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BBNC-ILI-CAEC LPSD Newhalen School 2012-EE
Newhalen School 900 School Road Newhalen, Alaska 99606 AkWarm ID No. BBNC-ILI-CAEC-01 Submitted by: Central Alaska Engineering Company Contact: Jerry P. Herring, P.E., C.E.A. 32215 Lakefront Drive Soldotna, Alaska 99669 Phone (907) 260-5311 akengineer@starband.net June 27, 2012 CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE i OF iv CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE ii OF iv CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE iii OF iv AEE ...................................................................................................................... Association of Energy Engineers AHFC ........................................................................................................... Alaska Housing Finance Corporation AHU .............................................................................................................................................. Air Handling Unit ARIS ............................................................................................................... Alaska Retrofit Information System ARRA .................................................................................................. American Recovery and Reinvestment Act ASHRAE .................................. American Society of Heating, Refrigeration, and Air-Conditioning Engineers BPO .................................................................................................................................... Building Plant Operator BTU ......................................................................................................................................... British Thermal Unit CAEC ......................................................................................................... Central Alaska Engineering Company CCF .................................................................................................................................... Hundreds of Cubic Feet CFL ......................................................................................................................................... Compact Fluorescent CFM ...................................................................................................................................... Cubic Feet per Minute DDC ........................................................................................................................................ Direct Digital Control deg F ........................................................................................................................................... Degrees Fahrenheit DHW ........................................................................................................................................ Domestic Hot Water ECI .............................................................................................................................................. Energy Cost Index EEM .............................................................................................................................. Energy Efficiency Measure EMCS ........................................................................................................... Energy Management Control System EPA ................................................................................................................... Environmental Protection Agency EUI .................................................................................................................................... Energy Utilization Index hr(s) ................................................................................................................................................................ Hour(s) HP ........................................................................................................................................................... Horsepower HPS ........................................................................................................................................ High Pressure Sodium H&V ................................................................................................................................... Heating and Ventilation IES ....................................................................................................................... Illuminating Engineering Society IGA ..................................................................................................................................... Investment Grade Audit kBtu ................................................................................................................ Thousands of British Thermal Units kWh .................................................................................................................................................... Kilowatt Hour LED ......................................................................................................................................... Light Emitting Diode LPSD ............................................................................................................... Lake and Peninsula School District ORNL .................................................................................................................... Oak Ridge National Laboratory sf ............................................................................................................................................................... Square Feet SIR ............................................................................................................................... Savings to Investment