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Home My WebLink AboutCraig Pre Feasibility Assessment for Integration of Wood Fired Heating Systems Final Report Craig Tribal Association Bld Final Report 7-24-2012-BIO Pre-Feasibility Assessment for Integration of Wood-Fired Heating Systems Final Report July 24, 2012 Craig Tribal Association Building Craig, Alaska Presented by CTA Architects Engineers Nick Salmon & Nathan Ratz Lars Construction Management Services Rex Goolsby For Craig Tribal Association In partnership with Fairbanks Economic Development Corporation Alaska Wood Energy Development Task Group Funded by Alaska Energy Authority and U.S. Forest Service 306 W. Railroad, Suite 104 Missoula, MT 59802 406.728.9522 www.ctagroup.com CTA Project: FEDC_KETCHCRAIG_CTA Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers i July 24, 2012 TABLE OF CONTENTS 1.0 Executive Summary ................................................................................................... 1 2.0 Introduction ............................................................................................................... 2 3.0 Existing Building Systems.......................................................................................... 2 4.0 Energy Use ............................................................................................................... 2 5.0 Biomass Boiler Size ................................................................................................... 2 6.0 Wood Fuel Use .......................................................................................................... 3 7.0 Boiler Plant Location and Site Access ....................................................................... 4 8.0 Integration with Existing Heating Systems ................................................................. 4 9.0 Air Quality Permits ..................................................................................................... 5 10.0 Wood Heating Options .............................................................................................. 5 11.0 Estimated Costs ........................................................................................................ 5 12.0 Economic Analysis Assumptions ............................................................................... 5 13.0 Results of Evaluation ................................................................................................. 6 14.0 Project Funding ......................................................................................................... 6 15.0 Summary ................................................................................................................... 7 16.0 Recommended Action ............................................................................................... 7 Appendixes Appendix A: Preliminary Estimates of Probable Cost .................................................. 1 page Appendix B: Cash Flow Analysis ............................................................................... 2 pages Appendix C: Site Plan ................................................................................................. 1 page Appendix D: Air Quality Report ............................................................................... 11 pages Appendix E: Wood Fired Heating Technologies ........................................................ 3 pages Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 1 of 7 July 24, 2012 1.0 Executive Summary The following assessment was commissioned to determine the preliminary technical and economic feasibility of integrating a wood fired heating system in the Craig Tribal Association Building, in Craig, Alaska. The following tables summarize the current fuel use and the potential wood fuel use: Table 1.1 - Annual Fuel Use Summary Fuel Avg. Use Current Annual Facility Name Type (Gallons) Cost/Gal Cost CTA Building Fuel Oil 9,000 $4.20 $37,800 Table 1.2 - Annual Wood Fuel Use Summary Fuel Cord Wood Oil Wood Pellets (Gallons) (Cords) (Tons) CTA Building 9,000 78.7 71.7 Note: Wood fuel use assumes offsetting 85% of the current energy use. Based on the estimated volume of wood and the estimated biomass boiler size, a pellet option and cord wood option will be evaluated. Chipped/ground fuel boilers were not considered because the potential fuel cost savings would not pay for the high capital cost of these system types. The options reviewed were: Wood Pellet Boiler Options: B.1: A freestanding boiler building with adjacent free standing pellet silo. Cord Wood Boiler Option: C.1: A free standing building with interior cordwood fuel storage. Table 1.3 - Economic Evaluation Summary CTA Building Biomass Heating System Year 1 NPV NPV 20 Yr 30 Yr Project Operating 30 yr 20 yr B/C B/C ACF ACF YR Cost Savings at 3% at 3% Ratio Ratio YR 20 YR 30 ACF=PC B.1 $650,000 $2,955 $461,328 $220,813 0.34 0.71 $327,074 $845,182 28 C.1 $225,000 $6,859 $599,067 $307,452 1.37 2.66 $448,460 $1,075,793 14 A cord wood boiler serving the Craig Tribal Association appears to be a good candidate for a wood heating system. With the current economic assumptions and the reported fuel use, the 20 year B/C ratio is 1.37. The annual fuel oil amount used in the analysis is 9,000 gallons. If this usage dropped to 8,000 gallons, then the 20 year B/C ratio would be 1.14 and the project remains viable. Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 2 of 7 July 24, 2012 2.0 Introduction The following assessment was commissioned to determine the preliminary technical and economic feasibility of integrating a wood fired heating system in the Craig Tribal Association Building, in Craig, Alaska. 