW of Alternative No. 4 (revised) is closest to the PW of Alternative No. 7 (discharge to the Yadkin River), but it is still 17_%, greater than the Present Worth of Alternative No. 7. It should be noted that neither the cost of the required additional land or the cost of pumping and piping the treated wastewater to off -site areas have been included in the PW calculations for any of the alternatives. 0" no am M WR No Ow fm Flo With the economic analyses indicating the re-evaluated Alternatives (without land costs and pumping/piping costs included) are not cost effective when compared to the present worth of Alternative No. 7, it is readily apparent that the re-evaluated Alternatives will not be cost effective even if the additional land and pumping/piping costs were $0. Based on this evaluation, no further investigation of the availability of off -site properties is warranted. Appendix B Page 2 No MR ALTERNATIVE NO.3 (Re-examined with additional land assumed available) INDIVIDUAL SUB -SURFACE SYSTEMS Under this re-examined alternative 224 lots will be developed with individual septic systems. The amount of infrastructure constructed in the original Alternative No. 3 served a total of 83 lots on 246 acres. The infrastructure cost was $4,238,388 for the original Alternative, plus $383,250 for the 83 septic systems Assuming similar streets, waterlines, storm drainage, and soils on adjacent properties, the projected infrastructure cost for 224 lots is: $4,238,388 x 224 lots/83 lots = $111,438,541 PW The total costs of the individual septic systems for 83 lots was estimated to be $383,250, which projects to the following costs for 224 lots: am $383,250 x 224 lots/83 lots = $1,034,313 Alternative No. 3 estimated the 246-acre Lissara tract could support the development of 83 lots with individual septic tanks. Assuming the surrounding properties have similar topography and soils, it is estimated that as much as 418 additional acres would be required to develop 141 lots, and create a total of 224 lots. Operation and Maintenance Costs MR In the interest of brevity, the calculations presented below are a summary of the detailed calculations presented under Alternative 3 in Appendix A, modified as appropriate to represent 224 lots rather than the original 83 lots. 00 The annual power costs are estimated as follows: Power costs per year ($.10/kWH) = $8.58 per house times 135 houses assumed to have pumped systems, or $1,158 per year Equipment Repair/Replacement: Replacement costs at 0.0398 x $ 650 x 135 lots = $ 31492 Maintenance at 5.0% of $ 87,750 = 4,388 No Total annual equipment replacement/repair charge = $ 71880 No A. OW Solids Removal and Disposal: Septic tanks are assumed to require pumping once every five years at a cost of $200 per pump -out. It is assumed the lots will be developed over a seven-year period. Appendix B Page 3 am The solids removal/disposal costs for this Alternative are summarized as follows: Pump out of residential septic systems: FM 32 tanks x $200 $ 6,400 in year 5 32 tanks x $200 $ 6,400 in year 6 32 tanks x $200 $ 6,400 in years 7, 12, 17, etc. FM 32 tanks x $200 $ 6,400 in years 8, 13, 18, etc. 32 tanks x $200 $ 6,400 in years 9, 14, 19, etc. RM 64 tanks x $200 $ 12,800 in years 10, 15, 20, etc. 64 tanks x $200 $ 12,800 in years 11, 16, 21, etc. Summary of the annual O&M costs for Alternative No. 3 (revised): Annual power costs $ 1,158 Equipment repair / replacement 7,880 Sub Total Annual O&M Costs $ 31348 am In addition to the sub -total listed above, there is a Solids Removal and Disposal cost that will be included in the economic analysis to reflect cleaning of the tanks once every five years. A' Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 224 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-6. The calculated annual power costs are dependent on the number of pump systems in place, and will be prorated for the first seven years as the development is built out. Year 0 Costs go Wastewater System Construction (32/224 of $1,034,313) $ 147,759 Infrastructure Costs for 32 Lots (32/224 of $11,438,541) $ 1,634,077 (No O&M cost in year 0 — facilities and houses constructed) on Total Year 0 Cost $ 11781,836 Year 1 Costs Wastewater System Construction (32/224 of $1,034,313) $ 147,759 Infrastructure Costs for 32 Lots (32/224 of $11,438,541) $ 1,634,077 Annual O&M Costs: Annual power costs (prorated) $ 165 Equipment repair / replacement . $ 7,880 Total Annual O&M Costs for Year 1: 8,045 Total Year 1 Costs $1,789,881 MO Year 2 Costs Wastewater System Construction (32/224 of $1,034,313) $ 147,759 Infrastructure Costs for 32 Lots (32/224 of $11,438,541) $ 1,634,077 we Annual O&M Costs: Appendix B Page 4 No Annual power costs (prorated) $ 331 Equipment repair / replacement $ 7,880 Total Annual O&M Costs for Year 2: 8,211 Total Year 2 Costs $1,790,047 Year 3 Costs Total Year 3 Costs $1,790,211 IM Year 4 Costs Total Year 3 Costs $1,790,376 am Year 5 Costs Wastewater System Construction (32/224 of $1,034,313) $ 147,759 Infrastructure Costs for 32 Lots (32/224 of $11,438,541) $ 1,634,077 "" Annual O&M Costs: Solids Removal Cost: $ 6,400 Annual power costs (prorated) $ 825 Equipment repair / replacement 7 880 Total Annual 0&M Costs for Year 5: 15,105 Total Year 5 Costs $1,796,941 Year 6 Costs Wastewater System Construction (32/224 of $1,034,313) $ 147,759 Infrastructure Costs for 32 Lots (32/224 of $11,438,541) $ 11634,077 Annual O&M Costs: O, Solids Removal Cost: $ 6,400 Annual power costs (prorated) $ 991 Equipment repair / replacement 7,880 FM Total Annual O&M Costs for Year 6: 15,271 Total Year 6 Costs $1,797,107 am Years 7-9 Costs (and for Years 12-14,17-19, 22-24, and 27-291 Annual O&M Costs: Solids Removal Cost: $ 6,400 I' Annual power costs (prorated) $ 1,158 Equipment repair /. replacement 7,880 PAR Total Annual 0&M Costs for Years 7, 8, and 9: $ 15,438 OM Years 10 and 11 Costs (and for Years 15-16, 20-21, 25-26, and 30) Annual 0&M Costs: Solids Removal Cost: $ 12,800 Annual power costs (prorated) $ 1,158 Equipment repair / replacement 7,880 Total Annual O&M Costs for Years 10 and 11: $ 21,838 Appendix B Page 5 Om "° The present worth for Alternative No. 3 (revised) is presented in Table 3-R below. P" MR P" W am MR 0" O. f" MR Im Im ma "a am Table 3-R Present Worth of Alternative No. 3 (revised) Year Total Annual Cost PIF, 7%, n Present Worth 0 $1,781,836 1.0000 $1,781,836 1 $1,789,881 0.9346 $1,672,786 2 $19790, 047 0.8734 $19563 9496 3 $1,790,211 0.8163 $1,461,345 4 $1,790,376 0.7629 $1,365,869 5 $1,796,941 0.7130 $19281,194 6 $1,797,107 0.6663 $1,197,488 7 $15,438 0.6227 $9,614 8 $159438 0.5820 $8,985 9 $15,438 0.5439 $89397 10 $21,838 0.5083 $11,101 11 $21,838 0.4751 $10,375 12 $15,438 0.4440 $6,855 13 $15,438 0.4150 $6,406 14 $15,438 0.3878 $5,987 15 $21,838 0.3624 $7, 915 16 $21,838 0.3387 $7, 397 17 $15,438 0.3166 $4,887 18 $15,438 0.2959 $4,568 19 $15,438 0.2765 $4,269 20 $219838 0.2584 $5,643 21 $21,838 0.2415 $5,274 22 $15,438 0.2257 $3,485 23 $151438 0.2109 $3,257 24 $15,438 0.1971 $3,044 25 $21,838 0.1842 $49024 26 $21,838 0.1722 $3,760 27 $15,438 0.1609 $2,484 28 $15,438 0.1504 $27322 29 $15,438 0.1406 $2,170 30 $21,838 0.1314 $2, 869 Present Worth of Alternative No. 3 (revised) $10,4599104 Appendix B Page 6 ram+ am ALTERNATIVE NO.4 (Re-examined with additional land assumed available) WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH DISPOSAL THROUGH CONVENTIONAL NITRIFICATION LINES IN A COMMUNITY SYSTEM Under this re-examined alternative 224 lots will be developed with a central treatment system consisting of a package treatment plant to achieve secondary treatment and disinfection. The individual lots can be smaller than 30,000 square feet and are not required to contain any suitable soils because there will be no septic systems on the lots created under this Alternative. All wastewater will be collected by a pressure sewer system (each house will have an individual grinder pump system) and delivered to the proposed Lissara Wastewater Treatment Plant. The treated effluent from the plant will be pumped from an effluent holding �., tank into the nitrification fields proposed in areas outside of the subdivision. Flow will be directed to each of the 18 nitrification fields by solenoid valves and an irrigation -style valve control system. The estimated wastewater flow for this Alternative is 107,520 gal/day, based on 224 four bedroom houses @ 480 gal/day. The original Alternative No. 4 used 38.26 acres of suitable soils for nitrification fields and repair areas. For the revised Alternative No. 4, the estimated total amount of suitable soils required is 69.1 acres. When the 224 lots and associated infrastructure are positioned on the Lissara tract, there is approximately 21.5 acres of suitable soils outside of the areas proposed to be developed, and within the Lissara boundaries. These soil areas decrease the amount of required off -site suitable soils to 47.6 acres. The original Lissara tract had approximately 30% of its total area classified as suitable, so it is assumed that approximately 158 acres (47.6 acres/30%) of offsite property similar to the Lissara tract would be required to support the development of 224 lots within Lissara. (Area in acres) x (43,560 sf per ac.) / (2 for the nitrification field and repair areas / (1.4 for the layout inefficiencies) / (9 ft. trench spacing) x (3 ft. trench width) x LTAR = Capacity in gal/day For this alternative: (69.11 acres x 43,560 sf/acre)/2 (repair)/1.4 (layout ineff.)/(9 feet trench spacing) x 3 feet trench width x 0.30 gpd/sf (LTAR) = 107,520 gal/day Im The wastewater treatment and disposal system costs, as scaled up from Alternative No. 4, are: Total Estimated Wastewater Treatment and Disposal Costs $ 2,488,141 The infrastructure costs for Alternative No. 4(revised) are: a. $344/LF of street x 15,351 LF of streets $5,280,744 Appendix B Page 7 R" OR water services: 224 x $700 each $156,800 Grinder pump station on each lot, installed: 224 at $5,500 each $1,232,000 Pressure Sewer: 5,100 LF of 2 inch at $6.50/1-F $33,150 5,600 LF of 3 inch at $9.75/LF $54,600 4,600 LF of 4 inch at $13.00/1-F $59,800 Total Infrastructure Cost $6,817,094 Operation and Maintenance Costs The annual power costs are estimated as (refer to Appendix A for detailed calculations): Annual power cost for grinder pump stations: Power costs per year ($.10/kwH) _ $23.30 per house, or $5,219 for 224 houses Flow equalization pumps: Power costs per year = $342 Flow Equalization Blower: Power costs per year = $1,156 Sludge Blower Power costs per year = $2,431 Main Plant Blower: Power costs per year = $9,724 Ultra -violet Disinfection System: Power costs per year = $858 Duplex effluent pumps: Power costs per year = $1,920 Summary of annual power costs: Grinder Pumps — all lots $5,219 Flow equalization pumps $ 342 Flow equalization blower $ 1,156 Sludge blower $ 2,431 Main plant blowers $ 9,724 Ultra -violet disinfection $ 858 Duplex Effluent Pumps 1920 �. Total Annual Power Costs $21,650 Appendix B �, Page 8 P" No Lab Analyses: For the purposes of this report, the annual testing cost is estimated to be $4,612. •w Annual solids (sludge) disposal cost: Contract disposal to application site, including stabilization, at $.10 per gallon = $31,549 ow Equipment Repair/Replacement: Assume 15-year life for pumps, motors, and generator, yielding an annual replacement charge of $6,607. This is based on a Sinking Fund Factor (A/F, 7%, 15 years) of 0.0398, times the equipment cost of $166,000. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 1661,000 = $ 61607 Maintenance at 5.0% of $ 166,000 = 8,300 Total annual equipment replacement/repair charge = $ 14,907 MR Fuel Costs: Total annual fuel costs = $ 11503 F" Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the MW plant and file all required reports. Im Annual Fee: $45,000 Summary of the annual O&M costs for Alternative No. 4(revised): Annual power costs $ 21,650 Annual testing cost $ 41612 Sludge disposal $ 31,549 Equipment repair / replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost 45,000 Total Annual O&M Costs $ 119,221 o' Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 224 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-6. The wastewater treatment system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first seven years of operation, until the development is built out. Appendix B Page 9 ao Year 0 Costs Wastewater Treatment System Construction $2,488,141 Infrastructure Costs for 32 Lots (32/224 of $6,817,094) 973,871 (No O&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $3,462,012 Year 1 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 15,531 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 4,507 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 1: 86,060 a" Total Year 1 Costs $1,059,931 IM Year 2 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: a, Annual power costs (prorated) $ 16,551 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 9,014 PM Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 am Total Annual O&M Costs for Year 2: 91,587 Total Year 2 Costs $11,065,458 Year 3 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 17,571 Annual testing cost $ 41612 Sludge disposal (prorated) $ 13,521 Equipment repair/replacement $14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 3: 97 114 P Total Year 3 Costs $1,070,984 am an Appendix B Page 10 PI OW Year 4 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 18,590 Annual testing cost $ 41612 Sludge disposal (prorated) $18,028 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 4: 102,640 am Total Year 4 Costs $1,076,511 Year 5 Costs No Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual 0&M Costs: Annual power costs (prorated) $ 19,610 "m Annual testing cost $ 4,612 Sludge disposal (prorated) $ 22,535 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 5: 108,167 Total Year 5 Costs $1,018,871 Mn Year 6 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 OR Annual 0&M Costs: Annual power costs (prorated) $ 20,630 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 27,042 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost 45 000 Total Annual O&M Costs for Year 6: 113 694 Total Year 6 Costs $1r087,565 No Year 7 through year 30 Costs (24 years) Total Annual O&M Costs $ 119,221 no Total Year 7 through year 30 Costs — (Each Year) $ 119,221 See Table 4-R for present worth of Alternative No. 4 (revised). am Appendix 6 No Page 11 0" am PM ON 0" am we am m" OR Fwq go FM MR MR a. Im go Table 4 - R Present Worth of Alternative No. 4 (revised) Year Total Annual Cost PIF, 7%, n Present Worth 0 $3,462,012 1.0000 $3,462,012 1 $19059,931 0.9346 $990,590 2 $19065,458 0.8734 $930,612 3 $1,070,984 0.8163 $874,242 4 $1,076,511 0.7629 $821,265 5 $1, 018, 871 0.7130 $726,441 6 $190879565 0.6663 $724,690 7 $119,221 0.6227 $74, 245 8 $119,221 0.5820 $69,388 9 $119,221 0.5439 $64,848 10 $119,221 0.5083 $60,606 11 $119,221 0.4751 $56,641 12 $119,221 0.4440 $52,936 13 $119,221 0.4150 $49,472 14 $119,221 0.3878 $46,236 15 $119,221 0.3624 $43,211 16 $119,221 0.3387 $40, 384 17 $119,221 0.3166 $37,742 18 $119,221 0.2959 $35,273 19 $119,221 0.2765 $32,966 20 $119,221 0.2584 $30,809 21 $119,221 0.2415 $28,793 22 $1199221 0.2257 $26,910 23 $119,221 0.2109 $25,149 24 $119,221 0.1971 $23,504 25 $119,221 0.1842 $21,966 26 $119,221 0.1722 $209529 27 $119,221 0.1609 $19,186 28 $119,221 0.1504 $17,931 29 $1199221 0.1406 $16,758 30 $119,221 0.1314 $15,662 Present Worth of Alternative No. 4 (revised) $9,440,999 Appendix B Page 12 PM am Alternative No. 5 (revised) WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH DISPOSAL THROUGH DRIP IRRIGATION LINES (SURFACE APPLIED) •� Under this re-examined alternative 224 lots will be developed with a central treatment system consisting of a. package treatment plant to achieve secondary treatment and