Ratio SP ...................................................................................................................................................... Simple Payback W ....................................................................................................................................................................... Watts CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE iv OF iv REPORT DISCLAIMER This Investment Grade Audit (IGA) was performed using American Recovery and Reinvestment Act (ARRA) funds, managed by Alaska Housing Finance Corporation (AHFC). IGA’s are the property of the State of Alaska, and may be incorporated into AkWarm-C, the Alaska Retrofit Information System (ARIS), or other state and/or public information systems. AkWarm-C is a building energy modeling software developed under contract by AHFC. This material is based upon work supported by the Department of Energy under Award Number DE- EE0000095. This report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof. This energy audit is intended to identify and recommend potential areas of energy savings, estimate the value of the savings and approximate the costs to implement the recommendations. Any modifications or changes made to a building to realize the savings must be designed and implemented by licensed, experienced professionals in their fields. Lighting recommendations should all be first analyzed through a thorough lighting analysis to assure that the recommended lighting upgrades will comply with State of Alaska Statute as well as Illuminating Engineering Society (IES) recommendations. Central Alaska Engineering Company bears no responsibility for work performed as a result of this report. Payback periods may vary from those forecasted due to the uncertainty of the final installed design, configuration, equipment selected, and installation costs of recommended Energy Efficiency Measures (EEMs), or the operating schedules and maintenance provided by the owner. Furthermore, EEMs are typically interactive, so implementation of one EEM may impact the cost savings from another EEM. Neither the auditor, Central Alaska Engineering Company, AHFC, nor any other party involved in preparation of this report accepts liability for financial loss due to EEMs that fail to meet the forecasted payback periods. This energy audit meets the criteria of a Level 2 IGA per the American Society of Heating, Refrigeration, Air-conditioning Engineers (ASHRAE). The life of the IGA may be extended on a case- by-case basis, at the discretion of AHFC. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 1 OF 22 This report presents the findings of an investment grade energy audit conducted for: Lake and Peninsula School District Contact: Tim McDermott PO Box 498 King Salmon, AK 99613 Email: tmcdermott@lpsd.com Alaska Housing Finance Corporation Contact: Rebekah Luhrs 4300 Boniface Parkway Anchorage, AK 99510 Email: rluhrs@ahfc.us This audit was performed using ARRA funds to promote the use of innovation and technology to solve energy and environmental problems in a way that improves the State’s economy. This can be achieved through the wiser and more efficient use of energy. The purpose of the energy audit is to identify cost-effective system and facility modifications, adjustments, alterations, additions and retrofits. Systems investigated during the audit included heating, ventilation, and air conditioning (HVAC), interior and exterior lighting, motors, building envelope, and energy management control systems (EMCS). The July 2008 – June 2010 average annual utility costs at this facility are as follows: Electricity $ 70,320 Fuel Oil $ 83,956 Total $ 154,276 Energy Utilization Index: 88.1 kBtu/sf Energy Cost Index: 5.38 $/sf Energy Use per Occupant: 63.2 MMBtu per Occupant Energy Cost per Occupant: $3,859 per Occupant The potential annual energy savings are shown on the following page in Table 1.1 which summarizes the Energy Efficiency Measures (EEM’s) analyzed for Newhalen School. Listed are the estimates of the annual savings, installed cost, and two different financial measures of return on investment. Be aware that the measures are not cumulative because of the interrelation of several of the measures. The cost of each measure for this level of auditing is considered to be + 30% until further detailed engineering, specifications, and hard proposals are obtained. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 2 OF 22 Rank Feature Improvement Description Annual Energy Savings (w/Maint. Savings) Installed Cost1 Savings to Investme nt Ratio, SIR2 Simple Payback (w/Maint. Savings)3 1 Refrigeration - Controls Retrofit: Vending Machine Add new Seasonal Shutdown $420 $900 8.97 2.1 2 Setback Thermostat: Gym Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Gym space. $1,856 $16,757 1.48 9.0 3 Setback Thermostat: Main floor Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Main floor space. $4,134 $40,495 1.36 9.8 4 Setback Thermostat: 2nd floor Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the 2nd floor space. $4,500 $45,011 1.34 10.0 5 HVAC And DHW Install new DDC system to reduce operating schedules of heating systems [$185,124]. Place timer on DHW circ pump [$3,000]. $8,489 ($2,000) $188,124 1.06 22.2 (17.9) 6 Ventilation Install new DDC system to reduce operating schedule of heating systems [$125,124]. $3,000 ($3,000) $125,124 1.00 41.7 (20.9) 7 Lighting - Combined Retrofit: Gym Replace with 26 FLUOR (2) T5 45.2" F28T5 28W High Lumen (3050 L) HighEfficElectronic and Add new Occupancy Sensor, Multi- Level Switch $544 ($4,480) $60,000 1.00 110.3 (11.9) 8 Lighting - Combined Retrofit: HPS Replace with 9 LED 25W Module StdElectronic and Add new Occupancy Sensor and