3.0 Existing Building Systems The Craig Tribal Association Building is a two-story metal building constructed in 2000. The facility is approximately 16,000 square feet and is heated by an 810,000 Btu/hr output hot water boiler. Domestic hot water is provided by a 120 gallon indirect water heater using the boiler water as a heating source. The existing boiler is original to the building and is in good condition. The heating system infrastructure is original to the building an in good condition. The Craig Tribal Association Building is across the street from the Craig Middle School served by the biomass district heating system which also heats the elementary school and the city pool building. Facilities Dropped from Feasibility Study No facilities were dropped from the feasibility study. Facilities Added to Feasibility Study No facilities were added to the feasibility study. 4.0 Energy Use Fuel oil bills for the facilities were provided. The following table summarizes the data: Table 4.1 - Annual Fuel Use Summary Fuel Avg. Use Current Annual Facility Name Type (Gallons) Cost/Gal Cost CTA Building Fuel Oil 9,000 $4.20 $37,800 Electrical energy consumption will increase with the installation of the wood fired boiler system because of the power needed for the biomass boiler components such as augers, conveyors, draft fans, etc. and the additional pumps needed to integrate into the existing heating systems. The cash flow analysis accounts for the additional electrical energy consumption and reduces the annual savings accordingly. 5.0 Biomass Boiler Size The following table summarized the connected load of fuel fired boilers and domestic water heaters: Table 5.1 - Connected Boiler Load Summary Likely Peak System Output Load Peak MBH Factor MBH CTA Building Boiler Fuel Oil 810 1.00 810 Total Of All Buildings 810 810 Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 3 of 7 July 24, 2012 Typically a wood heating system is sized to meet approximately 85% of the typical annual heating energy use of the building. The existing heating boilers and furnaces would be used for the other 15% of the time during peak heating conditions, during times when the biomass boiler is down for servicing, and during swing months when only a few hours of heating each day are required. Recent energy models have found that a boiler sized at 50% to 60% of the building peak load will typically accommodate 85% of the boiler run hours. Several projects are under consideration in Craig, therefore the boiler size will vary with each option as noted below. Table 5.2 - Proposed Biomass Boiler Size Likely Biomass System Biomass Boiler Peak Boiler Size MBH Factor MBH CTA Building 810 0.6 486 6.0 Wood Fuel Use The types of wood fuel available in the area include cord wood and wood pellets. The estimated amount of wood fuel needed of each wood fuel type for each building was calculated and is listed below: Table 6.1 - Annual Wood Fuel Use Summary Fuel Cord Wood Oil Wood Pellets (Gallons) (Cords) (Tons) CTA Building 9,000 78.7 71.7 Note: Wood fuel use assumes offsetting 85% of the current energy use. The amount of wood fuel shown in the table is for offsetting 85% of the total fuel oil use. The moisture content of the wood fuels and the overall wood burning system efficiencies were accounted for in these calculations. The existing fuel oil boilers were assumed to be 80% efficient. Cord wood was assumed to be 20% moisture content (MC) with a system efficiency of 65%. Wood pellets were assumed to be 7% MC with a system efficiency of 70%. Based on the potential wood fuel use, a cord wood system and a pellet system are the most viable. The fuel use is too low to generate enough savings to make a chipped/ground fuel option viable. There are sawmills and active logging operations in the region. Tongass Forest Enterprises has stared up a pellet plant in Ketchikan and is providing pellets to Sealaska. Pellets are also available from plants in British Columbia, Washington, and Oregon. There appears to be a sufficient available supply to service the boiler plant. Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 4 of 7 July 24, 2012 The unit fuel costs for fuel oil and the different fuel types were calculated and equalized to dollars per million Btu ($/MMBtu) to allow for direct comparison. The Delivered $/MMBtu is the cost of the fuel based on what is actually delivered to the heating system, which includes all the inefficiencies of the different systems. The Gross $/MMBtu is the cost of the fuel based on raw fuel, or the higher heating value and does not account for any system inefficiencies. The following table summarizes the equalized fuel costs at different fuel unit costs: Table 6.2 - Unit Fuel Costs Equalized to $/MMBtu Net Gross System System Delivered Gross Fuel Type Units Btu/unit Efficiency Btu/unit $/unit $/MMBtu $/MMBtu Fuel Oil gal 134500 0.8 107600 $4.00 $37.17 $29.74 $4.50 $41.82 $33.46 $5.00 $46.47 $37.17 Cord Wood cords 16173800 0.65 10512970 $150.00 $14.27 $9.27 $200.00 $19.02 $12.37 $250.00 $23.78 $15.46 Pellets tons 16400000 0.7 11480000 $200.00 $17.42 $12.20 $250.00 $21.78 $15.24 $300.00 $26.13 $18.29 7.0 Boiler Plant Location and Site Access The boiler room is not large enough to accommodate a new wood fired boiler so a new stand-alone plant would be required. The best location for a plant would be just west of the building. Any type of biomass boiler plant will require access by delivery vehicles. For cord wood systems this would likely be pick up trucks and trucks with trailers. For pellet systems, this would likely be 40 foot long vans or some similar type of trailer. Access to the plant would be from the north side of the property. Pick up trucks with small trailers can access the boiler plant from the north side easily. It is possible for large tractor trailers to access the plant from the north side, but it will be difficult. 