disinfection. All wastewater will be collected by a pressure sewer system (each house will have an individual grinder pump system) and delivered to the proposed Lissara Wastewater Treatment Plant. The treated effluent from the plant will be pumped from an effluent holding pond into the drip irrigation fields proposed in areas outside of the subdivision. The estimated wastewater flow for this Alternative is 107,520 gal/day, based on 224 four bedroom houses @ 480 gal/day. The drip irrigation area under the original Alternative No. 5 utilized 52.27 acres, based on a Ow layout inefficiency factor of 1.1. The layout inefficiency is due to topography, shape of suitable soil areas and setback requirements. For the Alternative No. 5 (revised), approximately 69.59 acres of land similar to the Lissara tract will be required for the drip FM irrigation area. When the 224 lots and associated infrastructure are positioned on the Lissara tract, there is approximately 20.9 acres of suitable surface irrigation soils outside of the areas proposed to be developed, and within the Lissara boundaries. These soil areas decrease the amount of required off site suitable soils to 48.7 acres. The original Lissara tract had approximately 68% of its total area classified as suitable for surface irrigation, so it is assumed that approximately 71.6 acres (48.7 acres/68%) of offsite property similar to the Lissara tract would be required to support the development of 224 lots within Lissara. The estimated cost of the wastewater system treatment and disposal components for this No Alternative is $3,988,147. The infrastructure costs for Alternative No. 5 (revised) are: MR $344/LF of street x 15,351 LF of streets $5,280f744 IM Water services: 224 x $700 each $156,800 Grinder pump station on each lot, installed: 224 at $5,500 each $1,232,000 an am Pressure Sewer: 5,100 LF of 2 inch at $6.50/LF $33,150 5,600 LF of 3 inch at $9.75/1-F $54,600 4,600 LF of 4 inch at $13.00/1-17 59 800 Total Infrastructure Cost $6,817,094 For this economic analysis, it is assumed the annual lot sales for Alternative No. 5 (revised) will be 32 lots per year, for years 0 through 6. Appendix B Page 13 0" OW go no FM FM am OR P" M" FNq ON am Nq Im Op go Operation and Maintenance Costs The annual power costs are estimated as (refer to Appendix A for detailed calculations): Annual power cost for grinder pump stations: Power costs per year ($.10/kWH) _ $23.30 per house, or $5,219 for 224 houses Flow equalization pumps: Power costs per year = $342 Flow Equalization Blower: Power costs per year = $1,156 Sludge Blower Power costs per year = $2,431 Main Plant Blower: Power costs per year = $9,724 Ultra -violet Disinfection System: Power costs per year = $858 Drip irrigation pumps: 107,520 gal per day x 365 days/200 irrigation days = 196,224 gallons per irrigation day. Pump rate is 116 gpm per zone, or with two zones irrigated at one time (232 gpm combined rate). Pump TDH is assumed to be 40 feet for static and friction losses to each zone, plus 81 feet (35 psi) at the inlet end of the drip tubing, or 121 feet for TDH. 196,224 gallons per irrigation day/232 gal per min. = 846 min. pumping per irrigation day, or 14.1 hours per irrigation day. Allow an additional 0.9 hours per day for zone flushing requirements Brake horsepower required: 10.1 BHP (70% efficiency) KW input to motor: 8.86 KW (85% motor efficiency) Power consumption per irrigation day: 8.86 KW x 15.0 hours per day = 132.9 kWh per irrigation day Power consumption per year = 132.9 kWh per irrigation day x 200 irrigation days per year = 26,580 kWh per year Power costs per year = $2,658 Summary of annual power costs: Grinder Pumps — all lots Flow equalization pumps Flow equalization blower Sludge blower Appendix B Page 14 $5,219 $ 342 $ 1,156 $ 2,431 MR Main plant blowers $ 9,724 Ultra -violet disinfection $ 858 Duplex Effluent Pumps 2 658 Total Annual Power Costs $22,388 Lab Analyses: For the purposes of this report, the annual testing cost is estimated to be $4,612. Annual solids (sludge) disposal cost: Contract disposal to application site, including stabilization, at $.10 per gallon = $31,549 Equipment Repair/Replacement: FM Assume 15-year life for pumps, motors, and generator, yielding an annual replacement charge of $6,607. This is based on a Sinking Fund Factor (A/F., 7%, 15 years) of 0.0398, times the equipment cost of $166,000. The annual cost of routine maintenance am and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 166,000 = $ 61607 PW Maintenance at 5.0% of $ 166,000 = t 8.300 Total annual equipment replacement/repair charge = $ 14,907 Fuel Costs: Total annual fuel costs = $ 1,503 Contract Operations: a„ Cost to hire a licensed wastewater treatment plant operator/company to operate the plant and file all required reports. MR Annual Fee: $45,000 Summary of the annual O&M costs for Alternative No. 4(revised): Annual power costs $ 22,388 Annual testing cost $ 41612 Sludge disposal $ 31,549 Equipment repair / replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost 45,000 Total Annual O&M Costs $ 119,959 ON Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 224 lots Appendix B Page 15 INq OM and their associated infrastructure in this Alternative will be constructed in phases in years 0-6. The wastewater treatment system will be constructed in year 0. Portions of the calculatedr annual power costs and the sludge disposal costs are flow proportional, and will be prorated Ow for the first seven years of operation, until the development is built out. am Year 0 Costs Wastewater Treatment System Construction $3,988,147 Infrastructure Costs for 32 Lots (32/224 of $6,817,094) 973,871 ON (No 0&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $4,962,018 MR Year 1 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: MR Annual power costs (prorated) $ 15,636 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 4,507 '" Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Ow Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 1: 86,165 Total Year 1 Costs $11060,036 Year 2 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 16,761 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 9,014 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 2: 91,797 Total Year 2 Costs $1,065,668 Year 3 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 17,886 Annual testing cost $ 41612 Sludge disposal (prorated) $ 13,521 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Appendix B Page 16 am Total Annual 0&M Costs for Year 3: 97,430 Total Year 3 Costs $1,071,300 MR Year 4 Costs MR Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $19,011 _ IM Annual testing cost $ 4,612 Sludge disposal (prorated) $ 18,028 Equipment repair/replacement $14,907 M+ Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 4: 103,061 FM Total Year 4 Costs $1,076,932 Year 5 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 20,136 Annual testing cost $ 4,612 ,R Sludge disposal (prorated) $ 22,535 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 MM Licensed contract operations cost 45 000 Total Annual 0&M Costs for Year 5: 108,693 IM Total Year 5 Costs $1,082,564 Year 6 Costs FM Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 21,261 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 27,042 Equipment repair/replacement $ 14,907 Fuel Costs $ 11503 Licensed contract operations cost 45 000 Total Annual O&M Costs for Year 6: 114 325 Total Year 6 Costs $1,088,196 Year 7 through year 30 Costs (24 years Total Annual 0&M Costs $ 119,959 Appendix B Page 17 FMR m Total Year 7 through year 30 Costs - (Each Year) $ 119,959 M•, FM Fm MR m" m MR MR mm MR pq FM OR mmi See Table 5-R for present worth of Alternative No. 5 (revised). Tables -R Present Worth of Alternative No. 5 (revised) Year Total Annual Cost P/F, 7%, n Present Worth 0 $49962, 018 1.0000 $4, 962, 018 1 $190609036 0.9346 $990,688 2 $1 t065,668 0.8734 $930,796 3 $1,071,300 0.8163 $874,500 4 $1,076,932 0.7629 $821,586 5 $1, 082, 564 0.7130 $771, 853 6 $1, 088,196 0.6663 $725,111 7 $119,959 0.6227 $749704 8 $119,959 0.5820 $69,817 9 $119,959 0.5439 $65,250 10 $119,959 0.5083 $60,981 11 $119,959 0.4751 $56,992 12 $119,959 0.4440 $539263 13 $119,959 0.4150 $49,779 14 $119,959 0.3878 $46,522 15 $119,959 0.3624 $43,479 16 $119,959 0.3387 $40,634 17 $1199959 0.3166 $379976 18 $119,959 0.2959 $35,492 19 $119,959 0.2765 $33,170 20 $1199959 0.2584 $31,000 21 $119,959 0.2415 $28, 972 22 $119,959 0.2257 $27, 076 23 $119,959 0.2109 $25,305 24 $119, 959 0.1971 $23,650 25 $119,959 0.1842 $22,102 26 $119,959 0.1722 $20,656 27 $1199959 0.1609 $19, 305 28 $119,959 0.1504 $18,042 29 $119,959 0.1406 $16, 862 30 $119,959 0.1314 $15,759 Present worth of Alternative No. 5 (revised) $10,993,339 Appendix B Page 18 No F" ALTERNATIVE NO.6 (Re-examined with additional land assumed available) MR WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH DISPOSAL THROUGH SPRAY IRRIGATION SYSTEM �-+ Under this re-examined alternative 224 lots will be developed with a central treatment system consisting of a package treatment plant to achieve secondary treatment and disinfection. All wastewater will be collected by a pressure sewer system (each house will have an individual grinder pump system) and delivered to the proposed Lissara Wastewater Treatment Plant. The treated effluent from the plant will be pumped from an effluent holding pond into the spray irrigation fields proposed in areas outside of the subdivision. The estimated wastewater flow for this Alternative is 107,520 gal/day, based on 224 four bedroom houses @ 480 gal/day. The spray irrigation area under Alternative No. 6 utilized 47.65 acres, based on a layout RM inefficiency factor of 1.2, to dispose of an average daily wastewater flow of 69,120 gpd. The layout inefficiency is due to topography, shape of suitable soil areas and setback requirements. For the revised Alternative No. 5, approximately 74.12 acres of land similar to the Lissara tract FX" will be required for the spray irrigation areas. When the 224 lots and associated infrastructure are positioned on the Lissara tract, there is approximately 14.7 acres of suitable surface irrigation soils outside of the areas proposed to be developed, and within the Lissara MR boundaries. These soil areas decrease the amount of required off -site suitable soils to 59.4 acres. The original Lissara tract had approximately 68% of its total area classified as suitable for surface irrigation, so it is assumed that approximately 87.5 acres (59.4 acres/68%) of MR offsite property similar to the Lissara tract would be required to support the development of 224 lots within Lissara. The estimated cost of the wastewater system treatment and disposal components for this Alternative is $2,806,627. M The infrastructure costs for Alternative No. 6 (revised) are: $344/1-17 of street x 15,351 LF of streets $5,280,744 Water services: 224 x $700 each $156,800 Grinder pump station on each lot, installed: 224 at $5,500 each $1,232,000 Pressure Sewer: 5,100 LF of 2 inch at $6.50/LF $33,150 51,600 LF of 3 inch at $9.75/LF $54,600 41600 LF of 4 inch at $13.00/1-F $59,800 "o Total Infrastructure Cost $6,817,094 FM For this economic analysis, it is assumed the annual lot sales for Alternative No. 6 (revised) will be 32 lots per year, for years 0 through 6. Appendix B MR Page 19 OW PW me ON am OR am am MR OW M" PW 0" go Operation and Maintenance Costs The annual power costs are estimated as (refer to Appendix A for detailed calculations): Annual power cost for grinder pump stations: Power costs per year ($.10/kWH) _ $23.30 per house, or $5,219 for 224 houses Flow equalization pumps: Power costs per year = $342 Flow Equalization Blower: Power costs per year = $1,156 Sludge Blower Power costs per year = $2,431 Main Plant Blower: Power costs per year = $9,724 Ultra -violet Disinfection System: Power costs per year = $858 Duplex irrigation pumps: 107,520 gal per day x 365 days/200 irrigation days = 196,224 gallons per irrigation day. Pump rate is 10 gpm per sprinkler head, or 490 gpm per zone. Pump TDH is assumed to be 40 feet for static and friction losses to each zone, plus 127 feet (55 psi) at the sprinkler nozzles, or 167 feet for TDH. 196,224 gallons per irrigation day/490 gal per min. = 400 min. pumping per irrigation day, or 6.67 hours per irrigation day Brake horsepower required: 29.52 BHP (70% efficiency) KW input to motor: 25.91 KW (85% motor efficiency) Power consumption per irrigation day: 25.91 KW x 6.67 hours per day = 172.7 kWh per irrigation day Power consumption per year = 172.7 kWh per irrigation day x 200 irrigation days per year = 34,540 kWh per year Power costs per year = Summary of annual power costs: Grinder Pumps — all lots Flow equalization pumps Flow equalization blower Sludge blower Main plant blowers $3,454 Appendix B Page 20 $5,219 $ 342 $ 1,156 $ 2,431 $ 9,724 FM Ultra -violet disinfection $ 858 Duplex Effluent Pumps 3 454 Total Annual Power Costs $23,184 MR Lab Analyses: For the purposes of this report, the annual testing cost is estimated to be $4,612. an Annual solids (sludge) disposal cost: Contract disposal to application site, including stabilization, at $.10 per gallon = $31,549 Equipment Repair/Replacement: Assume 15 year life for pumps, motors, and generator, yielding an annual replacement charge of $6,010. This is based on a Sinking Fund Factor (A/F, 7%, 15 years) of 0.0398, times the equipment cost of $166,000. The annual cost of routine maintenance and repairs is estimated to be 5% of equipment cost. Replacement costs at 0.0398 times $ 151,000 = $ 61010 Maintenance at 5.0% of $ 151,000 = 7,550 Total annual equipment replacement/repair charge = $ 13,560 Fuel Costs: Total annual fuel costs = $ 1,503 Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the «� plant and file all required reports. Annual Fee: $45,000 Summary of the annual O&M costs for Alternative No. 4(revised): �..