Improve Manual Switching $735 ($1,440) $30,000 0.86 40.8 (13.8) 9 Lighting - Combined Retrofit: 2 bulb T12 Replace with 18 FLUOR (2) T8 4' F32T8 25W Energy-Saver Program HighEfficElectronic and Add new Occupancy Sensor $793 ($288) $17,000 0.75 21.4 (15.7) TOTAL, all measures $24,471 ($11,208) $523,411 1.09 21.4 (14.7) Table Notes: 1. Cost estimates were generated using the Program Demand Cost Model for Alaskan Schools, 12th Edition, Updated 2011, developed for the State of Alaska DOE, Education Support Services/Facilities. Renovations Projects Manual provides information on school renovation costs. Upon developing a final scope of work for an upgrade with detailed engineering completed, detailed savings and benefits can then be better determined. Some of the EEM’s should be completed when equipment meets the burn-out phase and is required to be replaced and in some cases will take significant investment to achieve. 2. Savings to Investment Ratio (SIR) is a life-cycle cost measure calculated by dividing the total savings over the life of a project (expressed in today’s dollars) by its investment costs. The SIR is an indication of the profitability of a measure; the higher the SIR, the more profitable the project. An SIR greater than 1.0 indicates a cost-effective project (i.e. more savings than cost). Remember that this profitability is based on the position of that Energy Efficiency Measure (EEM) in the overall list and assumes that the measures above it are implemented first. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 3 OF 22 3. Simple Payback (SP) is a measure of the length of time required for the savings from an EEM to payback the investment cost, not counting interest on the investment and any future changes in energy prices. It is calculated by dividing the investment cost by the expected first-year savings of the EEM. With all of these energy efficiency measures in place, the annual utility cost can be reduced by $24,471 per year, or 15.8% of the buildings’ total energy costs. These measures are estimated to cost $523,411, for an overall simple payback period of 21.4 years. If only the cost-effective measures are implemented (i.e. SIR > 1.0), the annual utility cost can be reduced by $22,943 per year, or 14.8% of the buildings’ total energy costs. These measures are estimated to cost $476,411, for an overall simple payback period of 20.8 years. Table 1.2 below is a breakdown of the annual energy cost across various energy end use types, such as Space Heating and Water Heating. The first row in the table shows the breakdown for the building as it is now. The second row shows the expected breakdown of energy cost for the building assuming all of the retrofits in this report are implemented. Finally, the last row shows the annual energy savings that will be achieved from the retrofits. Description Space Heating Water Heating Lighting Refrigeration Other Electrical Ventilation Fans Total Cost Existing Building $111,355 $14,149 $17,539 $4,552 $1,171 $6,218 $154,985 With All Proposed Retrofits $96,992 $7,315 $15,467 $4,132 $1,171 $5,437 $130,514 SAVINGS $14,363 $6,835 $2,072 $420 $0 $781 $24,471 While the intent of many Energy Efficiency Measures is to increase the efficiency of fuel-burning and electrical equipment, an important factor of energy consumption lies in the operational profiles which control the equipment usage. Such profiles can be managed by administrative controls and departmental leadership. They determine how and when equipment is used, and therefore have a greater impact on energy savings potential than simple equipment upgrades alone. Significant energy cost savings can be realized when EEMs are combined with efficient minded operational profiles. Operational profiles may be outlined by organization policy or developed naturally or historically. These profiles include, but are not limited to; operating schedules, equipment set-points and control strategies, maintenance schedules, and site and equipment selection. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 4 OF 22 Optimization of operational profiles can be accomplished by numerous methods so long as the intent is reduction in energy-using equipment runtime. Due to the numerous methods of optimization, energy cost savings solely as a result of operational optimization are difficult to predict. Quantification, however, is easy to accomplish by metering energy usage during and/or after implementation of energy saving operational profiles and EEMs. Optimization of site selection includes scheduling and location of events. If several buildings in a given area are all lightly used after regularly occupied hours, energy savings can be found when after-hour events are consolidated and held within the most energy efficient buildings available for use. As a result, unoccupied buildings could be shut-down to the greatest extent possible to reduce energy consumption. Operational behaviors which can be combined with equipment upgrades are operating schedules and equipment control strategies including set-points. Occupancy and daylight sensors can be programmed to automatically shut-off or dim lighting when rooms are unoccupied or sufficiently lit from the sun. Operating schedules can be optimized to run equipment only during regular or high-occupancy periods. Also, through a central control system, or with digital programmable thermostats, temperature set-points can be reduced during low-occupancy hours to maximize savings. In addition, domestic hot water circulation systems and sporadically used equipment can be shut-down during unoccupied hours to further save energy. In general, having equipment operating in areas where no occupants are present is inefficient, and presents an opportunity