8.0 Integration with Existing Heating System Integration of a wood fired boiler system would be relatively straight forward in the building. The field visit confirmed the location of the boiler room in order to identify an approximate point of connection from a biomass boiler to the existing building. Piping from the biomass boiler plant would be run below ground with pre-insulated pipe and extended to the face of the building, and extended up the exterior surface in order to penetrate exterior wall into the boiler room. Once the hot water supply and return piping enters the existing boiler room it would be connected to existing supply and return pipes in appropriate locations in order to utilize existing pumping systems within each building. Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 5 of 7 July 24, 2012 Across the street to the south, the Craig Middle School, Elementary School, and the City Pool are currently served by a district heating system heated by a wood chip boiler plant. The plant is located across the parking lot from the pool building, and piping runs from the plant to the elementary school and then to the two middle school boiler rooms. When the highway that separates the CTA building from the school was re-paved recently, a large sleeve was installed under the highway to allow for the possibility of installing piping under the highway and connecting the CTA building to this existing district heating system. There are two main reasons why it would not be viable to try and connect to the school’s district system: (1) The cost would be significant. The Craig Tribal Association recently paved their parking lot, and a large trench would need to be installed from the highway, through the parking lot to the building. In addition, trenching would have to be done across the middle school parking lot as well. The costs of trenching, installing heating piping, and repairing these parking lots would far exceed any potential savings of this building. (2) The middle school is the end of the piping run for the district system. That system was not designed to be extended, so the pipe sizes are too small, and there is not enough available flow to properly service the CTA building. 9.0 Air Quality Permits Resource System Group has done a preliminary review of potential air quality issues in the area. Southeast Alaska is has meteorological conditions that can create thermal inversions, which are unfavorable for the dispersion of emissions. The proposed boiler size at this location is small enough, that the boiler is not likely to require any State or Federal permits. See the air quality memo in Appendix D. 10.0 Wood Heating Options The technologies available to produce heating energy from wood based biomass are varied in their approach, but largely can be separated into three types of heating plants: cord wood, wood pellet and wood chip/ground wood fueled. See Appendix E for these summaries. Based on the estimated volume of wood and the estimated biomass boiler size, a pellet option and cord wood option will be evaluated. Chipped/ground fuel boilers were not considered because the potential fuel cost savings would not pay for the high capital cost of these system types. The options reviewed were: Wood Pellet Boiler Options: B.1: A freestanding boiler building with adjacent free standing pellet silo. Cord Wood Boiler Option: C.1: A free standing building with interior cordwood fuel storage. 11.0 Estimated Costs The total project costs are at a preliminary design level and are based on RS Means and recent biomass project bid data. The estimates are shown in the appendix. These costs are conservative and if a deeper level feasibility analysis is undertaken and/or further design occurs, the costs may be able to be reduced. 12.0 Economic Analysis Assumptions The cash flow analysis assumes fuel oil at $4.30/gal, electricity at $0.27/kwh, wood pellets delivered at $300/ton, and cord wood fuel delivered at $200/cord. The fuel oil, electricity, Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 6 of 7 July 24, 2012 and cord wood costs are based on the costs reported by the facility. Pellet costs were obtained from Tongass Forest Enterprises. It is assumed that the wood boiler would supplant 85% of the estimated heating use, and the existing heating systems would heat the remaining 15%. Each option assumes the total project can be funded with grants and non obligated capital money. The following inflation rates were used: O&M - 2%, Fossil Fuel – 5%, Wood Fuel – 3%, Discount Rate for NPV calculation – 3%. The fossil fuel inflation rate is basedon the DOE EIA website. DOE is projecting a slight plateau with a long term inflation of approximately 5%. As a point of comparison, oil prices have increased at an annual rate of over 8% since 2001. The analysis also accounts for additional electrical energy required for the wood fired boiler system as well as the system pumps to distribute heating hot water to the buildings. Wood fired boiler systems also will require more maintenance, and these additional maintenance costs are also factored into the analysis. 