► Annual power costs $ 23,184 Annual testing cost $ 41612 Sludge disposal $ 31,549 Equipment repair / replacement $ 13,560 Fuel Costs $ 11503 Licensed contract operations cost 45 000 Total Annual O&M Costs $ 119,408 Present Worth Analysis Based on an average market absorption rate of approximately 32 lots per year, the 224 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-6. Appendix B on Page 21 ON MR The wastewater treatment system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first seven years of operation, until the development is built out. Year 0 Costs Wastewater Treatment System Construction $2,806,627 Infrastructure Costs for 32 Lots (32/224 of $6,817,094) 973 871 (No O&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $3,780,498 Year 1 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 15,750 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 4,507 Equipment repair/replacement $ 13,560 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 1: 84,932 Total Year 1 Costs $1,058,803 Year 2 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 16,989 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 9,014 Equipment repair/replacement $ 13,560 Fuel Costs $ 11503 Licensed contract operations cost 45 000 Total Annual O&M Costs for Year 2: 90 678 IM Total Year 2 Costs $1,064,549 Year 3 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 18,228 Annual testing cost $ 41612 Sludge disposal (prorated) $ 13,521 Equipment repair/replacement $ 13,560 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual O&M Costs for Year 3: 96,424 Appendix B Page 22 W" MR Total Year 3 Costs $1,070,295 Year 4 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual 0&M Costs: Annual power costs (prorated) $ 19,467 Annual testing cost $ 41612 �► Sludge disposal (prorated) $ 18,028 Equipment repair/replacement $ 13,560 Fuel Costs $ 1,503 Licensed contract operations cost $45,000 Total Annual 0&M Costs for Year 4: 102170 Total Year 4 Costs $1,076,041 Year 5 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual 0&M Costs: Annual power costs (prorated) $ 20,706 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 22,535 Equipment repair/replacement $ 13,560 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual 0&M Costs for Year 5: 107,916 Total Year 5 Costs $1,081,787 Year 6 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual 0&M Costs: Annual power costs (prorated) $ 21,945 Annual testing cost $ 4,612 Sludge disposal (prorated) $ 27,042 Equipment repair/replacement $13,560 Fuel Costs $ 11503 Licensed contract operations cost $45,000 Total Annual 0&M Costs for Year 6: 113,662 Total Year 6 Costs $1,087,533 Oft Year 7 through year 30 Costs (24 years) Total Annual 0&M Costs $ 119,408 Total Year 7 through year 30 .Costs — (Each Year) $ 119,408 Appendix B Page 23 PR .e F] ON flm No 00 am we OR PM OR am See Table 6-R for present worth of Alternative No. 6 (revised): Table 6 - R Present Worth of Alternative No. 6 (revised) Year Total Annual Cost PIF, 7%, n Present Worth 0 $39780,498 1.0000 $397809498 1 $1,058,803 0.9346 $989,536 2 $11064, 549 0.8734 $929, 818 3 $19070,295 0.8163 $873,680 4 $1, 076, 041 0.7629 $8209907 5 $1,081,787 0.7130 $771,299 6 $1,087,533 0.6663 $724,669 7 $119,408 0.6227 $74, 361 8 $119,408 0.5820 $69,497 9 $119,408 0.5439 $64,950 10 $119,408 0.5083 $60,701 11 $119,408 0.4751 $56,730 12 $119,408 0.4440 $53,019 13 $119,408 0.4150 $499550 14 $119,408 0.3878 $46,308 15 $119,408 0.3624 $43,279 16 $1199408 0.3387 $40,448 17 $119,408 0.3166 $37,802 18 $119,408 0.2959 $35,329 19 $119,408 0.2765 $33,017 20 $119,408 0.2584 $30,857 21 $119,408 0.2415 $28,839 22 $119,408 0.2257 $26,952 23 $119,408 0.2109 $25,189 24 $119,408 0.1971 $23,541 25 $119,408 0.1842 $22,001 26 $119,408 0.1722 $20,562 27 $119,408 0.1609 $19,216 28 $119,408 0.1504 $17, 959 29 $119,408 0.1406 $16,784 30 $119,408 0.1314 $15,686 Present Worth of Alternative No. 6 (revised) $99802,982 Appendix B Page 24 OM ALTERNATIVE NO. 8 (Re-examined with additional land assumed available) WASTEWATER COLLECTION SYSTEM AND WASTEWATER TREATMENT PLANT, WITH RE -USE QUALITY EFFLUENT DISPOSAL THROUGH DRIP IRRIGATION LINES (SURFACE APPLIED) Under this re-examined alternative 224 lots will be developed with a central treatment system consisting of a package treatment plant to achieve secondary treatment and disinfection. All wastewater will be collected by a pressure sewer system (each house will have an individual grinder pump system) and delivered to the proposed Lissara Wastewater Treatment Plant. The wastewater will be treated to re -use quality water, and the effluent from the plant will be pumped from an effluent holding pond into the drip irrigation fields proposed in areas outside of the subdivision. The estimated wastewater flow for this Alternative is 107,520 gal/day, based on 224 four bedroom houses @ 480 gal/day. The drip irrigation area under Alternative No. 8 utilized 58.00 acres, based on a layout inefficiency factor of 1.1, to dispose of an average daily flow of 88,075 gpd. The layout ,.� inefficiency is due to topography, shape of suitable soil areas and setback requirements. For the revised Alternative No. 8, approximately 70.8 acres of land similar to the Lissara tract will be required for the drip irrigation area. When the 224 lots and associated infrastructure are positioned on the Lissara tract, there is approximately 27.1 acres of suitable surface irrigation soils outside of the areas proposed to be developed, and within the Lissara boundaries. These soil areas decrease the amount of required off site suitable soils to 43.6 acres. The original Lissara tract had approximately 68% of its total area classified as suitable for surface irrigation, so it is assumed that approximately 64.1 acres (43.6 acres/68%) of offsite property similar to the Lissara tract would be required to support the development of 224 lots within Lissara. am The estimated cost of the wastewater system treatment and disposal components for this Alternative is $4,160,735. we The infrastructure costs for Alternative No. 8 (revised) are: $344/1-17 of street x 15,351 LF of streets No Water services: 224 x $700 each Grinder pump station on each lot, installed: 224 at $5,500 each Pressure Sewer: 5,100 LF of 2 inch at $6.50/1-F 5,600 LF of 3 inch at $9.75/LF 4,600 LF of 4 inch at $13.00/LF Total Infrastructure Cost am Appendix B Page 25 $5,280,744 $156,800 $1,232,000 $33,150 $54,600 59 800 $6,817,094 OW M For this economic analysis, it is assumed the annual lot sales for Alternative No. 5 (revised) will be 32 lots per year, for years 0 through 6. 'o Operation and Maintenance Costs The annual power costs are estimated as (refer to Appendix A for detailed calculations): IM Annual power cost for grinder pump stations: ,,,o Power costs per year ($.10/kWH) _ $23.30 per house, or $5,219 for 224 houses Flow equalization pumps: No Power costs per year = $342 Flow Equalization Blower: +m Power costs per year = $1,156 Sludge Blower we Power costs per year = $2,431 Main Plant Blower: 'A' Power costs per year = $9,724 Ultra -violet Disinfection System: ON Power costs per year = $858 am Filter Backwash pumps: Power costs per year = $83 Mudwell pumps: Power costs per year = $53 Drip irrigation pumps: Power costs per year = $2,658 Summary -of annual power costs: Grinder Pumps — all lots $5,219 Flow equalization pumps $ 342 Flow equalization blower $ 1,156 Sludge blower $ 2,431 Main plant blowers $ 9,724 Ultra -violet disinfection $ 858 �- Filter Backwash Pumps $ 83 Appendix B ,�, Page 26 No Mudwell Pumps $53 Drip Irrigation Pumps 2 658 Total Annual Power Costs $22,524 Lab Analyses: For the purposes of this report, the annual testing cost is estimated to be $14,040. MR Annual solids (sludge) disposal cost: Contract disposal to application site, including stabilization, at $.10 per gallon = $31,549 No Equipment Repair/Replacement: Assume 15-year life for pumps, motors, and generator, yielding an annual replacement +m charge of $7,690. This is based on a Sinking Fund Factor (A/F., 7%, 15 years) of 0.0398, times the equipment cost of $166,000. The annual cost of routine maintenance .and repairs is estimated to be 5% of equipment cost. go Replacement costs at 0.0398 times $ 193,200 = $ 7,690 go Maintenance at 5.0% of $ 193,200 = 9,660 rM Total annual equipment replacement/repair charge = $ 17,350 Fuel Costs: Total annual fuel costs = $ 11503 Contract Operations: Cost to hire a licensed wastewater treatment plant operator/company to operate the plant and file all required reports. Annual Fee: Summary of the annual O&M costs for Alternative No. 8 (revised): Annual power costs Annual testing cost Sludge disposal �+ Equipment repair / replacement Fuel Costs Licensed contract operations cost Total Annual O&M Costs no Present Worth Analysis $55,000 $ 22,524 $ 14,040 $ 31,549 $ 17,350 $ 1,503 Ss 000 $ 141,966 Based on an average market absorption rate of approximately 32 lots per year, the 224 lots and their associated infrastructure in this Alternative will be constructed in phases in years 0-6. Appendix B we Page 27 ON The wastewater treatment system will be constructed in year 0. Portions of the calculated annual power costs and the sludge disposal costs are flow proportional, and will be prorated for the first seven years of operation, until the development is built out. Year 0 Costs Wastewater Treatment System Construction $4,160,735 Infrastructure Costs for 32 Lots (32/224 of $6,817,094) 973,871 (No O&M cost in year 0 — facilities and houses constructed) Total Year 0 Cost $5,134,606 Year 1 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 15,772 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 4,507 Equipment repair/replacement $ 17,350 Fuel Costs $ 11503 Licensed contract operations cost s 55 000 Total Annual O&M Costs for Year 1: 108,172 Total Year 1 Costs $1,082,043 ON Year 2 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 16,897 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 9,014 Equipment repair/replacement $ 17,350 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual 0&M Costs for Year 2: 113,804 Total Year 2 Costs $1,087,675 Year 3 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 18,022 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 13,521 Equipment repair/replacement $ 17,350 Fuel Costs $ 1,503 Licensed contract operations cost $55,000 *�► Total Annual 0&M Costs for Year 3: 119,436 Appendix B Page 28 No M Total Year 3 Costs $1,093,307 Year 4 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 9731,871 Annual O&M Costs: Annual power costs (prorated) $ 19,147 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 18,028 Equipment repair/replacement $ 17,350 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual O&M Costs for Year 4: 125,068 Total Year 4 Costs $1,098,939 Year 5 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 20,272 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 22,535 Equipment repair/replacement $ 17,350 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual O&M Costs for Year 5: 130,700 Total Year 5 Costs $1,104,571 Year 6 Costs Infrastructure Costs for 32 Lots (32/224 of $6,817,094) $ 973,871 Annual O&M Costs: Annual power costs (prorated) $ 21,397 Annual testing cost $ 14,040 Sludge disposal (prorated) $ 27,042 Equipment repair/replacement $ 17,350 Fuel Costs $ 11503 Licensed contract operations cost $55,000 Total Annual O&M Costs for Year 6: 136,332 Total Year 6 Costs $1,110,203 �► Year 7 through year 30 Costs (24 years) Total Annual O&M Costs $ 141,966 am Total Year 7 through year 30 Costs — (Each Year) $ 141,966 Appendix B am Page 29 0" P" No Ow fm OR am fm am P" FM *w am go am fm on See Table 8-R for present worth of Alternative No. 8 (revised): Table 8 - R Present Worth of Alternative No. 8 (revised) Year Total Annual Cost P/F, 7%, n Present Worth 0 $5,134,606 1.0000 $5,1349606 1 $1,082,043 0.9346 $19011,255 2 $1,087,675 0.8734 $9509017 3 $1,093,307 0.8163 $892,464 4 $1, 098, 939 0.7629 $8389375 5 $1,104, 571 0.7130 $787, 544 6 $110,203 0.6663 $73,433 7 $1419966 0.6227 $88,409 8 $141,966 0.5820 $82,626 9 $141,966 0.5439 $77,220 10 $141,966 0.5083 $72,168 11 $141,966 0.4751 $679447 12 $141,966 0.4440 $63,035 13 $141,966 0.4150 $58,911 14 $141,966 0.3878 $55,057 15 $141,966 0.3624 $51,455 16 $141,966 0.3387 $48, 089 17 $141,966 0.3166 $44,943 18 $141,966 0.2959 $42, 003 19 $141,966 0.2765 $39,255 20 $141,966 0.2584 $36,687 21 $141,966 . 0.2415 $34,287 22 $1419966 0.2257 $32,044 23 $141,966 0.2109 $299947 24 $141,966 0.1971 $279988 25 $141,966 0.1842 $26,157 26 $141,966 0.1722 $24,446 27 $141,966 0.1609 $22, 847 28 $141,966 0.1504 $21,352 29 $141,966 0.1406 $19,955 30 $1419966 0.1314 $18,650 Present Worth of Alternative No. 8 (revised) $10,7722670 Appendix B Page 30 APPENDIX C INFRASTRUCTURE COST BASIS 0" PM P" fm fm Ow I" MR P" f" P" am APPENDIX C BASIS FOR INFRASTRUCTURE COSTS Construction contract prices for a typical residential subdivision in Forsyth County, from Ramey, Incorporated of Winston-Salem I. CLEARING & GRUBBING Ouantity Unit Cost Unit Cost Clearing & Grubbing 221 51640.001 AC 124 080.00 TOTAL CLEARING & GRUBBING 124 080.00 II. GRADING & EROSION CONT. Ouantity Unit Cost Unit Cost Topsoil Stripping & Waste On -Site 42,916 2.48 CY 106 603.34 Mass Rock Excavation 1000 66.24 CY 66 240.00 Mass Grading 59 912 3.31 CY 198 428.54 Undercut and Backfill On -Site 100 8.83 CY 883.20 Fine Grading Streets 25,000 1.10 SY 27j 600.00 Construction Entrance 1 1104.00 EA 11104.00 Temporary Sediment Trap 4 2760.00 EA 11 040.00 Temp. Diversion Berm 5 155 2.21 LF 11382.24 Temp. Sediment Fence 2 680 3.31 LF 81876.16 Temp. 18" CPP 210 17.66 LF 31709.44 Temporary Seeding 40 1766.401 AC 70 656.00 Permanent Seeding 40 1987.201.AC 79 488.00 TOTAL GRADING & EROSION CONTROL 586 010.93 III. STORM SEWER Ouantitv Unit Cost Unit Cost 15" R C Pie 33801 23.184 LF 78 361.92 18" R C Pie 795 25.392 LF 20 186.64 24" R C Pie 713 33.12 LF 23 614.56 30" R C Pie 37 46.368 LF 1715.62 Curb Inlets 62 1766.4 EA 109 516.80 Storm Manhole 2 1766.4 EA 3,532.80 15" R C Flared End Section 5 552 EA 2 760.00 18" R C Flared End Section 1 607.2 EA 607.20 24" R C Flared End Section 3 717.6 EA 2152.80 30" R C Flared End Section 1 828 EA 828.00 Inlet Protection 64 193.2 EA 12 364.80 RipRapAprons 150 35.328 EA 5 299.20 TOTAL STORM SEWER 260 940.34 MR Appendix C - Page 1 F" MR fm OR MR MR IV. SANITARY SEWER Pressure sewer system to be utilized for all Alternatives with a community treatment system. Cost of system varies with number and location of lots. See each Alternative for pressure sewer cost estimate. V. WATER Ouantitv Unit Cost Unit Cost 6" CI 350 Ductile Iron Pie 2 800 17.66 LF 49 459.20 8" CI 350 Ductile Iron Pie 3 000 20.98 LF 62 928.00 6" Gate Valve & Box 6 717.60 EA 41305.60 8" Gate Valve & Box 6 99.36 EA 596.16 6" SJ DI Plug 4 248.40 EA 993.60 6"x6" MJ DI Cross 2 441.60 EA 883.20 6'56" MJ DI Tee 2 331.20 EA 662.40 8"'W MJ DI Tee 2 386.40 EA 772.80 1-1/2"" Blow -Off Assembly 2 1656.00 EA 3 312.00 6" MJ DI 45 Bend 2 259.44 EA 518.88 8"x6" Tapping Sleeve & Valve 2 4968.00 EA 9 936.00 Fire Hydrant Assembly 12 3036.001 EA 36 432.00 TOTAL WATER 1 170 799.84 on VI. PAVING & CURB & GUTTER Quantity Unit Cost Unit Cost FM Roadway Paving 7" ABC, 2" S9.5B, 1" SF9.5 16 160 19.87 SY 321 131.52 30" Valley Curb & Gutter 11241 13.25 LF 148 920.77 5' wide 4" Thick Concrete Sidewalk 27 957 4.42 SF 123 458.11 Manhole Adjustment 15 386.40 EA 5,796.00 Valve Box Adjustment 12 331.20 EA 3,974.40 Curb Inlet Adjustment 62 - 259.44 EA 16 085.28 TOTAL PAVING AND CURB & GUTTER 619,36 M" VII. WIDENING/TURNLANE Ouantity Unit Cost Unit Cnst fW PM Grading 1 49 680.00 LS 49 680.00 Full Depth Asphalt Widening 1675 47.47 SY 79 515.60 Asphalt Overlay 3,8921 6.62 SY 25 780.61 Striping 1 10 267.20 LS 10 267.20 TOTAL WIDENING/TURN LANE 1 165 243.41 OM Total Construction Cost, excluding sewer system and water Approximate Length of Street Constructed (in Linear Feet): MR Construction Cost per Linear Foot of Street (without sewer. system and water services): am 1,926,440.59 5,600 $ 344 MR Appendix C - Page 2 MR PI The amount of street in each Alternative is determined from the preliminary subdivision plan for the Alternative. The length of street is multiplied by $344 per linear foot, to estimate the infrastructure costs (excluding the pressure sewer lines, individual grinder pum ►� stations on each lots, and water services) for the Alternative. The quantity of the excluded items vary in each alternative; the cost of the items are calculated in Appendix A and added to the infrastructure cost for the Alternative. F" M P" R" P" P" MR M" MR P" am Appendix C - Page 3 ow am FM a" PM 0=4 a4 PM APPENDIX D Im PRELIMINARY SOILS REPORT PREPARED BY SOIL & ON ENVIRONMENTAL CONSULTANTS P.A. ow MR fm P" Im MR am No Environmental Consultants, PA ive Greensboro, North Carolina 27455 • Phone: (336)540-8234 •.Fax: (336) 540-8235 ww ..SandEC.corn Project 4-1800.S2 Westview Development Company Attn: Brant Godfrey 2631 Reynolda Road Winston-Salem, NC 27106 Re: Preliminary Soil/Site Evaluation on Conrad Road EAA Project: +/-243 Acre Site on Conrad Road and Shallowford Road — Forsyth County, NC Dear Mr. Godfrey: Soil & Environmental Consultants, PA (S&EC) performed a preliminary soil and site evaluation on the above referenced tract. This was performed at your request as part of the preliminary planning process in order to estimate areas of soil that have potential for subsurface and surface wastewater disposal. Fieldwork was completed on August 16, 2007. This revised report contains additional information about anticipated application rates for the soils units _ identified in the Preliminary Soil/Site Evaluation for Surface Applications section. This revised report references the soil maps produced for this project in August 2007. PRELIMINARY SOUJSITE EVALUATION — SUBSURFACE APPLICATIONS S&EC traversed the property and observed landforms (slope, drainage patterns, past use, etc.) as well as soil conditions (depth, texture, structure, seasonal wetness, restrictive horizons, etc.) through the use of hand auger borings. The site was evaluated during very dry soil conditions. From these observations, an evaluation of the site, relative to subsurface disposal of wastewater, was developed. Soil areas were estimated in the field. The soil/site evaluation criteria used is that contained in 15 A NCAC 18A .1900 "Laws and Rules for Sewage Treatment and Disposal Systems". If the decision is made to use subsurface septic systems as the primary wastewater disposal method for this project, then a Detailed Soil/Site Evaluation must be conducted. A Detailed Soil/Site Evaluation would involve delineating and GPS locating the boundaries between suitable and unsuitable soils, allowing for maximum accuracy and efficiency in the subdivision planning process. FINDINGS This site is located in the Northwest region of Forsyth County. The upland soils on this tract are similar to the Hiwassee, Cecil, Pacolet, Mecklenburg, Wynott, Wilkes, Congaree, Altavista, and Iredell soil series. The Hiwassee, Cecil, and Pacolet soil series have a sandy loam surface material over a clayey subsoil. These soils are at least 30 inches deep to prohibitive soil characteristics and are generally useable for subsurface, septic systems. The Mecklenburg soils have mixed clay mineralogy and are generally marginal for subsurface septic systems. The Wynott and Wilkes soils are shallow to rock and expansive clay, and are generally unsuitable for conventional subsurface septic systems. The Iredell soils have soil wetness conditions and expansive clay and are generally unsuitable for conventional subsurface septic systems. The Congaree and Altavista soils are located in a marginal floodplain landscape position. The limiting factor on this project regarding subsurface septic suitability is complex and unsuitable topographic features, such as Charlotte Office, Raleigh Office: 236 LePhillip Court, Suite C 11010 Raven Ridge Road. Charlotte, NC 28025 Raleigh,NC 27614 Phone: (704) 720-9405 Phone ;(919) 946-5900 Fax: (704) 720-9406 Fax: (919) 846-9467 MR P" faq P" MM M" MR fm r" FHq ditches and gullies. The accompanying AutoCAD map indicates the estimated areas withh.potential .use for subsurface wastewater disposal. The red -slashed units .indicate areas of soils which are at least 24 to 30 inches deep., to prohibitive soil characteristics and these areas. have potential for a conventional septic system, a modified conventional (shallow placed lines with no fill required over the disposal area) or a: low pressure pipe system (LPP) and/or ultra -shallow conventional (shallow placed lines with fill.required over the disposal field) system. The pink -hatched unit.indicates and area of soils in a marginal floodplain landscape position. This -area is marginal due to. landscape position, opinions may vary among local health department officials. Unit "NE" indicates areas in and around existing houses that were not evaluated. Unit "UNS on the attached map indicates areas of unsuitable topography, or of soils that are less than 24 inches to prohibitive soil characteristics and are generally unsuitable for the type of systems mentioned above. The site plan for each lot must ensure that adequate soil area for system and repair is unaffected by site elements (house placement, driveway, wells, patios, decks, etc.) -.on that or adjacent lots. The area ultimately designated by the health department on the site plan. for the septic system and repair must remain undisturbed (no mechanical clearing, excavation; heavy traffic.or.other significant site disturbing activities) until authorized by the health department. A lot with initially adequate useable soil area may be rendered unusable as a result of improper site planning and/or disturbance. A field layout of the proposed septic systems may be required as part of the individual lot development process. , Upon completion of a'subdivision plan, S&EC recommends reviewing the plan before recording the subdivision lots. It is important to note that any preliminary certification that a subdivision plan meets does not represent approval or a permit for any site work, nor does it guarantee. issuance of an improvement permit for. any lot. Final site approval for issuance of improvements is based on regulations in force at the time of permitting and is dependent on satisfactory completion of individual site evaluations following application for an improvement permit detailing a specific use and sitting. GENERAL WASTEWATER CONSIDERATIONS Once potentially useable areas are located through vertical borings, the next consideration is the horizontal extent of those areas. The size and configuration of the useable soil area dictate the utility of that area. The size of a subsurface disposal field is determined by: 1) the design flow from the source (120 gallons/bedroom/day in residences), and 2) the long term acceptance rate (LTAR).�of the soil .(based on the hydraulic conductivity of the soil, a function of the soil's texture; mineralogy, structure, porosity-. etc.). The configuration must be such. that an efficient layout of disposal* lines (on contour) is possible: An additional °consideration is the required setbacks for the system from various elements such as wells (100'), streams and ponds (50') or more depending on watershed regulations), property lines (10');*top of embankment (15'), watershed buffers, etc. (see Attachment 1). The utility of a potential useable soil area for a subsurface system is most accurately determined by an on -ground layout of the proposed system. The total area needed for system and repair areas will depend upon the system type, the. layout of that system and the total.design flow (factors mentioned above). A typical area needed- for a three -bedroom residence is approximately 10,000 to 12,000 ? (could be more depending on site features) or 800 to 960 linear feet.of conventional line (system:and repair) or 1440 linear feet of LPP line (system and repair):.; These estimates reference. Uws and Rules for Sewage Treatment`and Disposal Systems -forNorth Carolina and use a LIAR. of .3 gpd/ft for conventional septic systems (.1955), a LIAR of .25. gpd/f a for f" n•� modified conventional (.1956) and .1 gpd/ft for LPP septic systems (.I 957a). The health department will deteiirnine the ultimate LTAR after.their lot evaluation. S&EC will be glad to assist in any system layout or sizing calculations if requested. A typical area needed for a four - bedroom residence is.approximately 14,000 to 16,000 ft (could be more depending on site features). PRELESENARY SOHJSITE EVALUATION — SURFACE APPLICATIONS S&EC traversed the property in order to estimate the dominant soil types present with respect to their uses and limitations for surface wastewater applications. Soils were mapped to the NRCS Soil Series level, and map units were grouped based on similar characteristics or close association. The map units depicted on the attached map are estimated and represent soils most similar to the NRCS soil series noted. in the legend. Inclusions of other soil types, as well as topographic irregularities, are likely to exist within map units. If the decision is made to' move forward with a reclaimed wastewater spray irrigation system, then a Detailed Soil/Site Evaluation will be required within all proposed spray areas. Additional studies such as hydrology and hydrogeology analysis are also necessary for these types of systems. If this project is to utilize a reclaimed.wastewater spray irrigation system, S&EC would be happy to assist you in the planning and analysis process. -These types of systems are regulated by the North Carolina Division of Water Quality. Below is a summary of the soil types found on this project. Cecil-Pacolet-Hiwassee: These soils are deep, well drained,.and have kaolinitic clay mineralogy. Historically, these soils have allowed for relatively high application rates of reclaimed wastewater. Cecil Pacolet-Hiwassee-COMPLEX TOPO: These units contain soils similar to Cecil, Pacolet, and Hiwassee, with complex'topographic irregularities included within map units.. These features may require amendments for use in surface application of wastewater. Wilkes-Wynott: These series are closely associated on this project. The Wilkes soils have expansive clay mineralogy, and have rock or weathered rock at depths ranging from 12 to 20 -inches. The Wynott soils have expansive clay mineralogy, and have rock or weathered rock at depths ranging from 20 to 40 inches. These soils. have historically allowed for relatively low application rates of reclaimed wastewater. This. unit also contains minor inclusions of the Mecklenburg soil series. The Mecklenburg series are deep and have mixed clay mineralogy.. These soils have historically allowed for relatively moderate application rates of reclaimed wastewater. Iredell: These soils. have expansive clay mineralogy and soil wetness conditions from 12 to 18 inches deep -. These soils have historically allowed for relatively low to seasonal -low application rates of reclaimed wastewater... Congaree: These soils have wetness conditions at depths ranging from 30 to 60 inches. These soils have historically. allowed for relatively low to moderate application rates of reclaimed wastewater. Altavista: These soils have wetness conditions at depths ranging from 18 to 30 inches. These soils have historically allowed for relatively low application rates of reclaimed wastewater. General estimates of annual application rates of reclaimed. wastewater for the above mentioned units ate as follows: PER t�l , Cecil-Pacolet-Hiwasee: +/- 25"/yr PON Wilkes-Wynott::+/- 15"/yr Iredell: +/- IO"/yr, may have seasonal limitations' Congaree:. +/* 20' /yr Altavista: +/- 20"/yr As mentioned above, these ate general estimates based on past experience and anticipated allowable application rates for the soil characteristics that are present. Should this project proceed with some type -of wastewater irrigation system,:these rates could be higher or lower than estimated. This report discusses the general location of potentially useable soils for on -site subsurface and surface wastewater disposal and, of course, does not constitute or imply any approval or permit as needed by the client from -the local heath department or state. S&EC is a professional consulting firm that specializes in the delineation of soil areas for wastewater disposal, and the layout and design of wastewater treatment systems:. As a- professional consulting firm, S&EC is hired for its professional opinion in'these matters. The rules governing. wastewater -treatment (interpreted and governed by local and state agencies) are evolving constantly, and in many cases, affected by the opinions of individuals employed* by these governing agencies. Because of this, S&EC cannot OR guarantee that areas delineated and/or systems designed will be permitted by the -governing agencies_. As always, S&EC recommends that anyone making financial commitments on a tract be fully aware of individual permit requirements, including,. but not limited to, applying for and obtaining improvement permits.and approval from local/State governing authorities oh that tract prior to final action. Soil & Environmental Consultants, PA.. is pleased to be of service in this matter and we look forward to assisting in any site analysis needs you may have in th . future. Please feel free to call �+ with any questions or comments. Sincerely .► ��' �. _RyanP. Smith Environme'ntal Scientist t ' Encl. Attachment `1 Preliminary.Soit-Suitability' Map =. Subsurface : Prehminary',S.oil Suitability'Map -'Surface ... r1 am P" MR 0" rAf on APPENDIX E PM LETTER REGARDING THE ESTIMATED MARKET VALUE OF m" THE LISSARA LOTS m" fan I" po fm wq P" no op Hubbard Im R E A L T Y w" January 15, 2008 Lissara Partners, LLC 2631 Reynolda Road In" Winston-Salem, NC 27106 Reference: Lissara Project — Developed Lot Values Dear Mr. Godfrey, Pursuant to the request of Mr. John F. Phillips; the following is a summary of the present market value of the proposed Lissara development in Forsyth County, North Carolina. Per the attached Preliminary Site Plan and Vicinity Map this project is located on the Yadkin River in Northwestern Forsyth County on the outskirts of Winston-Salem near the Town of Lewisville. This is a highly sought-after location for high -end single-family residential real-estate. With the additional amenities of the water-ski lake, common areas, walking/bike trails and Yadkin River frontage I foresee this as being an even more attractive and marketable neighborhood than anything presently on the market in Forsyth County and the Lewisville community. The proposed Lissara development is anticipated to proceed in two phases with the first phase being the 144 acres including the lake with 146 lots. The second phase will include the Yadkin River frontage on 100 acres and 78 lots. Value of Lots F" Phase 1 32 lake -front lots ranging is size from .75 acre to 1.5 acres with an average price of $137.500. 70 Garden -home lots averaging .25 acre per lot with a sale price of $65,000 ", each, 44 Off -water lots averaging .58 acres in size with an average lot sales price of $85,000. ow Phase 2 78 Off -water lots averaging .67 acres in size with an average lot sales price of $100,000. P" Please advise if I can be of further assistance. 