for energy savings. Operational profiles can also be implemented to take advantage of no or low cost EEMs. Examples include heating system optimizations (boiler section cleaning, boiler flush-through cleaning, and completing preventative maintenance on outside air damper and temperature reset systems) and tighter controls of equipment set-backs and shut-downs (unoccupied zones equipment shut-down, easier access to and finer control of equipment for after-hours control). In a large facility management program, implementation of these measures across many or all sites will realize dramatic savings due to the quantity of equipment involved. Changes to building operational profiles can only be realized while simultaneously addressing health, safety, user comfort, and user requirements first. It is impractical to expect users to occupy a building or implement operational behaviors which do not meet such considerations. That said, it is quite practical for management groups to implement administrative controls which reduce losses brought about by excess and sub-optimum usage. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 5 OF 22 This comprehensive energy audit covers the 28,692 square foot Newhalen School, depicted below in Figure 2.1, including classrooms, restrooms, a kitchen, and a gymnasium. This school also features a vocational education building, a boiler building, and several teacher housing facilities; all of which are separate buildings that are not connected to the main school. The teacher housing buildings are being used throughout the school year with occasional use in the summer. Utility information was collected and analyzed for two years of energy use by the building. This information was used to analyze operational characteristics, calculate energy benchmarks for comparison to industry averages, estimate savings potential and establish a baseline to monitor the effectiveness of implemented measures. An excel spreadsheet was used to enter, sum, and calculate benchmarks and to graph energy use information (refer to Appendix A for the Benchmark Report). The Annual Energy Utilization Index (EUI) is expressed in Thousands of British Thermal Units/Square Foot (kBtu/sf) and can be used to compare energy consumption to similar building types or to track consumption from year to year in the same building. The EUI is calculated by converting annual consumption of all fuels used to Btu’s then dividing by the area (gross conditioned square footage) of the building. EUI is a good indicator of the relative potential for energy savings. A comparatively low EUI indicates less potential for large energy savings. Building architectural drawings were utilized to calculate and verify the gross area of the facility. The gross area was confirmed on the physical site investigation. Refer to Section 6.0 of this report for additional details on EUI issues. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 6 OF 22 After gathering the utility data and calculating the EUI, the next step in the audit process was to review the drawings to develop a building profile which documented the building age, type, usage, and major energy consuming equipment or systems such as lighting, heating and ventilation (H&V), domestic hot water heating, refrigeration, etc. The building profile is utilized to generate, and answer, possible questions regarding the facility’s energy usage. These questions were then compared to the energy usage profiles developed during the utility data gathering step. After this information is gathered, the next step in the process is the physical site investigation (site visit). The site visit was completed on June 3, 2012 and was spent inspecting the actual systems and answering specific questions from the preliminary review. Occupancy schedules, O&M practices, building energy management program, and other information that has an impact on energy consumption were obtained. Photos of the major equipment and building construction were taken during the site visit. Several of the site photos are included in this report as Appendix D. Additionally during the site visit, thermal images of the building’s exterior were taken. These thermal images illustrate heat loss exhibited by the school. Several of the thermal images are included in this report as Appendix E. The post-site work includes evaluation of the information gathered during the site visits, developing the AkWarm-C Energy Model for the building, researching possible conservation opportunities, organizing the audit into a comprehensive report, and making recommendations on mechanical, electrical and building envelope improvements. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 7 OF 22 Central Alaska Engineering Company (CAEC) began the site survey after completing the preliminary audit tasks noted in Section 2.0. The site survey provided critical input in deciphering where energy opportunities exist within the facility. The audit team walked the entire site to inventory the building envelope (roof, walls, windows and doors, etc.), the major equipment including HVAC, water heating, lighting, and equipment in kitchens, offices, gymnasium, and classrooms. The site survey was used to determine an understanding of how the equipment is used. The collected data was entered into the AkWarm-C Commercial© Software (AkWarm-C), a building energy modeling program developed for Alaska Housing Finance Corporation (AHFC). The data was processed by AkWarm-C to model a baseline from which energy efficiency measures (EEMs) could be considered. The model was compared to actual utility costs to ensure the quality of baseline and proposed energy modeling performed by AkWarm-C. The recommended EEMs focus on the building