13.0 Results of Evaluation The following table summarizes the economic evaluation for each option: Table 13.1 - Economic Evaluation Summary CTA Building Biomass Heating System Year 1 NPV NPV 20 Yr 30 Yr Project Operating 30 yr 20 yr B/C B/C ACF ACF YR Cost Savings at 3% at 3% Ratio Ratio YR 20 YR 30 ACF=PC B.1 $650,000 $2,955 $461,328 $220,813 0.34 0.71 $327,074 $845,182 28 C.1 $225,000 $6,859 $599,067 $307,452 1.37 2.66 $448,460 $1,075,793 14 The benefit to cost ratio (B/C) takes the net present value (NPV) of the net energy savings and divides it by the construction cost of the project. A B/C ratio greater than or equal to 1.0 indicates an economically advantageous project. Accumulated cash flow (ACF) is another evaluation measure that is calculated in this report and is similar to simple payback with the exception that accumulated cash flow takes the cost of financing and fuel escalation into account. For many building owners, having the accumulated cash flow equal the project cost within 15 years is considered necessary for implementation. If the accumulated cash flow equals project cost in 20 years or more, that indicates a challenged project. Positive accumulated cash flow should also be considered an avoided cost as opposed to a pure savings. 14.0 Project Funding The Craig Tribal Association may pursue a biomass project grant from the Alaska Energy Authority. The Craig Tribal Association could also enter into a performance contract for the project. Companies such as Siemens, McKinstry, Johnson Controls and Chevron have expressed an interest in participating in funding projects of all sizes throughout Alaska. This allows the facility owner to pay for the project entirely from the guaranteed energy savings, and to minimize the project funds required to initiate the project. The scope of the project may be Pre-Feasibility Assessment for Craig Tribal Association Integration of Wood-Fired Heating Systems Craig, Alaska CTA Architects Engineers Page 7 of 7 July 24, 2012 expanded to include additional energy conservation measures such as roof and wall insulation and upgrading mechanical systems. 15.0 Summary A cord wood boiler serving the Craig Tribal Association appears to be a good candidate for a wood heating system. With the current economic assumptions and the reported fuel use, the 20 year B/C ratio is 1.37. The annual fuel oil amount used in the analysis is 9,000 gallons. If this usage dropped to 8,000 gallons, then the 20 year B/C ratio would be 1.14 and the project remains viable. 16.0 Recommended Action Most grant programs will likely require a full feasibility assessment. A full assessment would provide more detail on the air quality issues, wood fuel resources, and a schematic design of the boiler systems and system integration to obtain more accurate costs APPENDIX A Preliminary Estimates of Probable Cost Preliminary Estimates of Probable Cost Biomass Heating Options Criag Tribal Association, Craig, AK Option B.1 Pellet Boiler Biomass Boiler Building:$90,000 Wood Heating, Wood Handling System, & Pellet Silo: $110,000 Stack/Air Pollution Control Device:$50,000 Mechanical/Electrical within Boiler Building: $75,000 Underground Piping $2,700 CTA Integration $50,000 Subtotal:$377,700 30% Remote Factor $113,310 Subtotal:$491,010 Design Fees, Building Permit, Miscellaneous Expenses 15%: $73,652 Subtotal:$564,662 15% Contingency:$84,699 Total Project Costs 649,361$ Option C.1 Cord Wood Boiler Biomass Boiler Building Including Wood Storage Area: $55,000 Wood Boiler System:$32,000 Stack:$4,400 Mechanical/Electrical within Boiler Building: $20,200 Underground Piping $10,000 CTA Integration $9,500 Subtotal:$131,100 30% Remote Factor $39,330 Subtotal:$170,430 Design Fees, Building Permit, Miscellaneous Expenses 15%: $25,565 Subtotal:$195,995 15% Contingency:$29,399 Total Project Costs 225,394$ APPENDIX B Cash Flow Analysis Craig Tribal AssociationOption B.1Craig, AlaskaWood Pellet Boiler Date: July 24, 2012 Analyst: CTA Architects Engineers - Nick Salmon & Nathan Ratz EXISTING CONDITIONSCTA BuildingTotalExisting Fuel Type:Fuel Oil Fuel Oil Fuel Oil Fuel OilFuel Units:gal gal gal galCurrent Fuel Unit Cost:$4.30 $4.30 $4.30 $4.30 Estimated Average Annual Fuel Usage:9,0009,000Annual Heating Costs:$38,700 $0 $0 $0 $38,700ENERGY CONVERSION (to 1,000,000 Btu; or 1 dkt)Fuel Heating Value (Btu/unit of fuel):138500 138500 138500 138500Current Annual Fuel Volume (Btu):1,246,500,000 0 0 0Assumed efficiency of existing heating system (%):80% 80% 80% 80% Net Annual Energy Produced (Btu):997,200,000 0 0 0 997,200,000WOOD FUEL COSTWood Pellets$/ton: $300.00Assumed efficiency of wood heating system (%): 70% PROJECTED WOOD FUEL USAGEEstimated Btu content of wood fuel (Btu/lb) - Assumed 7% MC 8200 Tons of wood fuel to supplant net equivalent of 100% annual heating load.87Tons of wood fuel to supplant net equivalent of 85% annual heating load.7425 ton chip van loads to supplant net equivalent of 85% annual heating load.3 Project Capital Cost-$650,000 Project Financing InformationPercent Financed0.0%Est. Pwr Use 17000 kWh Type Hr/Wk Wk/Yr Total Hr Wage/Hr TotalAmount Financed$0 Elec Rate $0.270 /kWh Biomass System 2.0 40 80 $20.00 $1,600Amount of Grants$650,000 Other 0.0 40 0 $20.00 $01st 2 Year Learning 2.0 40 80 $20.00 $1,600Interest Rate5.00%Term10Annual Finance Cost (years)$0 220.0 years Net Benefit B/C Ratio$461,328 -$188,672 0.71$220,813 -$429,1870.34Year Accumulated Cash Flow > 0#N/AYear Accumulated Cash Flow > Project Capital Cost28Inflation FactorsO&M Inflation Rate2.0%Fossil Fuel Inflation Rate5.0%Wood Fuel Inflation Rate3.0%Electricity Inflation Rate3.0%Discount Rate for Net Present Value Calculation 3.0%Year Year Year Year Year Year Year Year Year Year Year Year Year Year Year Year Year YearCash flow Descriptions Unit Costs HeatingSource ProportionAnnual Heating Source VolumesHeating Units 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 20 25 30Existing Heating System Operating CostsDisplaced heating costs $4.30 9000 gal $38,700 $40,635 $42,667 $44,800 $47,040 $49,392 $51,862 $54,455 $57,178 $60,036 $63,038 $66,190 $69,500 $72,975 $76,623 $97,793 $124,811 $159,294Displaced heating costs $4.300 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Displaced