4" Very truly yours, HUBBARD REALTY OF WINSTON-SALEM, INC. uce R. Hubbard President �., Hubbard Realty of Winston-Salem, Inc. Accounting (336) 723-0303 2110 Cloverdale Avenue, Winston-Salem, NC 27103.2516 Property Management (336) 723-4306 Fax (336) 725-2400 Office (336) 723-0303 • Fax (336) 725-6644 Fax (336) 723-4309 ER p•a eowuMousa�c RMTW OPPoaiu►M MR as P" w pal ow a" APPENDIX F 00 MR LETTER FROM WINSTON-SALEM • FORSYTH COUNTY CITY/COUNTY UTILITIES REGARDING THE CAPACITY OF P1r1 THE TOWN OF LEWISVILLE TO PROVIDE WASTEWATER I" ow P" P" m" ow SERVICE TO LISSARA ow .,__..jjitns•Sewer • 5oiid Waste Disposal Vdlids Admini motion • CO. Box 2511 • lViaaonSalcm, NC 27102 • Ti4 336.727.8418 • A. 336.727.8432 April'26,2006 Lang Wilcox LTSSARA, LLC 1210 Forest Wood Drive Lewisville, North Carolina 27033 In Re: _Lissara Development Sewer Service Dear Mr. Wilcox - This letter is to inform you that David Saunders, Director of Utilities, presented your '+ proposal to construct the development entitled Lissam at the April 10, 2006 City/County Utility Commission Meeting. Mr. Saunders, informed the Commission that the public sewer was existing within Lewisville, NC, but there was no capacity to serve any developments outside of Lewisville. The plan to provide private sewer by the developer was also discussed. The City/County Utility Commission decided to voice a "no opinion vote" on this sewer service proposal since no City/County. Utility System was involved. If you have any questions concerning this subject, please give me a call at 727-8418. Sincerely, U`TIILI ADMINISTRATION /5� �. Robert W. Huff Assistant to the Superintendent RWH/If No fm on a" on P" MR M" f" No MR am APPENDIX G EXECUTED NPDES APPLICATION - FORM D A PORTION OF USGS QUADRANGLE MAP "CLEMMONS" INDICATING APPROXIMATE LOCATION OF REQUESTED DISCHARGE fm NPDES APPLICATION - FORM D For privately owned treatment systems treating 100% domestic wastewaters <1.0 MGD Mail the complete application to: N. C. Department of Environment and Natural Resources r Division of Water Quality / NPDES Unit 1617 Mail Service Center, Raleigh, NC 27699-1617 NPDES Permit INCOO r7 4 If you are completing this form in computer use the TAB key or the up - down arrows to move from one field to the next. To check the boxes, click your mouse on top of the box Otherwise, please print or type. 1. Contact Information: Owner Name Lissara Partners, LLC _ Facility Name Lissara Wastewater Treatment Plant Mailing Address 2631 Reynolda Road _ City Winston-Salem State / Zip Code NC / 27106 _ Telephone Number (336)777-0078 Fax Number ( 336) 722-5018 e-mail Address offisland@aol.com " 2. Location of facility producing discharge: Check here if same address as above ❑ r Street Address or State Road No address yet assigned. North of Shallowford Road, West of Conrad Road City Not in a City/Town (nearest town is Lewisville) r State / Zip Code NC County Forsyth County r 3. Operator Information: Name of the firm, public organization or other entity that operates the facility. (Note that this is not referring to the Operator in Responsible Charge or ORQ Name Lissara Partners, LLC �+ Mailing Address 2631 Reynolda Road City Winston-Salem r State / Zip Code NC / 27106 Telephone Number (336)777-0078 r Fax Number ( 336) 722-5018 1 of 4 Form-D 1/06 no NPDES APPLICATION - FORM D on For privately owned treatment systems treating 100% domestic wastewaters <1.0 MGD 4. Description of wastewater: 0M Facility Generating Wastewater(check all that applyf a, Industrial ❑ Number of Employees Commercial ❑ Number of Employees Residential ® Number of Homes 224 School ❑ Number of Students/ Staff Other ❑ Explain: Describe the source(s) of wastewater (example: subdivision, mobile home park, shopping centers, restaurants, etc.): Residential subdivision Population served: 224 houses with 3.5 persons f house assumed = 784 persons FM 5. Type of collection system ® Separate (sanitary sewer only) ❑ Combined (storm sewer and sanitary sewer) am 6. Outfall Information: go Number of separate discharge points 1 Outfall Identification number(s) 001 Is the outfall equipped with a diffuser? ElYes ® No aw 7. Name of receiving stream(s) (Provide a map showing the exact location of each outfallr am Yadkin River 8. Frequency of Discharge: ® Continuous ❑ Intermittent No If intermittent: Days per week discharge occurs: Duration: IM 9. Describe the treatment system List all installed components, including capacity, provide design removal for BOD, TSS, nitrogen and phosphorus. If the space provided is not sufficient, attach the description of the treatment system in a separate sheet of paper. `M See attached description w No ow MW 2of4 Form-D 1/06 a•a NPDES APPLICATION - FORM D "" For privately owned treatment systems treating 100% domestic wastewaters <1.0 MGD ON No 10. Flow Information: a" Treatment Plant Design flow 0.108 MGD Annual Average daily flow NA - proposed discharge MGD (for the previous 3 years) MR Maximum daily flow NA - proposed discharge MGD (for the previous 3 years) sm am am ow ON am 11. Is this facility located on Indian country? ❑ Yes ® No 12. Effluent Data Provide data for the parameters Iisted. Fecal Coliform, Temperature and pH shall be grab samples, for all other parameters 24-hour composite sampling shall be used. Effluent testing data must be based on at least three samples and must be no more than four and one half years old. Parameter Daily Maximum Monthly Avera a Units of Measurement Number of Samples Biochemical Oxygen Demand (BODS) NA - proposed discharge NA - proposed discharge NA - proposed discharge NA - proposed discharge Fecal Coliform NA NA NA NA Total Suspended Solids NA NA NA NA Temperature (Summer) NA NA NA NA Temperature (Winter) NA NA NA NA pH NA NA NA NA am 13. List all permits, construction approvals and/or applications: Type Permit Number Type Permit Number Hazardous Waste (RCRA) NESHAPS (CAA) Im UIC (SDWA) Ocean Dumping (MPRSA) NPDES X Dredge or fill (Section 404 or CWA) PSD (CAA) Special Order of Consent (SOC) +r.a Non -attainment program (CAA) Other 14. APPLICANT CERTIFICATION I certify that I am familiar with the information contained in the application and that to the best of my knowledge and belief such information is true, complete, and accurate. a. Brant Godfrey A�LManager Printed name of Person Signing Title N" 3 of 4 Form-D 1106 No E 4 APPLICATION - FORM D NPD WN For privately owned treatment systems treating 100% domestic wastewaters <1.0 MGD cif . A. 'AI .. 107 North Carolina General *a'tute 143-215.6 (b)(2) states: Any person who knowingly makes any false statement representation, or certification in any application, record, report, plan, or other document files or required to be a•n maintained under Article 21 or regulations of the Environmental Management Commission implementing that Article, or who falsifies, tampers with, or knowly renders inaccurate any recording or monitoring device or method required to be operated or maintained under Article 21 or regulations of the Environmental Management Commission implementing that Article, shall be guilty of a misdemeanor punishable by a fine not to exceed $25,000, or by imprisonment not to �n exceed six'months, or by both. (18 U.S.C. Section 1001 provides a punishment by a fine of not more than $25,000 or imprisonment not more than 5 years, or both, for a similar offense.) 0" ;W F" Mn am MR RM am Im No 0" W" am a" 4 of 4 Form-D 1l06 RM o" P" MR ON am MR APPENDIX H I, am PRELIMINARY WATER BALANCES FOR ALTERNATIVES NO. 5s 6j AND 8, USING DWQ SPRAY IRRIGATION WATER BALANCE SPREADSHEET f" ow ow fm No ow ow ow A Spray Irrigation Water Balance for Permit No: Lissara Drip Irrigation System Permittee Name: Contact Name: Address: Facility Lissara WWTP Address: Water Budget Prepared By: John F. Phillips, P.E. - Diehl & Phillips, P.A. Lissara DWQ Water Balance Drip As Project ld Version 5 December 2004 Enter Data —H := Precipitation Worksheet FYI Calculate the precipitation for an 80th percentile "wet' year, based on long term data (approx. 30 years or greater). Click on each step box Precipitation Data Step 1 Monlh Mean Monthly Precipitation Percent of Mean Annual Precipitation inches percent January 3.68 February 3.41 March 4.35 April 3.58 May 3.85 June 3.96 July 4.44 August 3.83 September 3.84 October 3.56 November 2.92 December 3.65 TOTALS = 4d.97 cUletloritl Ste 2 80th Percentile Monthly Precipitation il inches i _ _ —4.26 I f 3.94 I 5.03 r 414� i 4.45 4.58 y r�� r 4.43 f 4.44 ' ' 4.12 3.38 4.10 _ _( 61.89 i Step 3 - Precipitation Data Soucre ' Location of Precipitation Dala: Vadkinville 6E -COOP sta. 319675 Staring Year of Data Record: 1956 Ending Year of Data Record: 2007 Step 4 Values shown in yellow period of Record (Years) = 49 cells are linked to other locations within the Water r.arr� Balance Program Source of Data: State Climate Office of North Carolina (http://www.nc- climate.ncsu.edu/( I Lissara DWQ Water Balance Drip.xls Precip Version 5 December 2004 calctifations c$loulations Calculatlons. � ��5��\� -�a J Calculations Note: Pnriod of recoM for Temperature date shoultl match period of record for Precipitation data Influent, Lagoon Storage, and Zone SetupWorksheet Am 51 D.. gn Day Total Fl9 to be DI9Poad mNI Fl9w t9 Daily Flow to wetted Lagoon Flow OnDuentl (Annual All Zonae Zonet Acreu9a AvaraHd) Calculate the ad)uetad lnfoont loading by Including the gei^e acm gebldry gtleldey ecron the 5lera Lagoon, and up the Spray and louu ageat up Zone .,...and individual Zona llowrtlae 290 M1,8M 9a1✓dry gelNdry e0,3B7 M.85 Ctick m each atop box 83,257 • • 83,257 ehou Id ba In. Pete Dab Daq Mn EvaR Dele P.IP Lagoon Gain. a Louea NDuent o9ue1 (Intwk)• 0.45 Ste 1 Zone 1 Pan NP-P L eaIgn DVome Eve ion Gene LoeEaeP em parnt L geL«G�ainat8 Volurna, to Irrigationp^r Month 1mM11 D9N PanuWN precip Pan DN"� Inches Inchae Inches 9s0one 9ellone 9ellone 9ellone 9ellone Inches Janus ry 31 C30 0.21 4.0 231,034 40.417 ;499,1140 ;M1,458 1,812.W Feb.., m 1.88 1.37 3.94 2t4,003 74,5M ;257,920 2.397,488 1,M1,116 Im March 31 3.69 2.59 5.03 273,1109 140,287 ;490,11140 ;0 2,670 1 072,301 April W 4.01 144 4.14 224.758 1110,11413 ;419,200 ;457,313 1,811 1o10 Im Mry 31 9.16 431 4.45 241,707 234,1S9 ;4H,840 ;307,388 1,A2,307 1.99 June M 8.93 4.M 4.58 M.013 25;025 2,419,200 2,415,788 -Ter! -1.910 July 31 a." 4.87 5.13 278,748 2M,SM ;499,BM 2,514.019 11,11IT;307 1.89 Auquad 31 6.21 435 4.43 2MA52 2311,050 2,499,840 ;SM,M2 1,872.307 1.98 9eptwnber 30 4.01 3.23 4.M 241,079 175,23g 2,419,200 ;405,040 1,H1,H0 j 1.93 October 31 3.29 2.30 4.12 223,501 125.M 2A99,040 2,590,270 1,g7;M7 ) 1.99 November 30 201 1A1 ].]8 10,321 78,409 ;N9,2M ;328,115 1,H1,H0 ) 1.9J December 31 tA1 0.89 4.10 222,g73 33,599 ;lH,g10 ;gM,115 1,H;]01 t� 1�H�� Tolele. 395 I 344o 51.H ;e23,2e5 1,997,M9 29,433,eoo 30,3N,Hg 22,ON,g08 2143 1$Bpp Source of PAN Evap. Data Step 6 I Other (List Below) Lissara DWO Water Balance Drip.xls Influent+Zones Setup Version 5 December 20D4 Ie 3 Zone 4 Wetted� Daily Flow to We^etl A ga ��I, Zanne Ace ego sere. geladey .erne 8.83 it a.386 1.D8 Zone 6 Daly Flew le Welled iom6 Aersega I gelMdry scree 0 0.00 Zone 6 Dolly Flow ro WNted coma Aenega Zone 7 Dolly Flow to We Zane? Aeraega Zone 8 Delhj Flow to Wetted Zoneel Acreage gele/dey eem Zone 9 Zone 10 it Daily Flaw m Wmmd Dnlly Flow to Weaetl i,� 2one9 Acrnngn Znne fO Acreage j!y-gnlNde, �y eem f l 0.00 '� g.+laltlny ncros geWday gnlnlday acres 0 0.00 0 0.00 0 0.00 0 0.3e I. Rate 0.1 e (InN�Y)• In. Rota (INwM)• In. R.I.r. ��hvk) It, en R hnlwkl. Ire Rate nlw (I M)• Ph. RMa Inlw ( k)• I n. Rata I� Ilnlwk) a � � zonal nigtion pr month Volume toM Dlepoead 2ona,l Dselgn Irrlgetlon per month Zone6 Volume to be Dlepoead Zones Dxlpn Irrlgetlon par month Zone6 Volume to be Me,." Zones OmlgnZoneT Irrlgetlon per month Volume robe Dispoed zone] DeslgnZoneaDeslgn Irrlgeaonper month Volume to ba Dieposetl Za:0 Irrlgetlon par month ZomB Volumeto ba Dlapoaad HE] Zone 10 Volrmw lobe Dlepoesd 2orn,0 D.eln Irti,ation par meMh inches gelbne Inchm gellone Inchm Inches gellone Inches gellone InImhwr- U.00_ Da r- o.Oo- a rO.Op-0 r- UAO- O O.gO Q00 0 000 0 0.00 0 Q00 0 000 169 131,11e 1.69 0 000 Plon, 0.00 0 0.00 0 000 0 Q00 0 400128.800 1.6e0 0.m 0.00 0 0.00 o 0.00 0 0.00 0 OAO1.68 1II,1Te 1.60 O 0.00 0.00 0 0.00 0 0.00 0 0.011 0 0.001U lie,ee0 tAe 0 0.00 0.00 0 000 0 0.00 0 nog 00.00 0.00 0 0.00 0 O.M 0 0.00 01.69 ,do,1T6 1.SB 0 0.00 I m 0 Ow 0 0.00 0 0.00 0 Q00 1.0 12e,Mo t.0 0 0.00 0 a00 0 0.00 0 0.00 0 0.00 0 o.olo 1.s9 ,ll,ne 1.52 0 0.00 0 aoo a 0.00 0 OM o 0.00 0 Mm 1.0 u4esD 1.6e 0 0.00 o QOg o 0.00 0 6.00 0 MOD 0 O.Oo �.ee- o L_o.00 - 0 L- g.0o- o L_-o_ao - 0 L- o.00- 0 1- o_DD - 0 L_ 0-0-0- 0 0.00 0 0.00 ilT6 1,6ee,0e0 tlT6 0 0.00 0 0,00 0 0.00 0 0.00 6m Lissam DW4 Water Balance Drip.rls Influent+Zones Setup Version 5 December 2004 I 1 i Soils and Water Balance for Zone 1 Zone 1 Description: 11 Calculate Soil Drainage f x Kest Drainage vertical hydnullc Drainage factor (f) conductiviry (Ks Rate Inthr in/dry percent Infdry 17 0.03 067 0 100 1 r 000 Month poserFPET]Drainage 11Loss Precip nth Inches Inches Inches inches January 31 1.20 2.08 3.28 4.25 February 28 1.63 1.90 3.51 3.94 March 37 2.85 2.08 4.93 5.03 April 30 4.15 2.02 6.17 4.14 May 31 5.12 2.08 7.20 4A5 June 30 5.53 2.02 7.55 4.58 July 31 5.60 2.08 7.68 5.13 August 31 5.14 2.08 7.22 4.43 September 30 3.88 2.02 5.90 4.44 October 31 2.91 2.08 4.99 4.12 November 30 1.75 2.02 3.77 3.38 December J1 1.11 2.08 3.22 4.10 Totals: 365 40.90 24.53 65.43 51.99 Soils Series Information for Zone i Potential site limitations Water table risk of Is bedrock < Series Name Drainage class depth (BLS) perching 80' BLS? BLS -below land surface Cecil well >3.0 low no Click the Copied from Influent a Zones Setup Sheet: I "CALCULATE" galsiday button after making changes. acres Flow• 60.397 1 Area 34.65 Manual Calculated Actunl Used Override Maximum Maximum Mazimum Allowable Allowable Allowable Irrigation Irrigation Irtigatlon Inches Inches Inches 15.82 1 1 29.92 CAUTION: Maximum Allowable Irrigation Us is greater than the Calculated Max. Allow. Irrigation. Design per Inches Zone 1 Cummulative Storage Requiretl for IMgation Zone 1 Actusl Monthty IMgatlon FYI ��ly Excess Inches Inches Inches 421 j3.18 � ; 0.78 -0A8 3.64 j 1.32 0.15 1 3.48 1 2.14 57 1 1.51 1 3.90 2.13 I 0.D0 1 3.50 2.18 0.00 1.93 11,68 r_-____-000 _00-1 1.99 1.75 1.89 0A8 r~.00 1 1.93 -0.03 I m 1.98 -OAS I OA9 j 11,47 Om 23A3 -4, 23.43 Maximum Monthly Storage Required for the Irrigation of Zone Inches acres gallons 3.64 over 34.65 - 3,423,585 Version 5 December 2004 Lissara DWO Water Balance Drip.xls Z1 I I I I I I I I I I I Soils and Water Balance for Zone 2 Zone 2 Description: I Calculate Soil Drainage f x Ksat vertical hydraulic Drainage Drainage conductWiry IKsaO taCtOr m Rate Inmr I I in/day I I percent Solis Series Information for Zone 2 Potential site limitations Water table risk of Is bedrock c Series Name Drainage class depth (BLS) patching 80" BLS 7 BLS - below land surface Wilkes wall >3.a motlerate yes Click the Copied from Influent 8 Zones Set Setup 02j L2.41 j 0.100 0.04 1 (Daily Flow= 5,147 Zone 2 Area - 4.92 Days Zone 2 Zone 2 Month per PET Soil Total Precip month Drainage Loss Calculated Maximum Allowable Irrigation Manual Override Maximum Allowable Irrigation gcyual Used Maximum Allowable IMgation Design Inigal per Month Inches inches Inc hes Inches inches inches inches Inches January 31 1.20 1.27 2.47 4.25 0.00 -0.03 -0.03 1.19 February 28 1.63 1.15 2.78 3.94 0.00 0.59 0.59 1.08 March 31 2.85 1.27 4.12 5.03 0.00 1.33 1.33 1.19 April 30 4.15 1.23 5.38 4.14 1.24 3.11 3.11 1.16 May 31 5.12 1.27 6.39 4.45 1.94 3.31 3.31 1.19 June 30 5.53 1.23 6.76 4.58 2.18 3.32 3.32 1.16 July 31 5.60 1.27 6.87 5.13 1.74 2.66 2.66 1.19 August 31 5.14 1.27 6.41 4A3 1.98 2.92 2.92 1.19 September 30 3.88 1.23 5.11 4A4 0.S7 1,60 1,60 1,16 October 2.911.274.18 4.12 0.07 7.15 November 14L. 1.75 1.23 2.98 3.38 0.00 Fjq 0.69December 31 1.td 1.27 2Ai 4.100.00 -0.26 1.19 Totals: 365 40.90 14.98 55.88 51.99 9.83 20.37 I 14.06 -,J,.' 14.06 Maximum Monthly Storage Required for the Irrigation of Zone 2: CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max. Inches acres gallons Allow. irrigation. 3.71 over d.92 = 496,056 Lissara DWO Water Balance Drip.xls Z2 Version 5 December 2004 I 1 1 I I I 1 I 1 1 Soils and Water Balance for Zone 3 Soils Series Information for Zone 3 Potential site limitations class Water able risk of Is bedrock Zone 3 Description: Series Name Drainage< depth (BLS) perching 60" BLS 7 BLS v below land surface Calculate Soil Drainage Congaree well-motl well 2.0->3.0 moderete no S 1 1 x Kest D O D O vertitai hydraulic factor (1) Drainage conductivlly (Ksa[) Rate Click the inthr In/day percem inlday Copied from Influent 6 Zones Setup Sheet: "CALCULATE" 0.02 0.53 0.100 0.05 Daily Flow • 13,417 galstday button after making Zone 3 Area • 9.62 acres changes. Zone 3 Zone 3 Calculated Manual Actual Used Override Cummulative Days Zone 3 NZo"e,13 Maximum Maximum Maximum StorageMomh perPET Soil PrecipAllowable Allowable Design Irrigation Monthly Required for Drainage Irrigation Irrigation Irrigation per Month Excess Irrigation Irtigation Rate Inches Inches Inches inches Inches Inches inches Inches Inches Inches Inches January 31 1.20 1.64 2.84 4.25 0.00 0.33 0.33 1.59 -1.26 i 3.35 0.33 February 28 1.63 1.48 3.11 3.94 0.00 0.92 0.92 1.44 -0.52 i 3.88 I 0.92 March 31 2.85 1.64 4.49 5.03 0.00 1.70 1.70 /.59 0.11 ( 3.77 I 1.70 April 30 4A5 1.58 5.73 4.14 1.60 3.47 3.47 1 1.54 1.92 I 1.85 1 3.47 May 31 S.t2 1.64 6.76 4.45 2.31 3.68 3.68 1.59 2.08 0.00 i 3.44 June 30 5.53 1.58 7.11 4.58 2.54 3.68 3.68 1.54 2.13 F 0.00 1.54 July 31 5.60 1.64 7.24 5.13 2.10 3.02 3.02 1.59 1.43 r0 1.59 August 3t 5.14 1.64 8.78 4.43 2.35 3.29 3.29 1.59 1.70 O.W 1.59 September 30 3M 88 1.58 5.46 4.44 1.02 1.95 1.95 1.54 0.41 r�O.OD 1.54 October 31 t.e4 4.55 4.12 0.43 1.51 1.51.59-0OB 0.08 1.51 FYI November 30 1.58 3.33 3.38 0.00 t.04 1.04 1.54 -0.50December 3t 1.64 2.76 4.t0 0.00 0.08 0.08 1.59 -1.51 L 2.09 J 0.08 Totals: 0®- ®®51990365 40 90 0 1 oo a Maximum Monthly Storage Required for the Irrigation of Zone 3: CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max. inches acres gallons Allow. Irrigation. 