envelope, HVAC systems, water heating, lighting, and other electrical improvements that will reduce annual energy consumption. EEMs are evaluated based on building use and processes, local climate conditions, building construction type, function, operational schedule, existing conditions, and foreseen future plans. Energy savings are calculated based on industry standard methods and engineering estimations. When new equipment is proposed, energy consumption is calculated based on the manufacturer’s information where possible. Energy savings are calculated by AkWarm-C. Implementation of more than one EEM often affects the savings of other EEMs. The savings may in some cases be relatively higher if an individual EEM is implemented in lieu of multiple recommended EEMs. For example, implementing reduced operating schedule for specific inefficient lighting systems will result in a greater relative savings than merely replacing fixtures and bulbs. Implementing reduced operating schedules for newly installed efficient lighting will result in a lower relative savings, because there is less energy to be saved. If multiple EEM’s are recommended to be implemented, the combined savings is calculated and identified appropriately. Cost savings are calculated based on the historical energy costs for the building. Cost estimates were generated using the Program Demand Cost Model for Alaskan Schools, 12th Edition, Updated 2011, developed for the State of Alaska DOE, Education Support Services/Facilities. Renovations Projects Manual provides information on school renovation costs. The Geographic Area Cost Factor dated April 2011 for the Newhalen area has an index of 160.73 and was used in this report. Installation costs include design, labor, equipment, overhead and profit for school renovation projects and used to evaluate the initial investment required to implement an EEM. These are applied to each recommendation with simple paybacks calculated. In addition, where applicable, maintenance cost savings are estimated and applied to the net savings. The costs and savings are applied and a Simple Payback (SP) and Savings to Investment Ration (SIR) are calculated. These are listed in Section 7.0 and summarized in Table 1.1 of this report. The SP is based on the years that it takes for the net savings to payback the net installation cost (Cost divided by Savings). The SIR is calculated as a ratio by dividing the break even cost by the initial installed cost. The lifetime for each EEM is estimated based on the typical life of the equipment being replaced or altered. The energy savings is extrapolated throughout the lifetime of the EEM. The total energy savings is calculated as the total lifetime multiplied by the yearly savings. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 8 OF 22 The analysis provides a number of tools for assessing the cost effectiveness of various improvement options. These tools utilize Life-Cycle Costing, which is defined in this context as a method of cost analysis that estimates the total cost of a project over the period of time that includes both the construction cost and ongoing maintenance and operating costs. Savings to Investment Ratio (SIR) = Savings divided by Investment Savings includes the total discounted dollar savings considered over the life of the improvement. When these savings are added up, changes in future fuel prices (usually inflationary) as projected by the Alaska Department of Energy are included in the model. Future savings are discounted to the present to account for the time-value of money (i.e. money’s ability to earn interest over time). The Investment in the SIR calculation includes the labor and materials required to install the measure. An SIR value of at least 1.0 indicates that the project is cost-effective - total savings exceed the investment costs. Simple payback is a cost analysis method whereby the investment cost of a project is divided by the first year’s savings of the project to give the number of years required to recover the cost of the investment. This may be compared to the expected time before replacement of the system or component will be required. For example, if a boiler costs $50,000 and results in a savings of $5,000 a year, the payback time is 10 years. If the boiler has an expected life to replacement of 20 years, it would be financially viable to make the investment since the payback period of 10 years is less than the project life. The Simple Payback calculation does not consider likely increases in future annual savings due to energy price increases. As an offsetting simplification, Simple Payback does not consider the need to earn interest on the investment (i.e. it does not consider the time-value of money). Because of these simplifications, the SIR figure is considered to be a better financial investment indicator than the Simple Payback measure. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 9 OF 22 All results are dependent on the quality of input data provided. In this case the site investigation was limited to observable conditions. No testing or destructive investigations were undertaken. Although energy-conserving methods are described in the EEMs, in some instances several methods may also achieve the identified savings. Detailed engineering is required in order to develop the EEMs to a realizable project. This audit and report are thus intended to offer approximations of the results achievable by the listed improvements. This report is not intended to be a final design document. The design professional or other persons following the recommendations shall accept responsibility and liability for the results. An accurate model of the building performance can be created by simulating the thermal performance of the walls, roof, windows and floors of the building. The HVAC system and central plant are modeled as well, accounting for the outside air ventilation required by the building and the heat recovery equipment in place. The model uses local weather data and is trued up to historical energy use to ensure its accuracy. The model can be used now and in the future to measure the utility bill impact of all types of energy projects, including improving building insulation, modifying glazing, changing air handler schedules, increasing heat recovery, installing high efficiency boilers, using variable air volume air handlers, adjusting outside air ventilation and adding cogeneration systems. For the purposes of this study, Newhalen School was modeled using AkWarm-C energy use software to establish a baseline space heating and cooling energy usage. Climate data from Newhalen, Alaska was used for analysis. From this, the model was be calibrated to predict the impact of theoretical energy savings measures. Once annual energy savings from a particular measure were predicted and the initial capital cost was estimated, payback scenarios were approximated. Project cost estimates are provided in the Section 7.0 of this report reviewing the Energy Efficiency Measures. Limitations of the AkWarm-C Commercial© Software are reviewed in this section. The AkWarm-C model is based on typical mean year weather data for Newhalen, Alaska. This data represents the average ambient weather profile as observed over approximately 30 years. As such, the fuel oil and electric profiles generated will not likely compare perfectly with actual energy billing information from any single year. This is especially true for years with extreme warm or cold periods, or even years with unexpectedly moderate weather. The heating and cooling load model is a simple two-zone model consisting of the building’s core interior spaces and the building’s perimeter spaces. This simplified approach loses accuracy for buildings that have large variations in cooling/heating loads across different parts of the building. AkWarm-C does not model HVAC systems that simultaneously provide both heating and cooling to the same building space (typically done as a means of providing temperature control in the space). The energy balances shown were derived from the output generated by the AkWarm-C simulations. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 10 OF 22 The structure of Newhalen School is a two-story facility that was built in 1980. This building has had two (2) additions made to it, adding more classroom space and new locker rooms. From the audit it was determined to be a well built and functional school facility. The school typically opens at 7AM by staff with faculty and student occupancy from 8AM to 4PM during the weekdays. Additional occupancy time keeping the school open late or on weekends occurs occasionally. There are an estimated 40 full time students, faculty, and staff occupants using the building. The insulation values and conditions were modeled using the data provided in the architectural drawings. No destructive testing was completed for the audit. The following are the assumptions made for the AkWarm-C building model: Exterior walls of the building have double paned, vinyl framed windows in place which have an estimated U-factor of 0.33 Btu/hr-sf-F. All doors on this building are commercial grade, insulated and metal framed that are windowed or solid. Most of the doors appear to be in adequate condition, but could use additional weather stripping installed. This school is built as a slab on grade building with 2-inches of slab edge insulation. The above grade wall sections of the school are made up of 6-inch studs filled with fiberglass batt insulation, providing an estimated R-19 composite value. Wall height of the school varies from 15-feet to 30-feet, depending on location. The different wall constructions can be noted in the IR images provided in Appendix E of this report. The roof system of the school is a cathedral ceiling, insulated with 6-inches of polyurethane for an insulating estimated R-34 value. The entirety of the roof is covered with corrugated metal roofing. The building is heated by three (3) fuel oil-fired cast iron boilers which were installed in the year 2007, and one electric boiler, installed in the year 2001. The boilers are located in a detached mechanical room which is neatly configured. The hydronic heating system is circulated throughout the building by two 1½ HP circulation pumps located in the mechanical room, and an additional ¼ HP pump is used to supply water heated by the electric boiler. The electricity required by the electric boiler is purchased at a lower rate, as waste electricity from a nearby hydroelectric plant. Heated water is supplied to the entire school campus using these circulating pumps. The hydronic heat is delivered to the air handlers, unit heaters, and baseboard radiators through the various building hydronic loops. This building has a pneumatic control system in place with end devices using pneumatic controls. The heating plants used in the building are described below: Boiler’s 1, 2, & 3 Fuel Type: Fuel Oil Input Rating: 588,000 Btu/hr OR 4.2 gal/hr Rated Efficiency: 82 % (estimated) Heat Distribution Type: Hydronic, Water Boiler Operation: All Year CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 11 OF 22 Boiler 4 Fuel Type: Electricity Input Rating: 150 kW Rated Efficiency: 95 % (estimated) Heat Distribution Type: Hydronic, Water Boiler Operation: All Year Domestic Hot Water (DHW) is supplied by one (1) electric storage hot water maker. DHW is circulated 24/7 around the building and supplies hot water to the