heating costs $4.300 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Displaced heating costs $4.300 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Biomass System Operating CostsWood Fuel ($/ton, delivered to boiler site)$300.00 85% 74 tons $22,150 $22,815 $23,499 $24,204 $24,930$25,678 $26,449 $27,242 $28,059 $28,901 $29,768 $30,661 $31,581 $32,529 $33,504 $38,841 $45,027 $52,199Small load existing fuel$4.30 15% 1350 gal $5,805 $6,095 $6,400 $6,720 $7,056 $7,409$7,779 $8,168 $8,577 $9,005 $9,456 $9,929 $10,425 $10,946 $11,494 $14,669 $18,722 $23,894Small load existing fuel$4.30 15% 0 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Small load existing fuel$4.30 15% 0 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Small load existing fuel$4.30 15% 0 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Additional Operation and Maintenance Costs$1,600 $1,632 $1,665 $1,698 $1,732 $1,767 $1,802 $1,838 $1,875 $1,912 $1,950 $1,989 $2,029 $2,070 $2,111 $2,331 $2,573$2,841Additional Operation and Maintenance Costs First 2 years$1,600 $1,632Additional Electrical Cost $0.270$4,590 $4,728 $4,870 $5,016 $5,166 $5,321 $5,481 $5,645 $5,814 $5,989 $6,169 $6,354 $6,544 $6,741 $6,943 $8,049 $9,331$10,817Annual Operating Cost Savings$2,955$3,733$6,233$7,162$8,156$9,217$10,351$11,561$12,852$14,229$15,695$17,257$18,920$20,690$22,572$33,904$49,159$69,544Financed Project Costs - Principal and Interest0000000000 Displaced System Replacement Costs (year one only)0Net Annual Cash Flow2,955 3,733 6,233 7,162 8,156 9,217 10,351 11,561 12,852 14,229 15,695 17,257 18,920 20,690 22,572 33,904 49,159 69,544Accumulated Cash Flow2,955 6,688 12,921 20,083 28,239 37,456 47,808 59,369 72,221 86,450 102,145 119,403 138,323 159,012 181,584 327,074 540,569 845,182Additional Power UseAdditional MaintenanceSimple Payback: Total Project Cost/Year One Operating Cost Savings:Net Present Value (30 year analysis):Net Present Value (20 year analysis): Craig Tribal AssociationOption C.1Craig, AlaskaCord Wood Boiler Date: July 24, 2012 Analyst: CTA Architects Engineers - Nick Salmon & Nathan Ratz EXISTING CONDITIONSCTA BuildingTotalExisting Fuel Type:Fuel Oil Fuel Oil Fuel Oil Fuel OilFuel Units:gal gal gal galCurrent Fuel Unit Cost:$4.30 $4.30 $4.30 $4.30 Estimated Average Annual Fuel Usage:9,0009,000Annual Heating Costs:$38,700 $0 $0 $0 $38,700ENERGY CONVERSION (to 1,000,000 Btu; or 1 dkt)Fuel Heating Value (Btu/unit of fuel):138500 138500 138500 138500Current Annual Fuel Volume (Btu):1,246,500,000 0 0 0Assumed efficiency of existing heating system (%):80% 80% 80% 80% Net Annual Energy Produced (Btu):997,200,000 0 0 0 997,200,000WOOD FUEL COSTCord Wood$/cord: $200.00Assumed efficiency of wood heating system (%): 65% PROJECTED WOOD FUEL USAGEEstimated Btu content of wood fuel (Btu/cord) - Assumed 20% MC, 6,700 Btu/lb x 28.4 lb/cf x 85 cf16,173,800 Cords of wood fuel to supplant net equivalent of 100% annual heating load.95Cords of wood fuel to supplant net equivalent of 85% annual heating load.8125 ton chip van loads to supplant net equivalent of 85% annual heating load.N/A Project Capital Cost-$225,000 Project Financing InformationPercent Financed0.0%Est. Pwr Use 1150 kWh Type Hr/Wk Wk/Yr Total Hr Wage/Hr TotalAmount Financed$0 Elec Rate $0.270 /kWh Biomass System 10.0 40 400 $20.00 $8,000Amount of Grants$225,000 Other 0.0 40 0 $20.00 $01st 2 Year Learning 2.0 40 80 $20.00 $1,600Interest Rate5.00%Term10Annual Finance Cost (years)$0 32.8 years Net Benefit B/C Ratio$599,067 $374,067 2.66$307,452 $82,4521.37Year Accumulated Cash Flow > 0#N/AYear Accumulated Cash Flow > Project Capital Cost14Inflation FactorsO&M Inflation Rate2.0%Fossil Fuel Inflation Rate5.0%Wood Fuel Inflation Rate3.0%Electricity Inflation Rate3.0%Discount Rate for Net Present Value Calculation 3.0%Year Year Year Year Year Year Year Year Year Year Year Year Year Year Year Year Year YearCash flow Descriptions Unit Costs HeatingSource ProportionAnnual Heating Source VolumesHeating Units 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 20 25 30Existing Heating System Operating CostsDisplaced heating costs $4.30 9000 gal $38,700 $40,635 $42,667 $44,800 $47,040 $49,392 $51,862 $54,455 $57,178 $60,036 $63,038 $66,190 $69,500 $72,975 $76,623 $97,793 $124,811 $159,294Displaced heating costs $4.300 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Displaced heating costs $4.300 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Displaced heating costs $4.300 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Biomass System Operating CostsWood Fuel ($/ton, delivered to boiler site)$200.00 85% 81 cords $16,125 $16,609 $17,107 $17,620 $18,149 $18,694 $19,254 $19,832 $20,427 $21,040 $21,671 $22,321 $22,991 $23,680 $24,391 $28,276 $32,779 $38,000Small load existing fuel$4.30 15% 1350 gal $5,805 $6,095 $6,400 $6,720 $7,056 $7,409$7,779 $8,168 $8,577 $9,005 $9,456 $9,929 $10,425 $10,946 $11,494 $14,669 $18,722 $23,894Small load existing fuel$4.30 15% 0 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Small load existing fuel$4.30 15% 0 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Small load existing fuel$4.30 15% 0 gal $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0 $0Additional Operation and Maintenance Costs$8,000 $8,160 $8,323 $8,490 $8,659 $8,833 $9,009 $9,189 $9,373 $9,561 $9,752 $9,947 $10,146 $10,349 $10,556 $11,654 $12,867 $14,207Additional Operation and Maintenance Costs First 2 years$1,600 $1,632Additional Electrical Cost $0.270$311 $320 $329 $339 $349 $360 $371 $382 $393 $405 $417 $430 $443 $456 $470 $544 $631 $732Annual Operating Cost Savings$6,859$7,819$10,507$11,631$12,826$14,097$15,448$16,883$18,407$20,025$21,742$23,564$25,495$27,543$29,714$42,649$59,812$82,462Financed Project