3,88 over 9.62 1,012,424 Lissara DWQ Water Balance Dnp.xls Z3 Version 5 December 2004 Soils and Water Balance for Zone 4 Soils Series Information for Zone Potential site limitations Zone 4 Description: Series Name Drainage class dater table I� risk of n Is bedrock c pth (BLS) I perching I I 60" BLS 7 gLg • below land surface Calculate Soil Drainage Altavista I I mnt mod weI2.M.o �� moderate I no St� SI teb 2 1 IFr-- x Ksat �� I I I I toondu draulic factor (� Drainage (Ksaq Rate Click the iNdaypercent in/day Copied from Influent a Zones Setup Sheet: "CALCULATE" 0.53 0.100 0.05 Daily Flow = 4,296 galsiday button after making Zone 4 Area m 3.08 acres changes. Calculated ManualctalUsed Override Zone 4 Zone 4 Mezimum Maximummomh PET]Drainage Lore Pre cip Allowable Allowable Irt gatloln Dazlgn Irrigation MomhN Imigatlon Irflgation Rate per Month Excess Inches inches Inches Inches Inches Inches inches Inches Inches Inches Inches January 31 1.20 1.84 2.84 4.25 0.00 0.X1 0,33 1.59 •1.28 3.J5 1 0.33 February 28 1.63 1.48 Ill3.94 0.00 0.92 0.92 1.44 -0.52 3.88 0.92 March 31 2.85 1.64 4.49 5.03 0.00 1.70 1.70 1.59 0.11 I 3.77 ( 1.70 April 30 4.15 7.58 5.73 4.14 1.60 3.47 3.47 1.54 1.92 1.85 3.47 May 31 5.12 1.64 6.78 4.45 2.31 3.68 3.68 1.59 2.08 0.00 3.44 June 30 5.53 1.58 7.71 4.56 2.54 3.68 3.68 1.54 2.13 0.00 1.54 July 31 5.80 1.64 7.2d 5.13 2.10 3.02 3.02 1.59 1.43 0 OD 1.59 August 314 t.64 6.78 4.43 2.35 3.29 3.29 1.59 1.70 f 0.00 1.59 September 30 3.88 1.58 5.46 4.44 1.02 1.95 1.95 1.54 0.41 rr O.W 1.54 October 31 2.91 1.64 4.55 4.12 0.43 1.51 1.51 1.59 -0.08 0�08 rr 1.57 FYI November 30 1.75 1.5a 3.33 3.36 0.00 1.04 1.04 1.54 -0.50 I 0.58 I 1.04 December 31 1.14 t.6! 2.79 4.10 0.00 0.08 0.08 1.59 -1.57 l_ ®® ®®� Totals: 365 40.90 19.27 60.17 51.99 12.35 24.66 18.75 18.75 Maximum Monthly Storage Required for the Irrigation of Zone 4: CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max. Inches acres gallons Allow. Irrigation. 3.88 over 3.06 324,194 Lissara DWQ Water Balance Dnp.xls Z4 Version 5 December 2004 Zonal Storage Summations OBJECT: Toalmdef."a minNwmend.16orworse, required for a nmMple zoned "ray inlpedon the Zone 1 Zone 2 Zone 3 Zone 4 Zone 5 Zone 6 Zone T Zane 9 Zone 9 Zone 10 Totals emwn es,ew neeemnYaaeN.» TaW Rlew e].fsi p.R'rbwmzene»> q,]N We 5ne We 1]A1l Wa e30a OPe a p" O o we a we o Wa v ppe a We" �r vim CWmNNve 9ro ReWtM nlpr ClmmuWXe RpW�~p� ClmmluYtive 8[wa R[Terea q CUmmueeve Bmnq R<Pa�re—e—� CYNnmtlWe CIVT6411ve 11npe ClmlMvan Bmrape CummWellve Sm CummlMYeera PeWrne e � PaWYea Re91Arce rape P[Wn4 �v —r� ClalimlbgepMepe PeWP<e CUmmuYNe 9lpa e PeWlne p 1 F 1r I r Ir r 7F 1.65p.55] Il qlm Rawl,vd Ron"Iprearlel ---------- 111. Mnemm ]terepe • 5,356,260 aMa elvitleE fry Raw we • 65,1 dv v >,,, I FYIMheden Pew�n�f Liam. MO Wana 9aume Ora to arel Suns Vamm S Oe[enaer2o05 A Spray Irrigation Water Balance for Permit No: Lissara Spray Irrigation System Permittee Name: Contact Name: Address: Facility Lissara WWTP Address: Water Budget Prepared By: John F. Phillips, P.E. - Diehl & Phillips, P.A. Lissara DWQ Water Balance Spray.xls Project Id Version December2004 Enter Data ===->= Precipitation Worksheet- FYI Calculate the precipitation for an 60th percentile "wet' year, based on long term data (approx. 30 years or greater). Click on each step box Precipitation Data Step 1. -. Step 2 - Step 3 - Precipitation Data Soucre 80th Percentile Mean Monthly Percent of Mean Monthly Month—�I Precipitation Annual Precipitation Precipitation Pre inches percent .:.: inches Location of Precipitation Data: Yadkinville 6E - COOP sta. 319675 January 3.68 I 4.25 1 February 3.41 �3.94 —1 Staring Year of Data Record: A958 March April 4:35 3.53 r 1 4.14 1 Ending Year of Data Record: 2007 Step 4 j67 May June 3.85 3.96'- 1 4.45 15.03 Values shown in yellow l4.58 1 Period of Record (Yecells 4.83 are linked to otherJuly 5.13 { locations within the Water yu August 3.83 852{ 8.52 { 4.43 { Balance Program Source of Data. September 3.84 8.54 I 4.44 { State Climate Office. of North Carolina (http://www.nc- I October 3.56 7.92 {� 4.12 climale.ncsu.eduQ November 2.92 6.49 3.338 December 3.55 7.89 4.10 I TOTALS = 44.97 100.00 5t99 ��Iirl��rtr••�n,��t,hi�t�n�i ,r�rh•sr;� Lissara DWQ Water Balance Spray.xls Precip Version 5 December 2004 i I 1 I I 1 1 1 1 1 1 1 I i I 1 I 1 1 P4_ "I �. Ste 2 4 �' Sfe 3,m'` � Ste 4. � Zone 1 Zone 2 ZI Influent, Lagoon Storage, Total Flosed he and Zone SetupWorksheet Arca of Oesi9n Daily Disposal Total Fla Slo Dolly Flow la Wetted Daily Flaw to Wetted Daily Flaw to Lagoon Flow (In/IuenQ (Annual All Zane Zvnvt Acrvagv Zone 2 Acreage Zone 3 AvvrageJ) Calculate it,. adjustor Influent loading by including the gams acres 9alslday galsltlay acme galsltlay acres galsltlay and I seas Rom line Storage U.00n, and at up the Spray "Zones areas and intllvlJual Znnv flawrales. 1.46 89,120!I. galsltlay gals/day 6T.�T64, ,. t3b.84 3,438.3.1.4,_ Click on each step box 71,031 71,031 Enter Data =_> I Pan Evap. Data precip Lagoon Gains & Lasses Inlluent should be In. Rate 0.42 b" Rate 0.25 Irr. Rate J equal (Inlwk)= linlwkl= (inlwkl= Ste 1 Zone 1 Zone 2 Days Pan Elllfl Design Influent Tvtal: Inlluent+ Zen, Design Zane 2 Design Zone 3 par Evaporation AJjusted G[L�j Volume per Lagoon Ga ns 8 Volume to be Irrigation per Volume to be Irrigation per Volume to be monllI Data anaarp Month Losaes Olsposetl moniM1 Olsposetl month Disposed inches Inches Inches 9allans 9ailons gallons gallons gallons Inches 9a lions inches 9allens January 31 1l0I 10 262,508 February 28 1kr`51.867, J1 1.37 3.94 166,281 54,389 1.935,360 2,037,252 1.617,112 1 1.66 85,064 1 1.00 337,1 D4 March 31N2.58 5.03 199,3n 102,395 2142,720 2,239,686 1,790,374 1.84 94,178110 262,500 April 303.44 4.14 ifi4,0]2 1Jfi,2492,101,423 1,732,620 1.78 91,140 1.07 254,040 May 314.J1 dA5 176,446 170,936 2,142,720 2,140,230 1,790,374 1.84 94,178 -0.70 2fi2,500 June 304.64 4.68 181,400 183,978 2,0]3,600 201,109 1,7R,620 1.78 91,140 1.07 254,040 July 31 4 4.87 5.13 203,406 193,135 $142,72D 2,153,0]1 1,190,174 1.84 94,178 1.10 262,508 August 31 4.35 4A3 175,530 172,J23 2,142,]20 $145,926 1)90,374 1.84 94,178 1.10 262,59e September 30 g"q §wir 3.23 4.44 175,988 127,934 2,0]J,600 2,121,663 1,732.620 1.78 91,140 1A7 254,040 October 31 4� r2_ ,.. 2.30 4.12 163,155 91,295 2,142,720 2,214,500 1,790,374 1,84 94,178 1 1.10 262,508 November I 30 P. 3.30 133.624 66,776 2,073,600 2,151,648 1,732,620 1 1.78 91,140 1 1.07 254,040 December 31 A 0.99 4.10 162.697 39,127 3,142,72D 2,266,291 1,790,374 1:._ .1.04 94,178 I 1.10 262,508 Totals: 3fi5 F 34.40 sn. I 2.060,983 1,363,603 35,220,000 25026,181 21,080,210 21.69 1,100,--- 13.01 3,1390,820 Source of PAN Evap. Data t �, Other (Ust Bciow� ' Lissara DWQ Water Balance Spray.xls Influent+Zones Setup Version 5 December 2004 i I 1 I I I I I 1 I I I I I I I l I le 3 Zone 4 Zone 5 Zone 6 Zone 7 Zone 8 Zone 9 Zone 10 Wetted Aceage Daily Flaw to Zone 4 Wetted Acreaga Daily Flow to Zone 5 Wetted Acreage Daily Flow to Zone B Wettetl Acreage Daily Flow to Zone ] Wetted Acreapo Daily Flow to Zone81 Wetted Acreage Daily Flow to Zone 9 Wetted Acreage Daily Flow to Zone 10 Wetted Acreage acres 9al¢Iday 9alsltlay acros galslday cres galsltlay acros galaltlay M. gals/day galslday acres ". .8.58'}It�R12 0.00Ougl {I` t'S!' ' i� w�p.00c• 4 s, e0.00 , ... 0 e{ c; �:&l O.00e?}l,, O' C , 0.01.' �. 0.33 Ire Rat. 0.21 Iinlwkl= Ir, Rate Ilnlwkl= In. Rate Iinlwkl= In. Rate Iinlwkl= In. R.I. Iinlwkl= III. Rate linlwkl= lo. Rate Ilnlwkl= Zone 6 Zone 6 Design Volume to be Irrigation per Disposetl month Zane 3 Design Irrigation per man1M1 Zone 4 Volume to be Disposed Zoa.4 Design Irrigation per month Zonv 5 Volume t. be Disposed Zone 5 Design Irrigation per month Zane ] Volume to be Disposed Zane ] Design Irrigation per month Zane 8 Volume to be Disposetl Zone 8 Design Irrigation per month Zone 9 - Volwne t. be Disposetl Zone 9 Design loigatlon per month Zone 10 Volume to be Disposed Zonc 10 Design Irrigation per month inches gallons incM1es gallons Inches gallons IncM1es gallons inches gallons Inches gallons Inches gallons Inches I 0.00 I 1.4] 54,901 I. 0.94 0 I 0.000 I 0.00 D I 0.00 0 I 0.00 0.00 0.00 0 I 0.00 0 1.33 49,6B8 0.85 0 000 .: 0 I 0.00: 0 I 0.00 0. 0 0 0.00 0.00 0 0 0.00 0.00 1:47 54,901 0.94 0 0.00 0 O.OII 0 ` 0.00 0 1.43 53,1 ]0 0.91 0 0.00 0 0.00 0 0.00 0 0.00 0.00 0 0.00 0 0.00 1.47 54,901 0.94 0 0.00 0 0.00 0 0.00 0 0 0.00 0 0.00 1.43 53,130 0.91 o O.00 0 0.00 o O.Oo 0 0.00 0 0.00 0 0.00 0.00 0.00 1.47 54,901 0.94 0 0.00 0 0.00 0 OAO a 0.00 0 0.00.. 0.00 0 0 1.47 54,901 0.94 0 0.00 0 0.00 0 0.00 0 0.00 0 1.43 53,130 0.91 0 0.00 0 0.00 0 0.00 0 0.00 0 0.00 0 0.00 0.00 1.47 54,901 0.94 0 0.00 0 0.00 0 0.00 0 0.00 0 0.00 0 I 1.43 53,130 I 0.91 0 1 0,00 0 I 0.00 0 I 0.00 0 I 0.00 a I 0.00 0 I 0.00 I 1.47_11 64,901 I-A.94 0 I.�0.00 ^.' 0 I 0.00 0 I. OAO 0.00 0 I- 0.00 0 I 000__ 0 I 0.00 0.00 17.35 6d6,415 11.07 0 0.00 0 0.00 0 0 0.00 0 0.00 0 Lissara DWD Water Balance Spray.xls Influent+Zones Setup Version 5 December 2004 I WE Soils and Water Balance for Zone9 Soils Series Information for Zone 1 Potential site limitations t� Water table tlapth risk of Is bedrock < Zane 1 Description: I Series Name Drainago class (BLS) perching 60" BLS? BLS = below land surface Calculate Soil Drainage r;. Cecil weu >3.0 low no nm* f z Ksat In-snu salmaletl vertical Sail , hydraulic contluctivily Drainage Drainage factor (g--- (Ksal)Rate - Click the m1hr in/tlay percent inlday Copied from Influent & Zones Setup Sheet "CALCULATE" 0.03. 0.67- O,t6q Daily Flow= 57,754 galsiday button after making changes Zone Area 35.80 acres Zone i Zone i Calculated Manual pdual Used Override Commutative Zone Maximum Maximum Maximum StorageSoil Actual Days per Zone 1 Required for Monthly Month ❑ PET Drainage ❑ PreaP Allowable Allowable Allowable Design Irngation Monthly month Total Loss Irrigation Irrigation Rate Oralnage Irrigation Irrigation Irrigation per Month Excess inches Inches inches inches,. inches inches inches inches inches inches.._. Inches January 31 1.20 2.08 3.28 4.25 0.00 0.78 0.78 1.84 -1.06 2.0u 0.78 February 28 1.63 1.88 ].51 3.94 0.00 1.32 1.32 1.66 -0.34 ) 3o3 ( 1.32 March 31 2.85 2.08 4.93 5.03 0.00 2A4i- 2.14 1.84 0.30 '.,. 273' I 2.14 April 30 4.15 2.02 6.17 4.14 2.03 3.90 3.90 1.78 2.11 +.. 0.62 3.90 - May 31 5.12 2.08 7.20 4.45 2.75 4.12 4.12 1.84 2.28 ) 0.00 ) 2.46 June 30 5.53 202 Z55 4.58 2.97 4A1 4.11 1.78 2.33 t 0.00 ) 1.78 July 31 5.60 2.08 7.68 5.13 2.55 3,47 3.47 1.84 1.63 i 0 00 1.04 August 31 5.14 2.as 7.22 4.43 2.80 3.74 3.74 1.84 1.89 I ' o 1.14 September 30 3.88 2.02 5.90 4.44 1.46 2.39 2.39 1.78 0.60 0.00 ) 1.78 October 31 P1. .91 2.08 4.99 4.12 0.88 1.96 1.96 1.84 0.12 ) 0.00 i 1.8d FYI November 30 .75 2.02 J.77 3.38 0.39 1.47>. 1.47 1]8 -0.31 r 0.31 1.47 December 31 142.08 3.22 4.10 6.09 0.53 0.53 1.84 -1.3t _ 1.61 'y 0.53 jKON Totals: 365 40.90 24.53 65.43 51.99 15.82 , t h 2992 27.69 21.69 Maximum' Monthly' Storage Required for the Irrigation of Zone 1: CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max. Allow. inches acres gallons Irrigation. 3.03 over 3580 2,947,803 _ Version December 2004 Lissara DWQ Water Balance Spray.xls Z1 Soils and Water Balance for Zone 2 Soils Series Information for Zone 2 Potential site limitations Water table depth risk of Is bedrock < Zone 2 Description. I Series Name Drainage class (BLS) perching 60" BLS Y BLS = below land surface Calculate Soil Drainage Wilkes well >a.o moderate yes - Step1= r.Ste 2 fx Ksat In -situ saturated vertical So" Drainage hydraulic conductivity factor (f) Drainage Ksat Rate Clink the Inlhr In/day percent In/day Copied from Influent& Zones Setup Sheet: "CALCULATE 0,02 0.41 Od00 � 0.04 Daily Flow 3,038 galsiday button after malting changes. Zone 2 Area = 3.14 acres Zone2 Zone2 Manual Calculated Override71rngtUion Gum mutative Zone Maximum Maximum Storage Actual Re ulred forEH�PET Soil PreciP Allowable AllowableDesin Irrigation MonlhlY 9 Drainage Tatal Loss Irri align Irri anon Irrigation 9 9 9per Month Excess I L�. inches Inches inches Inches Inches inches Inches Inches inches Inches inches L-January 31 1.20 1.27 2.47 R4.45 000 A.03 .0.03 1.10 .1.14 1 291� -0.03 February 28 1.63 115 2.78 0.00 Q.59 0.59 1.00 -0.41 (. 3.32 - I 0.59 March 31 2.85 1.27 4.12 000 ;.,�„A3, 1.33 1.70 0.23 �:.. 3.09 ( 1.33 April 30 4.15 1.23 5.35 124 M-0 3.11 1.07 2.04 ( 1.05 I 3.11 May 31 5.12 1.27 6.39 1.94 3.31 7d0 2.21 0.00 I 2.15 June 30 5.53 1.23 6.76 2.18 3.32 1.07 225 I 0.00 I 1.07 July 31 5.60 1.27 fi.87 1742.66 1.10 1.55 1 000August 31 SA4 1.2] 6.41 1.98 2.92 1.10 1.82 (O.00 1.10 4.44 067 1.60 1.07 0.53 i 0.00 I 1.07 October 31 2.91 1.27 4.18 4.12 0 07 1.15 1.10 O 04 10.00 1.10November 30 1.75 L23 2.98 3.38 000 0.69 1.07 -0.38 00.69 December 31 1.14 1.27 2.41 6.10 0.00 -0.28 1.10 -1.39 r 1 77 t -018 '_s_I ��F�� Totals: 365 do.90 14.98 55.88 51.99 9.83 20.37 73.01 �' 13.01 Maximum Monthly Storage Required for the Irrigation of. Zone 2: CAUTION: Maximum Allowable InicJation Used is greater than the Calculated Max. Inches acres gallons Allow. Irrigation. 3.32 over 3A4 q 282,881 Lissara DWQ Water Balance Spray.xls Z2 Version 5 December 2004 I I 1 I I I I 1 1 1 I I 1 I 1 I I I Soils and Water Balance four Zone 33 Zone 3 Description. l Calculate Soil Drainage C Step 1 ` Sfep �2j f x Ksat` ICE r.rtu saturated veN al ❑ Soilg L Drainage h tlraulic conduchvd Drama e factor (f) R Soils Series Information for Zone 3 Series Name Drainage class Congaree well-matl well I� Potential site limitations Water table depth risk of Is bedrock < (BLS( perching 60" BLS 7 BLS = below land surface 2.0-13.0 moderate no IMF . Ksaq ate Clirh the nlhr in/day percent inlday copied from Influent & Zones Setup Sheet: CALCUI AYE" 0.53 Month Dmo�ih r PET EEL January 31 1.20 February 28 1.63 March 31 2.85 April 30 4.15 May 31 5.12 June 30 5.53 July 31 5.60 August 31 5.14 September 30 3.88 October 31 2.91 November 30 1.75 December 31 1.14 Totals: 365 40.90 0.05 Daily Flow= 8,46a galslday button after making changes. Zane 3 Area = 6.56 acres Zone 3 2one 3 Manual [;g Actual Used Overntle Commutative I I Zone Maximum Maximum Storage Actual Poz�-- 3 Required for Mantitly Soil . PreciP Allowable Allowable Design Irrigation . Monthly Drainage ass Irri anon Irri anon Irrigationg g 9 per Month Excess inches inches inches inches inches inches inches inches inches inches 1.64 2.84 4.25 0.00 1'""Q.3Q,} 0.33 1.47 -1.14 2.92 1 0.33 1.48 3Al 3.94 0.00 0.92 1.33 -0.42 1 3.34 t 0.92 1.fi4 4.49 5.03 0.00 r% 1.70 1.47 0.22 1 3.11 ( 1.70 1.59 5.73 4.14 1660 ,»,9�4, 3.47 1.43 2.04 1 1.07 1 3.47 1.64 6.76 4.45 2.31 ir`�, :6 § 3.68 1.47 2.20 I 0.00 t 1 2.55 1.5a 7.11 4.58 254 ,4r. 3.68 1.43 2.25 1 000 ". 1 1.43 1.64 5.13 1.64 4.43 1.58 X 4.44 1.64 4.12 1.58 J.38 1.64 4.10 1927.60.17 51.99 2.10 ?-a,.-BiQ. .:. 3.02 1.47 t.ss F____o0� 1.47 2.35 -r'; 3.21k 3.29 1.47 1.82 r 0.00 �l 1.47 102 t2 1.95 1.43 0.53 1 0.000 1.43 oa3 #5,"hV dx71i 1s1 1.a7 o.oa �� ta7 s+Ir, pYl 0.00 r`b`p x 1.04 1.43 .0.39 ,1 0 39 1.04 0.00 1.47 -1.39 1. 7.78 � 0.08 12.35 24.66 iL35 Maximum Monthly Storage Required for the Irrigation of Zone 3: CAUTION: Maximum Allowable Irrigation Used Is greater than the.CalculateddMax; inches acres gallons ".Allow. Irrigation. 