Costs - Principal and Interest0000000000 Displaced System Replacement Costs (year one only)0Net Annual Cash Flow6,859 7,819 10,507 11,631 12,826 14,097 15,448 16,883 18,407 20,025 21,742 23,564 25,495 27,543 29,714 42,649 59,812 82,462Accumulated Cash Flow6,859 14,678 25,185 36,816 49,642 63,739 79,187 96,070 114,478 134,503 156,245 179,809 205,304 232,847 262,561 448,460 711,274 1,075,793Additional Power UseAdditional MaintenanceSimple Payback: Total Project Cost/Year One Operating Cost Savings:Net Present Value (30 year analysis):Net Present Value (20 year analysis): APPENDIX C Site Plan BOILERPLANTSTACKTRIBAL ASSOC.BUILDING105'-0"MISSOULA, MT(406)728-9522Fax (406)728-8287Date®BIOMASS PRE-FEASIBILITY ASSESSMENTCRAIG, ALASKACRAIG TRIBAL ASSOCIATION BUILDINGSSFNHR07/24/2012FEDCJ:Tribal AssocSITE PLANNORTHREF.LEGENDPIPE ROUTINGBOILER ROOM100'50'25'0SCALE: 1:50 APPENDIX D Air Quality Report 55 Railroad Row  White River Junction, Vermont 05001 TEL 802.295.4999  FAX 802.295.1006  www.rsginc.com INTRODUCTION At your request, RSG has conducted an air quality feasibility study for seven biomass energy installations in Ketchikan and Craig, Alaska. These sites are located in the panhandle of Alaska. The following equipment is proposed:  Ketchikan o One 4,700,000 Btu/hr (heat output) pellet boiler at the Ketchikan High School. o One 800,000 Btu/hr (heat output) pellet boiler at the Ketchikan Indian Council Medical Facility. o One 150,000 Btu/hr (heat output) pellet boiler at the Ketchikan Indian Council Votec School. o One 200,000 Btu/hr (heat output) pellet boiler at the old Ketchikan Indian Council Administration Building.  Craig o One 450,000 Btu/hr (heat output) cord wood boiler at the Craig Tribal Association Building. o One 450,000 Btu/hr (heat output) cord wood boiler near the Fire Hall. o One 250,000 Btu/hr (heat output) cord wood boiler at the Shaan‐Seet Office. To: Nick Salmon From: John Hinckley Subject: Ketchikan‐Craig Cluster Feasibility Study Date: 24 July 2012 Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 2 A USGS map of the Ketchikan study area is provided in Figure 1 below. As shown, the area is mountainous, with Ketchikan located on the southwest side of a mountain range. Ketchikan has a population of 14,070. The area is relatively fairly well populated and developed relative to other areas in Alaska. The area is also a port for cruise ships, which are significant sources of air pollution. The topography, population, level of development, and existing emission sources has the potential to create localized, temporary problematic air quality. Figure 1: USGS Map Illustrating the Ketchikan Study Area Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 3 Figure 2 shows CTA Architects’ plan of the location of the proposed biomass facility at the Ketchikan High School. The site slopes moderately to steeply downward in the southeasterly direction with the grade becoming very steep to the northeast of the High School building. The school building is between two to three stories high. The biomass facility will be located in a stand‐alone building on the north side of the school building, which is the high side of the building. There are residential areas west, north, and east of the proposed biomass facility which are uphill (above) the facility. The precise dimensions of that building, the stack location and dimensions, and the biomass equipment specifications have not been determined. The degree of separation of the biomass building from the other buildings will create a buffer for emissions dispersion. Figure 2: Site Map of the Ketchikan High School Project Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 4 Figure 3 shows CTA Architects’ plan of the location of the proposed biomass facility at the Ketchikan Indian Council Medical Facility. The site slopes moderately to steeply downward in the southeasterly direction. As a result, there are buildings above and below the site. The biomass facility will be located in a stand‐alone building on the northeast (uphill) side of the school building. The precise dimensions of that building, the stack location and dimensions, and the biomass equipment specifications have not been determined. The degree of separation of the biomass building from the other buildings will create a small buffer for emissions dispersion. Figure 3: Site Map of the Ketchikan Indian Council Medical Facility Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 5 Figure 4 shows CTA Architects’ plan of the location of the Ketchikan Indian Council Votec School (marked Stedman) and Ketchikan Indian Council Admin Building (marked Deermount). The sites slope moderately to steeply downward in the southeasterly direction. As a result, there are buildings above and below the sites. The precise dimensions of that building, the stack location and dimensions, and the biomass equipment specifications have not been determined. Figure 4: Site Map of Ketchikan Indian Council Votec School (Stedman) and the Admin Building (Deermount) Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 6 A USGS map is provided below in Figure 5. As shown, Craig Island is relatively flat with mountainous terrain to the west, and water in all other directions. The area is relatively sparsely populated. The population of Craig is 1,397. Our review of the area did not reveal any significant emission sources or ambient air quality issues. Figure 5: USGS Map Illustrating the Craig Study Area Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 7 Figure 6 shows CTA Architects’ plan of the location of the proposed biomass facility and the surrounding buildings. The site is relatively flat and moderately populated with one and two story high buildings. The boiler plant is located in a stand‐alone building to the west of the Tribal Association Building and east of another building. The stack should be designed to provide plume rise above both of these buildings. The precise dimensions of that building, the stack location and dimensions, and the biomass equipment specifications have not been determined. Figure 6: Site Map of the Craig Tribal Association Building Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 8 Figure 7 shows CTA Architects’ plan of the proposed Shaan‐Seet biomass facility and the surrounding buildings. The site is relatively flat and moderately populated with one and two story high buildings. The boiler plant is located in a stand‐alone building. The precise dimensions of that building, the stack location and dimensions, and the biomass equipment specifications have not been determined. Figure 7: Site Map of Shaan‐Seet Boiler Plant Site Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 9 METEOROLOGY Meteorological data from Annette, AK, was reviewed to develop an understanding of the weather conditions. Annette is the closest weather data representing the climactic conditions occurring in the Panhandle and is therefore a good proxy of Ketchikan and Craig weather conditions. This data indicates calm winds occur only 10% of the year when, which suggests there will be minimal time periods when thermal inversions and therefore poor emission dispersion conditions can occur.1 Figure 8: Wind Speed Data from Annette, AK 1 See: http://climate.gi.alaska.edu/Climate/Wind/Speed/Annette/ANN.html Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 10 DESIGN & OPERATION RECOMMENDATIONS The following are suggested for designing this project:  Burn natural wood, whose characteristics (moisture content, bark content, species, geometry) results in optimal combustion in the equipment selected for the project.  Do not install a rain cap above the stack. Rain caps obstruct vertical airflow and reduce dispersion of emissions.  Construct the stack to at least 1.5 times the height of the tallest roofline of the adjacent building. Hence, a 20 foot roofline would result in a minimum 30 foot stack. Attention should be given to constructing stacks higher than 1.5 times the tallest roofline given higher elevations of surrounding residences due to the moderate to steep slopes present.  Operate and maintain the boiler according to manufacturer’s recommendations.  Perform a tune‐up at least every other year as per manufacturer’s recommendations and EPA guidance (see below for more discussion of EPA requirements)  Conduct regular observations of stack emissions. If emissions are not characteristic of good boiler operation, make corrective actions.  For the Ketchikan High School: install at minimum a multicyclone to filter particulate matter emissions. These design and operation recommendations are based on the assumption that state‐of‐the‐ art combustion equipment is installed. STATE AND FEDERAL PERMIT REQUIREMENTS This project will not require an air pollution control permit from the Alaska Department of Environmental Quality given the boilers’ relatively small size and corresponding quantity of emissions. However, this project will be subject to new proposed requirements in the federal “Area Source Rule” (40 CFR 63 JJJJJJ). A federal permit is not needed. However, there are various record keeping, reporting and operation and maintenance requirements which must be performed to demonstrate compliance with the requirements in the Area Source Rule. The proposed changes have not been finalized. Until that time, the following requirements are applicable:  Submit initial notification form to EPA within 120 days of startup.  Complete biennial tune ups per EPA method.  Submit tune‐up forms to EPA. Please note the following:  Oil and coal fired boilers are also subject to this rule. Ketchikan‐Craig Air Quality Feasibility Study Resource Systems Group, Inc. 24 July 2012 page 11  Gas fired boilers are not subject to this rule.  More requirements are applicable to boilers equal to or greater than 10 MMBtu/hr heat input. These requirements typically warrant advanced emission controls, such as a baghouse or an electrostatic precipitator (ESP). The compliance guidance documents and compliance forms can be obtained on the following EPA web page: http://www.epa.gov/boilercompliance/ SUMMARY RSG has completed an air quality feasibility study for Ketchikan and Craig, Alaska. These boilers are not subject to state permitting requirements, but are subject to federal requirements. Design criteria have been suggested to minimize emissions and maximize dispersion. The following conditions suggest advanced emission control devices (ESP, baghouse) are not mandatory in Ketchikan and Craig: 1. The wood boilers will be relatively small emission sources. 2. Most of the wood boilers will be located in a separate building which will create a dispersion buffer between the boiler stack and the building. 3. There are no applicable federal or state emission limits. 4. Meteorological conditions are favorable for dispersion. The following conditions suggest additional attention should be given to controlling emissions in Ketchikan: 1. Presence of other emission sources. 2. Relatively high population density. 