3.74 Over 6.56 594,160 Lissara DWQ Water Balance Spray.xls Z3 Version 5 December 2004 Soils and Water Balance for Zone 4 Zone 4 Description: Calculate Soil Drainage y *:;:`, STep.1 Step 2', f x Ksat 1-situ saturated vertical Soll Drainage hydraulic contluctivity /actor (I) Drainage (Ksat) ❑ Rate III in/hr i0p - ercent In/day 902 0.53 0.100'JF 0.05 [E[y p ❑ Zone 4 ❑ Imonthr PET Soil 'Total Loss PrOci Drainage EEL] inches inches inches January 31 1.20 114 2.84 4.25 F ar h 10 4.15 1.64 4.49 5.03 March 31 2.05 1.fi4 4.49 5.03 July 5.60 August5.14 September $30 3.88 October 2.91 November 1.75 1.64 6.76 4.45 1.58 7.11 4.58 1.64 7.24 5.13 1.64 6.78 4.43 1.50 5.46 4.44 s: 3fi5 40.90 1927 Total Soils Series Information for Zone 4 Potential site limitations Water table depth risk or Is bedrock < f� Series Name Drainage class (BLS) perching 60" BLS ? BLS = below land surface I Altavista mod well 2.n-00 moderate no - Calculated Manual Overntle Maximum Maximum Allowable Allowable Irrigation Irrigation inches inches 0_00 0_00 1.60 2.31 2.54 2.10 0.00 60.17 51.99 II 12.35 - Click the Copied from Influent & Zones Setup Sheet: 'CALCULATE" y Flow = 1,771 galslday button after making changes. e 4 Area 2.15 acres Zone 4 Zone 4 Actual Use' Cummulative Maximum 'Storage Actual Allowable Design Irrigation Monthly Required for Monthly Irrigation per Me,,i Excess Irrigation Irrigation Rate inches inches inches Inches inches 0.3] 0.94 .0.61 'I 1.47 -W' 0.33 0.92 0.85 0.07 I 140 I 0.92 1.70 11 0.94 0.76 0.64 1 1.70 3.60 1.95 1.51 1.04 0.08 24.66 CAUTION: Maximum Allowable In'igation Used is greater than the Calculated Max. Allow. Irrigation. 0.91 2.56 I 0.00 ( 1.55 " .` FYI' 0.94 2.74 ;1 0.00 0.04 0.91 2.77 1 000 -.. I 0.91 0.94 2.08 F 0.00 t 0.94 0.94 2.35 1 0.00 0.94 0.91 0.94 1.04 0.57 1 0.00 00 0.91 0.94 0.91 0.13 0,00 1 0.91 0.94 -0.86 1. 0.86 11.07 07 Maximum Monthly Storage Required for the Irrigation of Zone 4: inches acres gallons 1.47 - over z.is. ... - 85,578 Lissara DWQ Water Balance Spray.xls Z4 Version 5 December 2004 I I I I 1 I I 1 I 1 I I 1 y Zonc 1 Zone 2 Zone ] Zona 4 Zone 5 Zone 6 2ane 7 Zone 6 Zone 9 Zone 10 Totals n Il Wally in Il a on] W.".mum- con0.,ee gn.Ttic Is ].». ] al flow DIprMom 71,1131 miry Flaw) zone-» si,im aW ]ma eW 8,46a aW tm pW 0 epa o vW 0 8pa a epd 0 aW v apd •d Wel]¢tl Pcr ea 9u ••» J6 al grea L Ilve Slot] pv CYm mu btive Stara ev LummYla11ve 5bra 9¢ LYm mYl o1K51ora 6e r C ulaln'e 5] ge Cum mulal e51ora0c Lu II sbra9e ra Cum mul vllve 5l 9v Cum mule llve 5le ra Be Cu telly Slvrage C TYIa11Ve 5bragv Monin Oaya par � flc9ulrad Raqubea ReVuhaO Re9utreG Re9uhed Re9uirN ReVulaed RMu4ea Re9ulred RNulrea Re9uIrM �� mone. orlon.. lnchea anon. manes anona mcnn mmna loon¢. almn. mcne. mlona 0 allone manes mlona mcnoa morn. mcnaa mlena eanono fli.Ne Wv.tte i"Y'. L6n 61 ].el t.n fine 0 O.O1 0 0.00 0 a,as 0 3.466.741 Im.. v ase .eeru 3B ] ]6¢i a0i ].]] ]N.Y1 >)a 6N 160 ]AO B1 BB1 0.80 0 000 0 0.00 0 0.00 0 v00 0 O.aO 0 ar ].]] te61 B1] ]]]36 a,I 084 0 .09.121 3.6091121 878.700 Oat o] moau ciao o o.w 000 o Boa Oa0 o Boo Boa 0 t.n.30o.ao0 aw 000 0 coo 0 oo0 sea coo 0 In a.aa B 0 0 aro0 0 000 a a M 0 1 0 0 0 0.00 o aoo 0 0 0.00 0 oO0 0.80 400 o aoo o Boo 0 000 0 9aa 0 $e tors.¢, ]a o Bo 0 0 0.00 o Boo 0 o Bao waav v o.00 a Bao o Bao 0 o.qo 0 ana 0 r .00 30 ta]NB an talus, KissBOO 405;92 I,09),594 - Minimum Required Storage (gallons) Miumunl Storage = 3906531 gallons divided By 69120 SO 56.5 days FYI FYI ]dimmum Reruled Statape Lisomm BWD Water Balance Spray As Zonal Sums Version 5 December 2004 A Spray Irrigation Water Balance for Permit No: Lissara Re -Use Drip Irrigation System Permittee Name: Contact Name: Address: Facility Lissara WWTP Address: Water Budget Prepared By: John F. Phillips, P.E. - Diehl & Phillips, P.A. Lissara DWQ Water Balance ReUse Drip.xls Project Id Version 5 December 2004 Enter Data ===->= Precipitation Worksheet FYI Calculate the precipitation for an 80th percentile "vvet' year, based on long term tlaia (appiox. 30 years or greater). Click on eachstep box p Precipitation Data Step 1 Mean Monthly Percent of Mean Month Precipitation Annual Precipitation inches Percent January 3.68. 8.18 February 3.41 7.58 March 4.35 9.67 April 3.58 7.96 May 3.85 8.56 June 3,96 8.81 July 4.44 9.87 August 3.83 8.52 8.54 MD.c..b.r .92 3.55 7.89 TOTALS = 44.97 100.00 I� Step 80tb Percentile Monthly Precipitation inches 4.25_--7.1 35.03 t 4.14:. 4.45 1 4.58 I Values shown in yellow 5.13 4.43 1 4.44 i l 412 1 —� Step 3 • Precipitation Data Soucre Location I Yadkinville 6E - COOP sta. 319675 Staring Year of Data Record: I 1958 Ending Year of Data Record: 2007 `Siep 4 Period of Record (Years) = 49 _ — , 1 " Source of Data. i cells are linked toother locations within the Water Balance Program I State Climate Office of North Carolina (httpJ/www.nc- climate:m:su.edul). C51.99 � I 4.10 5 Lissara DWQ Water Balance ReUse Drip.xls Precip Version 5 December 2004 I I 1 1 1 1 1 i 1 l 1 1 I Influent, Lagoon Storage, and Zone Setup Worksheet Calculate Ibo atljuAml turning loading by including 111e gains antl losses hem the Storage Lagoon, and set up the Spray Zenms areas and individual Zen. flowmtes. Click on each. step box - Enter Data'= LLJ Pan Evap. Data Precip Days per EvaPoralion Atljusletl Month month Data Pan Oata Preci �.. inches Inches Inches January 31 I5 esl. 0.91 4.25 February 28y$ 1.97 J.94 March 31 i$3"� 2.Sa 5.03 April 30 ;,:, i9.,: +e 3.44 4.14 May 31 (g`pF?(66jfiy 4.31 4.45 Juno 30 4F67#1 4.64 4.50 July 31 8'�S„ 4.97 5.13 August 31 i 4.36 4.43 September 30 3.23 4.44 October ]i ,;?�.29_, 2.30 4.12 November 30 2.014 ( 1.41 3.38 December ]1 Y:btr° 0.99 4 .10 Totals: ]65 49]4 34.40 51.99 Stop 2 Area of Lagoon as 2.14 Lagoon Gains 5 Losses Lagoon Gains tram Precip. Lagoan Losses from Evap. gallons gallon 247,207 52,976 229,069 ]9,]20 292,2 6 1150,006 240,489 199,708 258,627 250,550 266,016 269,667 298,260 283,089 267.283 252,584 257,055 1a7,506 239,146 13],816 196,163 01,154 238,474 57,350 ],020 a94 1 998,]OS j Total Flow to be Design Daily Dispostal LT9O6:417 toDaily Flow to Watlmd Dolly Flow 1. Welletl Daily Flow Flow Qnfluentl (Annual Zane 1 Acreage Zen. 2 Aaeage Zone 3 Avemged) 9alsltlay 9alsltlay arms gals/tlay galslday 87,640 9alsltlay 60,906 34.98 6,021 6.53 16,605. 90,641 aboultl bIrr. Rate In. Rate In. Rate influent ogua (inhek)= 0.45 (inlwk)= 0.2] (In/wk)= Zane 1 Zone 2 Design Influent Total: Influent+ Zone 1 Design Zone 2 Design Zone 3 Volume per Lagoon Gains It Volume to be Irrigation per Volume io be litigation per Volume to 1 Month Losses Disposed month Disposed month Disposed gallons gallons galimis Inches 21 gallons inches gallons :4: :520 2865'169 L088.0011 Up 190,988 --1.08 464940 ;]23,040 2,911,3]1 1,808,086 I 1.99 211,451 I 1.19 614,766 755 1 2,723,040 1 2,904,164 1,8a0,096 I 1.99 311,451 1 1.19 2,489,665 14 �04 3],OB],]08 22,230,690 2].41 32,061,600 Lissara DWD Water Balance ReUse Drip.xls Influent+Zones Setup Version 5 December 2004 I 1' I 1 1' 6 t I' 11 1 C F I' Ii D D 1 Ie 3 Zone 4 Zone 5 Zone 6 Zone 7 Zone 8 Zone 9 Zone 10 Wettetl Acreage Da lly Flow to 2one4 Wetted Acreage Daily Flow to Z.neb Wettetl Acreago Daily Flow to Zvn.B Wetted Acreage Daily Flaw to Zone'! Wetted Acreage Oally Flow to Zone01 Wetted Acreage Daily Flow t. Zen. Wettetl Acreegv Wally Flow to Zatty l0 Wettetl Acreage cres quisltlay galeltlay acrca galbltlay acres Oalsltlay galslJay acres galeltlay galaltlay acres 11.92 6,309 4.50 0 0.00 0 O.Oo 0 suss Ires 0.]6 Irr. Rate (Inlwk)' OA5 Irr. Rate Ilnlwkl= I, Rate (inlwk)= Irc Rate linlwkl= In. Rate (Inlwk)= Err. Rate (Inlwk)= Irr. Rate (0tlwk)= Zone 10 Zone 10 Design Volume to be Irrigation per Disposed month Zone 3 Design Irrigation per month Zen.4 Volume to be Drip osvtl Zone 4 Design Irrigation per m.niM1 Zane 5 Velum. to be Disposetl Zone 5 Design Irrigation per month Zone 6 Velum. to be Olspasetl Zone 6 Design Irrigation per month Zonc ] Volume m be Olsposetl Zane ] Design Irrigation per month Zone 8 Volume to be Disposed Zone 0 Design Irrigation per month Zone 9 Volume to be Dlsp... tl Zone 9 Design Irrigation per month Inches gativns Inches gallons inches gallons inches gallons nches gallons Inches gallana inches gallons ncM1es I 1.59 195,579 I 1.59 0 I suss 0 I suss 0 I suss 0 I suss O I OAO 0 I suss 1A4 176,652 1." 0 r 0.00 O 0.00 0 suss 0 suss 0 F 0.00 0 0.00 1.99 195,679 1.59 0 1 O.00c 0 0.00 0 0.00 0 0.00 0 0.00 0 0.00 1.54 189,2 00 1.54 0 1 0.00 O 0.00 0 0.00 0 0.00. 0 '.0.00 a Oer) 1.59 195,579 1.69 0 0.00 0 0.110 0 boss 0 0.00 0 ODO 0 suss L54 169,27a 1.54 0 o.a0 0 OAO 0 000 0 O.00- 0 :V a 0 O.Oo 1.59 195,579 1.59 0 0t0. 0 000 a 0.00 0 0.00 0 00o 0 O.Oo 1.69 195,579 1.69 0 0.00 a 0.00 0 0.00 0 1 0.00 0 0.00 0 0.00 1.54 169,2 00 1.54 0 1 0.00 0 0.00 0 0.00 0 1 000 0 1 0.00 0 0.00 1.59 155.579 1.59 0 0.00 0 0.00 0 0.00 0 0.00 0 1 0.00 0 0.00 I 1.54 189,270 I 1.64. 0 I 0.00 0 I 0.00 0 I 0.00 0 I 0.00 0 I 0.00 0 I 0.00 I_ 1.59 195,579 I 1.58 e I 000 0 I 0so a I OAs 0 I .sure suss 0 I ruts 0 I suss 0 0 18.73 2,]02,785 10.]2 0 0.00 0 0.00 suss 0 0.00 0 suss Lissara DWQ Water Balance Re Use Drip.xh; Influent+Zones Setup Version 5 December 2004 Soils. and Water Balance for Zone 2 Soils Series Information for Zone 2 Potential site limitations Water table tleplh risk of Is bedrock < Zone 2-0escriptie❑ Series Name Drainage class (BLS) perching 60" BLS 7 BLS = below land surface Calculate Soil Drainage : Wilkes well >3.0 moderate yes Step j Step'2i.1 f x Ksal r�I r0� r0I I--�I n-situ saturated vertical Soll hydraulic cc ductlAt Drainage Drama e y (Ksaq y factor (f) Rateg r in/hr In/tlay percent - in/tlay O.oYF 0 417DMO"$ F 0.04 Zone 2 Month Dmonper PET Soil9 Total Loss Frecip Dralna a inches .....inches inches inches January 31 1.20 1.27 2.47 4.25 February 28 1.63 1.15 2.78 3.94 March 31 2.85 1.27 4.12 5.03 April 30 4.15 1.23 5.38 4.14 May 31 5.12 1.27 6.39 4.45 June 30 5.53 1.23 6.76 4.58 July 31 5.60 1.27 6.87 5.13 August 31 5.14 1.27 6.41 4.43 September 30 3.88 1.23 5.11 4.44 October 31 2.91 1.27 4.18 4.12 November 30 1.75 1.2] 2.98 3.38 December 31 7.14 1.27 2.41 4.10 OEM Totals: 365 40.90 14.98 55.88 51.99 Copied from Influent & Zones Setup Sheet Daily Flow= 6,821 gaefday Zone 2 Ama = 6.53 acres Calculated Maximum Allowable Irrigation Manual Override Maximum Allowable Irrigation Actual Used Maximum Allowable Inng alien Design Irrigation per Month inches inches inches Inches 0.00 -0.03 -0.03 1.19 0.00 0.59 0.59 1.08 0.00 1,33 1.33 1.19 1.24 3.11 3.11 1.15 1.94 3.31 3.31 1.19 2.18 3,32-' 3.32 1.15 1.74 2.66 2.66 1.19 1.98 2.92 ` 2.92 1.19 0.67 1.60 1.60 1.15 0.07 9.t5 1.15 1.19 0.00 0.69 U.69 1.15 0.00 .0.28 -0.28 1.19 �' I 2U.37 III 1 4.U4 Maximum Mon CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max inches Allow. Irrigation. 3.70 Monthly Excess Click the "CALCULATE".. button after making changes. E Irrigation Rate inches Inches inches " FYI -1.22 3.21 .0.03 -6.49 I 3.70 I 0.59 0.14 ) 3.56 ) 1.33 1.96 i 1.61 i 3.11 2.12 i 0.00 I 2.80 2.17 I 0.00 ) 1.15 1.47 F 0.0 i 1.19 1.73 r 0.00 1.19 1.19 0.46 1 0.00 ) 1.15 4.05 f 0.05 1.16 -0.41 r 0,61 0.69 4 -0.28 4.04 thly Storage over Required for: the Irrigation of Zone 2: acres - gallons F 6.53 = 656,831 Lissara DWO Water Balance ReUse Drip.xls Z2 Version 5 December 2004 1 1 1 1 1 t � i i � ► 1 i 1 Soils and Water Balance for Zone 3 Zane 3 Description: Calculate Soil Drainage Step Step2 Ix Ksat 1-situ saturated vertical Drainage Soll hydraulic conductivity factor (f) Dralnaga (Ksat) Ratc inlhr inlday percent in/day U 02 0.53 ,.0.700 0.05 EEdF PET inches January 31 February 28 March 31 P4.1 April 30 May 31 June 30 October 31 November 30 December 31 !•�GlI Z Sol3 Zone3 Soil Total Lass 1PDrainage Inches Inches Inches 1.64 2.84 P4. 1.49 3.11 1.64 4.49 1.58 5.73 1.64 6.76 1.58 7.11 t0 L75%164M271 3.38 1.14 4.1 Soils Series Information for Zone 3 Potential site limitations FWIertable depth risk of Is bedrock<Series Name Drainage class(BLS) perching 60" BLS 7 BLS = below land surface Congaree welhmotl well 2.0->3.0 motlerate no - Click the Copied from Influent 8 Zones Setup Sheet: "CALCULATE' Daily Flow= 16,605 gals/day button after making changes. Zone 3 Area = 11.92 acres - Calculated Mazimum Allowable Irrigation Manual Override Maximum Allowable Irrigation Actual Used maximum Allowable Irrigation Inches inches Inches 0.00 0.33 1 0.33 0.00 0.92 0.92 0.00 1.70 1.70 1.60 3.47 3.47 2.31 3.68 3.68 2.54 3.68 3.68 2.10 3.02 3.02 2.35 3,29 3.29 1.02 1,95 1.95 0.43 1.51 1.51 9.9a 1 4 1.64 0.00 0.08 0.08 Totals: 315 40.90 19.27 60.17 51.99 CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max. Allow. irrigation. -v-- Zone 3 Zone 3 Cummulative Storage Actual Design Irrigation Monthly Required /or Monthly per Month Excess Irrigation Irrigation Rate inches Inches Inches Inches 1.59 1.26 1 3.35 0.33 154 1.93 I 1.83 1 347 1.59 2.09 1 1 0.00 1 3.42 1.54 2.14 1 0.00 1 1.54 1.59 1.43 r 0.00 -1 1.59 1.59 1.70 r U.00 1.59 1.54 0.42 1 0.00 1.64 1.59 -0.08 �� 1.51 FY1 1.54 .0.50 ~5i� 1.04 1.59 _ 18.73 -1.51 a 2.09 _ Y 1 n ffIttllh 0.08 ie.73 Maximum Monthly Storage Required for the Irrigation of Zone 3: inches acres gallons 3.87 over 11.92 0 1,251,489 Lissara DWQ Water Balance ReUse Drip.xls Z3 Version 5 December 2004 Soils and Water Balance for Zone`4 1 Soils series Information for Zone Potential site limitations Water table depth risk of labetlrock < Zone 4 Description: Series Name Drainage class (BLS) perching 60" BLS 7 BLS = below land surface Calculate Soil Drainage Altavista mod well 2.O a.0 moderate no Step 1 Step 2 f x Ksat I -� 3-situ saturated vertical Soil Drainage hydraulic conductivity factor (� Drainage (Ksap Rate Click the Inlhr Inlday percent Inlday Copied from Influent &Zones Setup Sheet "CA"CALCULATE"gM'' 0.53 F 0.05 Daily Flow= 6,309 galsiday button after making 'yMamum PET Sail ral Loss Precum i p ❑ rane9 F- Drainage Incites Inches inches inches .. 31 1.20 1.64 2.84 4.25 28 1.63 1.48 111 3.94 31 2.85 1.fi4 4.49 5.03 30 4.15 7.58 5.73 A.14 31 5.12 7.64 fi.76 4.45 30 5.53 1.58 7.11 4.58 31 S.60 1.64 7.24 5.13 31 5.14 1.64 6.78 4.4J 30 J.58 1.50 5.46 4.44 31 2.91 1.64 M25 4.12 30 1.75 1.58 3.38 1.14 164 4.10 Calculated Allowable Irri alion Manual Overritle MzmDpar Allowable Irrigation _inches inches 0.00 0.00 0.00 1.60 2.31 2.54 2.10 2.35 1.02'yii0_Q_. 0.43 0.00 " 1.04.a31 0.00 'i 11,��+ Zone 4 Area = 4.53 acres Zone 4 Actual Used n Commutative Maximum Allowable Irrigation inches 0.33 0.92 1.70 3.47 3.60 3.60 3.02 3.29 1.95 1.51 1.04 0.08 Totals: 365 40.90 1 19.27 60.17 51.99 II 12.35 24.66 CAUTION: Maximum Allowable Irrigation Used is greater than the Calculated Max. Allow. Irrigation. Design Irrigation Monthly per Month Excess Inches inches. 1.54 1.93 59 2.09 54 2.14 1.59 1.43 1.59 1.70 1.54 0.50 1.59 1.51 18.72 Maximum Monthly Storage I inches 3.86 over Storage Required for Irrigation Inches Zane 4 Actual Monthly Irrigation Rate inches 0.33 0.92 changes. 1.83 I 3.47 FYI I 0.00 I 3.42 i - 0.00 I 1.54 F 1,59 0.00 1.59 0.000 1.54 i0.08 1.51 ~ ose� t.aa 0.08 . 18.72 2eciuired for the Irrigation of Zone 4: acres gallons 0.53 = 475,388 Lissara DWQ Water Balance ReUse Drip.xls Z4 Version 5 December 2004 I 1 I I I I I I I I 1 I I 1 I I 1 I I Zonal 5toraoe Summations nn.IFeT-Tn ealc,Jaln R,n minMUm wee weameram]aeU ranuirea far a mwLnle zenea so]av irriealion R. Zone 1 Zone 2 Zone 3 Zone 4 Zone 5 Zone 6 Zone T Zone 8 Zone 9 Zone 10 TotaIS znn. m[nlPrnn s» IIj �, peaq d. pal. memm B7,e40 cecl Wllkva - -- �J eoneamu Aeavlam IbPal- PrBJmn 1$ Ilv=» I Tv1aI FI0W 01[Pv[va 90.O E1 p ally Flv 1 2 v•» 6p q06 OPJ fi,631 9VJ 16.6 e5 gptl 0,]99 OVJ 0 BPJ vya � B 9W � B evJ B eptl o vptl � � � IbWI• We11eJ AcreaOe=•» JS aclev � 13 eclei � � � �. � � � Tolal Ar-a 5] 9fi CummulaUve Storage Cum mule llvo $l via pv Cum mula4vv slvrape Cum mul]Y vv 6l vrugv u m lal rve Slora m Be Lummulc9ve $lofa b` Cum mule 11 vc Slvra be Cummulallve Slvmpe Lummulali vv Storage Cum m Nallve slvruge Cum m ulavrabe AIvnIM1 Oaye peg mvnlM1 RequlrN RryuimJ Requiretl RcquUeJ Requi red RequimJ Req ul�N Req uilcJ flequlma Req ulreJ LVJ Req-ave 00 0� o� IncRe, aageai o� o� o allva. o� o .