3. The sensitive populations housed by all Ketchikan buildings. While not mandatory, we recommend exploring the possibility of a cyclone or multi‐cyclone technology for control of fly ash and larger particulate emissions for all the aforementioned boilers. We also recommend developing a compliance plan for the aforementioned federal requirements. Given its size and sensitive population served, air dispersion modeling can be performed for the Ketchikan High School site to determine the stack height and degree of emission control (multicyclone vs ESP). Please contact me if you have any comments or questions. APPENDIX E Wood Fired Heating Technologies WOOD FIRED HEATING TECHNOLOGIES CTA has developed wood-fired heating system projects using cord wood, wood pellet and wood chips as the primary feedstock. A summary of each system type with the benefits and disadvantages is noted below. Cord Wood Cord wood systems are hand-stoked wood boilers with a limited heat output of 150,000- 200,000 British Thermal Units per hour (Btu/hour). Cord wood systems are typically linked to a thermal storage tank in order to optimize the efficiency of the system and reduce the frequency of stoking. Cord wood boiler systems are also typically linked to existing heat distribution systems via a heat exchanger. Product data from Garn, HS Tarm and KOB identify outputs of 150,000-196,000 Btu/hr based upon burning eastern hardwoods and stoking the boiler on an hourly basis. The cost and practicality of stoking a wood boiler on an hourly basis has led most operators of cord wood systems to integrate an adjacent thermal storage tank, acting similar to a battery, storing heat for later use. The thermal storage tank allows the wood boiler to be stoked to a high fire mode 3 times per day while storing heat for distribution between stoking. Cord wood boilers require each piece of wood to be hand fed into the firebox, hand raking of the grates and hand removal of ash. Ash is typically cooled in a barrel before being stock piled and later broadcast as fertilizer. Cordwood boilers are manufactured by a number of European manufacturers and an American manufacturer with low emissions. These manufacturers currently do not fabricate equipment with ASME (American Society of Mechanical Engineers) certifications. When these non ASME boilers are installed in the United States, atmospheric boilers rather than pressurized boilers are utilized. Atmospheric boilers require more frequent maintenance of the boiler chemicals. Emissions from cord wood systems are typically as follows: PM2.5 >0.08 lb/MMbtu NOx 0.23 lb/MMbtu SO2 0.025 lb/MMbtu CO2 195 lb/MMbtu Benefits: Small size Lower cost Local wood resource Simple to operate Disadvantages: Hand fed - a large labor commitment Typically atmospheric boilers (not ASME rated) Thermal Storage is required Page 1 Wood Pellet Wood pellet systems can be hand fed from 40 pound bags, hand shoveled from 2,500 pound sacks of wood pellets, or automatically fed from an adjacent agricultural silo with a capacity of 30-40 tons. Pellet boilers systems are typically linked to existing heat distribution systems via a heat exchanger. Product data from KOB, Forest Energy and Solagen identify outputs of 200,000-5,000,000 Btu/hr based upon burning pellets made from waste products from the western timber industry. A number of pellet fuel manufacturers produce all tree pellets utilizing bark and needles. All tree pellets have significantly higher ash content, resulting in more frequent ash removal. Wood pellet boilers typically require hand raking of the grates and hand removal of ash 2-3 times a week. Automatic ash removal can be integrated into pellet boiler systems. Ash is typically cooled in a barrel before being stock piled and later broadcast as fertilizer. Pellet storage is very economical. Agricultural bin storage exterior to the building is inexpensive and quick to install. Material conveyance is also borrowed from agricultural technology. Flexible conveyors allow the storage to be located 20 feet or more from the boiler with a single auger. Emissions from wood pellet systems are typically as follows: PM2.5 >0.09 lb/MMbtu NOx 0.22 lb/MMbtu SO2 0.025 lb/MMbtu CO2 220 lb/MMbtu Benefits: Smaller size (relative to a chip system) Consistent fuel and easy economical storage of fuel Automated Disadvantages: Higher system cost Higher cost wood fuel ($/MMBtu) Page 2 Page 3 Wood Chip Chip systems utilize wood fuel that is either chipped or ground into a consistent size of 2-4 inches long and 1-2 inches wide. Chipped and ground material includes fine sawdust and other debris. The quality of the fuel varies based upon how the wood is processed between the forest and the facility. Trees which are harvested in a manner that minimizes contact with the ground and run through a chipper or grinder directly into a clean chip van are less likely to be contaminated with rocks, dirt and other debris. The quality of the wood fuel will also be impacted by the types of screens placed on the chipper or grinder. Fuel can be screened to reduce the quantity of fines which typically become airborne during combustion and represent lost heat and increased particulate emissions. Chipped fuel is fed from the chip van into a metering bin, or loaded into a bunker with a capacity of 60 tons or more. Wood chip boilers systems are typically linked to existing heat distribution systems via a heat exchanger. Product data from Hurst, Messersmith and Biomass Combustion Systems identify outputs of 1,000,000 - 50,000,000 Btu/hr based upon burning western wood fuels. Wood chip boilers typically require hand raking of the grates and hand removal of ash daily. Automatic ash removal can be integrated into wood chip boiler systems. Ash is typically cooled in a barrel before being stock piled and later broadcast as fertilizer. Emissions from wood chip systems are typically as follows: PM2.5 0.21 lb/MMbtu NOx 0.22 lb/MMbtu SO2 0.025 lb/MMbtu CO2 195 lb/MMbtu Benefits: Lowest fuel cost of three options ($/MMBtu) Automated Can use local wood resources Disadvantages: Highest initial cost of three types Larger fuel storage required Less consistent fuel can cause operational and performance issues