� o ao o .Ilnn 0'I 11 sill 9's"la a a a. a a 1. aS,OSB,193 aMdlld 11sMa a e,a a as ab,839,901 III ]n][IZ 1a[ fia �lw as a p.0o 5,608,633 as l SS w♦ 'a l 2 .1ae a m v 3,626,906 Ma 0a a 0B w e a D 00 0 000 a 0 000 06 ro 0 a a aB m 1000 0 J.BJ a olv a oaJ a aac v a49 a a.aaa 0 s.lmefie, 30.0a a pva v 0.00 o O.Oo 0 B.vB a 94o a eoB a a.aa o a4o o o.o0 0 0 onm., m om a[lar o05 ..m 0609 m,e56 0.av a v.]v v.vv v v.av a eov p ad o aas v v.Ba a 73,513 a as Uae a69]a] Ir61 91Ia> D6a 1a)63] 0.55 ]IZBS a.aa 0 a.ea a aDa 0_ O.as a a.ea B a.00 610,103 vur UecenNn 31 9a5383 ida Is, 33111 Za9 675BaB ]EY Nfl]II vav 0 aaa a 0 a 000 000 J I 3,110.473 I Mini um Ra9u mtl SlonpU 19allvnz) -{Y 5,829,991—, Minimum 53oraPe- 5.829.901 gallons divided by 62,840 Opp days - FYl FYI M'n mum Red allied Slolaga Llssala OWO Wide, Rmance ReUse pnp is Zoaal Sums Vmzion 5 peeembcr 2004 m OR om on APPENDIX I CORRESPONDENCE REGARDING USGS STREAMFLOW fm ESTIMATES. FOR PROPOSED DISCHARGE POINT IN THE YADKIN RIVER am no oft ow M p1 No me Wo an no .m MR an on am MR MA aw MW am Summary of USGS-NC Streamflow Data for Requested Discharge Location Average Flow 21440 CFS 7Q10 550 CFS 30Q2 11140 CFS W7Q10 860 CFS 7Q2 990 CFS fm Page 1 of 2 0" John F. Phillips From: "John C Weaver" <jcweaver@usgs.gov> To: <jfphillips@bellsouth.net> Cc: "John C Weaver" <jcweaver@usgs.gov>; "Jeanne C Robbins" <jrobbins@usgs.gov> Sent: Monday, September 24, 2007 3:56 PM Subject: Low -flow estimates for selected Yadkin basin sites John, During the latter part of August, you submitted formal low -flow requests for 3 sites in Yadkin River basin, requesting the full range of flow statistics typically provided in response to formal requests. Due to other items requiring my focus these day -- particularly the drought -- I have been unable to spend time on your requests until this afternoon. The purpose of this email is to provide you with some information that may be helpful to you at this time and to confirm your need for a formal response. The "most recent' low -flow information published for this area is in a statewide report completed in the early 1990's. It is USGS Water -Supply Paper 2403, 'Low -flow characteristics of streams in North Carolina" (Giese and Mason, 1993). An online version of the report is available through http://pubs.er.usgs.gov/usgspubs/wsptwsp2403. The report provides the low -flow characteristics (based on data through 1988) via regional relations and at -site values for sites with drainage basins between 1 and 400 sgmi and not considered or known to be affected by regulation and/or diversions. If you access the report, please note the online report files are provided in the ". DJVU" format and require a particular Lizardtech plug-in, also available through a link.displayed on the page. Or you can click an adjacent s, link that will allow you to view the report as a group of images without the need for a plug-in. A check of the low -flow files here at the USGS North Carolina Water Science Center for each of your sites 0" indicates the following: (1) Your site of interest on South Deep Creek tributary (adjacent to Starmount High School) is identical to a site where low -flow estimates have previously been determined -- South Deep Creek tributary near Wagoner (station ON id 02115541, drainage area 0.53 sgmi). The following estimates were determined in June 1987 based on the flow characteristics at a nearby partial -record site on North Deep Creek near Yadkinville (station id 02115610): ow Average flow = 0.7 cfs (1.03 cfsm) 7Q10 = 0.06 cfs (0.109 cfsm) 30Q2 = 0.2 cfs (0.383 cfsm) winter 7Q10 = 0.15 (0.290 cfsm) 7Q2 = 0.16 cfs (0.293 cfsm) .� (2) Your site of interest on Forbush Creek is almost identical to another site where low -flow estimates have previously been determined -- Forbush Creek above gaging station near Forbush (station id 0211549820, drainage area 21.6 sgmi). The following estimates were determined in January 1990 based on the flow characteristics at a discontinued continuous -record gaging station located 0.6 mile downstream from your point of interest — Forbush Creek near Yadkinville (station id 02115500, period of record in 1940-71): Average flow = 22 cfs (1.03 cfsm) am 7Q10 = 2.1 cfs (0.098 cfsm) 30Q2 = 7.1 cfs (0.330 cfsm) winter 7Q10 = 6.7 (0.307 cfsm) go 7Q2 = 5.6 cfs (0.262 cfsm) 2/18/2008 P" Page 2 of 2 PM Please note the low -flow yields (expressed as flow per sqmi drainage area, or cfsm) at the above two sites are very comparable for each statistic. no (3) For your site of interest on the Yadkin River, the difference in drainage areas between your location and the gaging station at Enon (station id 02115360, drainage area 1,694) is negligible such that flow characteristics at the gage can be considered applicable to your site. Average flow = 2,440 cfs 7Q10 = 550 cfs 30Q2 =1,140 cfs winter 7Q10 = 860 cfs 7Q2 = 990 cfs "" Please note the above statistics are based on the 1965 to 2006 climatic years, which reflects the full period of record at the gaging station and the regulated flow releases from W. Kerr Scott Reservoir near Wilkesboro. no Note: The climatic year is the standard annual period used for low -flow analyses at continuous -record gaging stations. It runs from April 1 through March 31 and is designated by the year in which the period begins. For example, the 2006 climatic year is from April 1, 2006, through March 31, 2007. fm In some of the western basins in North Carolina, the low -flow conditions observed during the 1998-2002 drought have resulted in lower low -flow statistics. No formal statewide investigation has been completed to document the changes in low -flow statistics since the drought. However, where updated analyses have been completed for aw selected stations, the changes in pre- versus post -drought 7Q10 discharges have been on the order of about 10 to 25 percent. For example, the 7Q10 discharge estimated for the Enon gaging station as of 1998 was about 620 cfs. The updated value is about 12 percent lower that the 1998 value. However, with no additional data from the Im discontinued gaging station on Forbush Creek, there no means other than a "guess estimate" to consider what an updated 7Q10 discharge might be at this location. If using this email as a means to provide you with the low -flow estimates is not sufficient -or- if you still want the formal response completed for each site, the let me know. I have been using email as the primary means of providing low -flow information (at no charge) to help facilitate more rapid responses. Again, if you need the formal responses, then I will attempt to complete these by mid- to late October (charge of $150 per site). Thank you for you patience... hope this information is helpful. No Curtis Weaver J. Curtis Weaver, Hydrologist, PE USGS North Carolina Water Science Center 3916 Sunset Ridge Road Raleigh, NC 27607 r„ Telephone: (919) 571-4043 H Fax: (919) 571-4041 E-mail address -- jcweaver@usgs.gov Internet address — http://nc.water.usgs.gov/ no am 2/18/2008 P" DIEHL & PHILLIPS, P.A. CONSULTING ENGINEERS 219 East Chatham Street Cary, North Carolina 27511 �► Telephone (919) 467--9972 — Fax (919) 467-5327 August 23, 2007 Mr. J. Curtis Weaver, Hydrologist U.S. Geological Survey 3916 Sunset Ridge Road Raleigh, NC 27607 ROw e: Request for Stream Flow Data -- Forsyth County Site • Yadkin River am Dear Mr. Weaver: WILLIAM C. DIEHL, P.E. JOHN F. PHILLIPS, P.E. ALAN R. KEniL P.E. The property owner adjacent to a potential treated wastewater discharge point into the Yadkin Ow River is pursuing the required NPDES permit. As a first step in this process, we are requesting USGS provide the following flow statistics for the location marked on the enclosed maps: No 0" im Ow me Average flow 7Q10 minimum flow 30Q2 minimum flow Winter 7Q 10 minimum flow Annual 7Q2 minimum flow The proposed discharge point is located approximately 6,500 feet downstream of the USGS gaging station "02115360 Yadkin River at Enon, NC". This station has a drainage area of 1,694 square miles. The additional drainage area below the station and tributary to the potential discharge point is 5.4 square miles in Forsyth County and 0.26 square miles in Yadkin County. This creates a total drainage area of 1,699 square miles at the potential discharge point, by our measurements. We would appreciate this flow data when you can provide it. Please forward your invoice for your services to Diehl & Phillips, P.A. If you have any questions, please call. Enclosures Cc: Mr. Brant Godfrey Yours Very Truly, Diehl & Phillips, P.A. John F. Phillips, P.E. OR ow am am ow go wa am am on a. OR am MR pq wo APPENDIX J EXECUTED ATTACHMENT A. LOCAL GOVERNMENT FORM, FROM EAA GUIDANCE DOCUMENT Im Im A" Attachment A. Local Government Review Form No General Statute Overview. North Carolina General Statute 143-215.1 (c)(G) allows input from local governments in the issuance of NPDES Permits for non -municipal domestic wastewater treatment facilities. Specifically, the Environmental Management Commission (EMC) may not act on an application for a new non -municipal domestic wastewater discharge facility until it has received a written statement from each city and county government having jurisdiction over any part of the lands on No which the proposed facility and its appurtenances are to be located. The written statement shall document whether the city or county has a zoning or subdivision ordinance in effect and (if such an ordinance is in effect) whether the proposed facility is consistent with the ordinance. The EMC shall not approve a permit application for any facility which a city or county has determined to be inconsistent with zoning or subdivision ordinances unless the approval of such application is determined to am have statewide significance and is in the best interest of the State. Instructions to the A1Hlicanr. Prior to submitting an application for a NPDES Permit for a proposed facility, the applicant shall request that both the nearby city and county government complete this form. The applicant must: ■ Submit a copy of the permit application (with a written request for this foam to be completed) to the clerk of the city and the county by certified mail, return receipt requested. ■ If either (or both) local governments) fail(s) to mail the completed foan, as evidenced by the postmark on the certified �+ mail card(s), within 15 days after receiving and signing for the certified mail, the applicant may submit the application to the NPDES Unit ■ As evidence to the Commission that the local government(s) famed to respond within 15 days, the applicant shall submit a copy of the certified mail card along with a notarized letter stating that the local governments) failed to respond within the 15-day period. Instructions to the Local Government: The nearby city and/or county government which may have or has jurisdiction over am any part of the land on which the proposed facility or its appurtenances are to be located is required to complete and return this form to the applicant within 15 days of receipt The form must be signed and notarized. OR Name of local government: Forsythtv (City/County) ow Does the city/county have jurisdiction over any part of the land on which the proposed facility and its appurtenances are to be located? Yes [JJ No [ ] If no, please sign this form, have it notarized, and return it to the applicant: Does the city/county have in effect a zoning or subdivision ordinance? Yes LA No [ ) If there is a zoning or subdivision ordinance in effect, is the plan for the proposed facility consistent with the ordinance? Yes [� No [ ) Date 2 . D % Signaftm 72 � Mwngec/County Manager) State of 14& r-44, CaxD1 i Ma.. , County of Fd rs Li .a On this g day of Fe6ru� I ,fig ,personally appeared before me, the said name LAA 1ey Wa;Rs i :S—r. to me known and known to me to be the person described in and who executed the foregoing document and he (or she) acknowledged that he (or she) executed the same and being duly sworn by me, made oath that the statements in the foregoing document are true. My Commission expires."C�%er 02.4, OU09 .(Signature of Notary Pub.'�K' am Notary Nblic (Official Seal) 0BOU Ls�. ma ACWWMCWKWI ��nPi c corn OF FORSM =3 an EAA Guidance Document Version: June 23, 2005 BOARD OF COMMISSIONERS OwGLORIAD. WHISENHUNT, Chair DEBRA CONRAD, Vice Chair BEAUFORT 0. BAILEY .TED KAPLAN RICHARD V. LINVILLE WALTER MARSHALL BILL WHITEHEART of 4 FORSYTH COUNTY, NORTH CAROLINA February 8, 2008 Mr. John F. Phillips, P.E. Diehl & Phillips, P.A. 219 East Chatham Street r Cary, NC 27511 M Dear Mr. Phillips: J. DUDLEY WATTS, JR. County Manager A. EDWARD JONES Deputy County Manager DAMON SANDERS-PRATT Assistant County Manager JANE F. COLE Clerk to the Board/ Assistant to the Manager Enclosed herewith please find the signed document you had requested in your r correspondence to me dated January 28, 2008. If I can be of further assistance, please feel free to contact me. r Sincerely, r _ Jane F. Cole, CMC Clerk to the Board of Conunissioners .. JFC/kh r r r Enclosure Forsyth County Government Center • 201 N. Chestnut Street • Winston-Salem, North Carolina 27101-4120 Telephone (336) 703-2020 • FAX (336) 727-8446 P" pa ow am mm PM pm no ow APPENDIX K SENSITIVITY ANALYSIS TO EXAMINE THE EFFECT OF on VARIOUS INTEREST RATES ON THE RELATIVE RANKING OF THE ALTERNATIVES Im ow mm fm I, fm o. Im OR OR go EZI Oa Ow 00 fm am Ow M MM No no IM Sensitivity Analysis As presented in the tables on the following two pages, Alternative No. 7, the treatment plant with a discharge to the Yadkin River has a substantially lower Present Worth than any of the other Alternatives. At 7.00% interest rate, the PW of Alternative No. 7 is $8,038,626. The next closest alternative, No. 4, has a PW of $12,840,603, a difference of over $4.8 million dollars. The second table in this Appendix presents a relative ranking of the Alternatives for each interest rate, to further demonstrate that the only cost effective alternative is Alternative No. 7, which proposes to discharge treated wastewater into the Yadkin River. Appendix K Page 1 Sensitivity Analysis at 4%, 7%, and 1O% Interest Rates Present Worth Present Worth Present Alt. Description 4% Interest 7% Interest Worth 10% Number rate rate Interest rate 1 Connection to Publicly Owned Treatment Works N/A N/A N/A 2 Connection to Privately Owned Treatment Plant N/A N/A N/A 3 Individual Sub -surface Systems $14,330,558 $13,103,534 $12,053,821 Wastewater Collection System and Wastewater 4 Treatment Plant, with Disposal through Conventional $12,743,779 $14,095,607 $9,923,174 Nitrification Lines Wastewater Collection System and Wastewater 5 Treatment Plant, with Disposal through Drip Irrigation $14,294,741 $12,840,603 $11,7301120 Lines (Surface Applied) Wastewater Collection System and Wastewater 6 Treatment Plant, with Disposal through Spray $14,903,589 $13,305,554 $12,060,304 Irrigation System Wastewater Collection System & Wastewater 7 Treatment Plant, with Disposal through Surface $9,155,454 $8,038,626 $7,240,872 Discharge to Yadkin River Wastewater Collection System and Wastewater 8 Treatment Plant, With Re -Use Quality Effluent Disposal $13,924,696 $12,483,793 $11,413,573 Through Drip Irrigation Lines (Surface Applied) Appendix K Page 2 Relative Rankine of Alternatives at 4%, 7%, and 10% Interest Rates Present Worth Present Worth Present Alt. Description 4% Interest 7% Interest Worth 10% Number rate rate Interest rate 1 Connection to Publicly Owned Treatment Works N/A N/A N/A 2 Connection to Privately Owned Treatment Plant N/A N/A N/A 3 Individual Sub -surface Systems 1.565 1.630 1.665 Wastewater Collection System and Wastewater 4 Treatment Plant, with Disposal through Conventional 1.392 1.753 1.370 Nitrification Lines Wastewater Collection System and Wastewater 5 Treatment Plant, with Disposal through Drip Irrigation 1.561 1.597 1.62 Lines (Surface Applied) Wastewater Collection System and Wastewater 6 Treatment Plant, with Disposal through Spray 1.628 1.655 1.666 Irrigation System Wastewater Collection System & Wastewater 7 Treatment Plant, with Disposal through Surface 1.000 1.000 1.000 Discharge to Yadkin River Wastewater Collection System and Wastewater 8 Treatment Plant, With Re -Use Quality Effluent Disposal 1.521 1.553 1.576 Through Drip Irrigation Lines (Surface Applied) Appendix K Page 3