showers, restrooms, kitchen, and the various sinks in the building. Storage Water Heater 1 Fuel Type: Electric Input Rating: 4.5 kW Rated Efficiency: 80 % (estimated) Heat Distribution Type: Circulation 24/7 DHW Maker Operation: All Year There are five (5) AHUs located inside of the building providing ventilation to the gymnasium. The AHUs use pneumatically controlled end devices, controlled by the pneumatic system. Outside air is drawn into the building primarily through windows and these AHUs, when operated. Excess air is removed from the building with the use of exhaust fans located throughout the building. The International Mechanical Code for this application requires the building to bring in 10,042 CFM of outdoor air into the school (minimum design for classroom space specifies 35 occupants/1,000 sf @ 10 CFM/occupant for the 28,692 sf school = 10,042 CFM). The capacity of the exhaust fans in the school equals approximately 2,244 CFM, indicating the school appears to be well over-ventilated at 56.1 CFM/occupant, assuming the exhaust system is operated per design capacity at current occupant level of 40 during school hours. The outdoor air should never be provided at less than 10 CFM/occupant to be code compliant. There are several types of light systems throughout the building. The majority of the building uses older T8 lights. The gym lighting system also uses T8 bulbs. The T8 lighting systems remaining in the building were evaluated for replacement to new Energy-Saver T8, programmable start electronic ballast and occupancy sensor based controls, though at the current utility rates was shown to provide unsubstantial savings. The High Pressure Sodium (HPS) lights mounted on the outside of the building were evaluated for replacement as there have been recent advances in LED technology, often making it a viable option to replace the HPS systems. Interior lights were evaluated as being replaced with new LED technology, though at this time the light output of LED lights is not substantial enough to compete with readily available and cheaper fluorescent bulbs. There are some EEM’s are provided in this report reviewing the lighting system upgrade recommendations. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 12 OF 22 There are several plug loads throughout the building. This includes the computers with monitors, copy machines, refrigerators, kitchen equipment, microwave ovens, coffee pots and shop equipment. These building plug loads are estimated in the AkWarm-C modeling program at 0.05 watts/sf. Following the completion of the field survey a detailed building major equipment inventory was created and is attached as Appendix C. The equipment listed is considered to be the major energy consuming items in the building whose replacement or upgrade could yield substantial energy savings. An approximate age was assigned to the equipment if a manufactured date was not shown on the equipment’s nameplate. As listed in the 2011 ASHRAE Handbook for HVAC Applications, Chapter 37, Table 4, the service life for the equipment along with the remaining useful life in accordance to the ASHRAE standard are also noted in the equipment list. Where there are zero (0) years remaining in the estimated useful life of a piece of equipment, this is an indication that maintenance costs are likely on the rise and more efficient replacement equipment is available which will lower the operating costs of the unit. Maintenance costs should also fall with the replacement. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 13 OF 22 Tables provided in Appendix A, Energy Benchmark Data Report, represent the electric and fuel oil energy usage for the surveyed facility from July 2008 to June 2010. Electricity for the school is provided under large commercial building rate schedules. Electricity for the electric boiler is provided by a nearby hydroelectric power plant, sold as waste electricity at a lower rate schedule. Fuel Oil is being provided under a contract to top off the tanks. The electric utility bills for consumption in kilowatt-hours (kWh) and for maximum demand in kilowatts (kW). One kilowatt-hour is equivalent to 3,413 Btu’s. The consumption (kWh) is determined as the wattage times the hours it is running. For example, 1,000 watts running for one hour, or 500 watts running for two hours is a kWh. The maximum demand is simply the sum of all electrical devices on simultaneously. For example, ten, 100 watt lights running simultaneously would create a demand of 1,000 watts (1 kW). Demand is averaged over a rolling window, usually 15 minutes. Thus, the facility must be concerned not only with basic electricity usage (consumption) but also the rate at which it gets used. The basic usage charges are shown as generation service and delivery charges along with several non-utility generation charges. Identify your school’s major equipment, know when it is used and work with staff to adjust time and duration of use. Also, consider using smart thermostats, relays, timers, on/off switches, and circuit breakers to shut down non-essential equipment and lights before starting equipment which draws a large amount of power. Relays or timers can prevent two large loads from being on at the same time. Peak demand can be best managed if first understood when it occurs. Know your school’s peak months, days and hours. Billing information can be used to acquire your benchmark data on the demand load and cost for the school building. Demand costs can be managed by scheduling times of the day when your electric usage is lowest to run equipment that uses the most power. You may want to pay special attention to equipment such as pumps, electric water heaters, 5-horsepower and larger motors, electric heat and commercial appliances. Most equipment has an identification tag or nameplate that lists the kW, or demand. Some tags may only list the amperage (amps and voltage the equipment uses). You can still use this information to figure the approximate usage rate in kilowatts. Multiply amps by volts and divide by 1,000 to get kilowatts. To help manage demand load and cost, install a special meter that records 15 minute load profile information, allowing you to view the electric power consumption over time. This data can help in determining when the peak loads occur. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 14 OF 22 The fuel oil usage profile shows the predicted fuel oil energy usage for the building. As actual oil usage records were available, the model used to predict usage was calibrated to approximately match actual usage. Fuel oil is sold to the customer in units of gallon (GAL), which contains approximately 140,000 BTUs of energy. The average billing rates for energy use are calculated by dividing the total cost by the total usage. Based on the electric and fuel oil utility data provided, the 2008-2009 through 2009-2010 school year costs for the energy and consumption at the surveyed facility are summarized in Table 6.1 below. 2008-2009 2009-2010 Average Electric 0.47 $/kWh 0.51 $/kWh 0.49 $/kWh Fuel Oil 5.44 $/GAL 5.44 $/GAL 5.44 $/GAL Total Cost $150,684 $157,866 $154,275 ECI 5.25 $/sf 5.50 $/sf 5.38 $/sf Electric EUI 16.8 kBtu/sf 17.3 kBtu/sf 17.1 kBtu/sf Fuel Oil EUI 71.0 kBtu/sf 71.0 kBtu/sf 71.0 kBtu/sf Building EUI 87.8 kBtu/sf 88.3 kBtu/sf 88.1 kBtu/sf Data from the U.S.A. Energy Information Administration provides information for U.S.A. Commercial Buildings Energy Intensity Using Site Energy by Census Region. In 2003, the U.S.A. average energy usage for Education building activity is shown to be 83.0 kBtu/sf. For reference, data from the ARRA funded utility benchmark survey for the subject fiscal years completed on 84 schools in the Anchorage School District computed an average EUI of 106.5 kBtu/sf, and ECI of 1.77 $/sf, with an average building size of 86,356 square feet. Over the analyzed period, the surveyed facility was calculated to have an average EUI of 88.1 kBtu/sf. This means the surveyed facility uses a total of 6.1% more energy than the US average and 17.3% less energy than the Anchorage School District average on a per square foot basis. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 15 OF 22 At current utility rates, the Lake and Peninsula School District is modeled to pay approximately $154,985 annually for electricity and other fuel costs for the Newhalen School. Figure 6.1 below reflects the estimated distribution of costs across the primary end uses of energy based on the AkWarm-C computer simulation. Comparing the “Retrofit” bar in the figure to the “Existing” bar shows the potential savings from implementing all of the energy efficiency measures shown in this report. Figure 6.2 below shows how the annual energy cost of the building splits between the different fuels used by the building. The “Existing” bar shows the breakdown for the building as it is now; the “Retrofit” bar shows the predicted costs if all of the energy efficiency measures in this report are implemented. $0 $50,000 $100,000 $150,000 $200,000 Existing Retrofit Ventilation and Fans Space Heating Refrigeration Other Electrical Lighting Domestic Hot Water Annual Energy Costs by End Use CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 16 OF 22 Figure 6.3 below addresses only Space Heating costs. The figure shows how each heat loss component contributes to those costs; for example, the figure shows how much annual space heating cost is caused by the heat loss through the Walls/Doors. For each component, the space heating cost for the Existing building is shown (blue bar) and the space heating cost assuming all retrofits are implemented (yellow bar) are shown. It should be noted that the retrofit bar for the windows is actually showing a slight negative associated cost, implying that the windows will be adding to the building heating load. The tables below show AkWarm-C ’s estimate of the monthly fuel use for each of the fuels used in the building. For each fuel, the fuel use is broken down across the energy end uses. Electrical Consumption (kWh) Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec Lighting 3937 3588 3937 3810 3826 484 500 2274 3810 3937 3810 1881 Refrigeration 788 719 788 763 788 763 788 788 763 788 763 788 Other Electrical 267 243 267 258 259 22 22 148 258 267 258 121 Ventilation Fans 1347 1228 1347 1304 974 464 480 927 1304 1347 1304 665 DHW 2319 2113 2319 2244 2319 2244 2319 2319 2244 2319 2244 2319 Space Heating 6406 5624 5679 4545 3901 3221 3047 3172 3548 4670 5360 6260 Space Cooling 0 0 0 0 0 0 0 0 0 0 0 0 Fuel Oil #2 Consumption (Gallons) Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec DHW 11 10 11 11 12 12 15 13 11 11 11 11 Space Heating 2503 2131 1995 1266 752 340 152 241 569 1290 1836 2401 CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 17 OF 22 Energy Utilization Index (EUI) is a measure of a building’s annual energy utilization per square foot of building. This calculation is completed by converting all utility usage consumed by a building for one year, to British Thermal Units (Btu) or kBtu’s, and dividing this number by the building square footage. EUI is a good measure of a building’s energy use and is utilized regularly for comparison of energy performance for similar building types. The Oak Ridge National Laboratory (ORNL) Buildings Technology Center under a contract with the U.S. Department of Energy maintains a Benchmarking Building Energy Performance Program. The ORNL website determines how a building’s energy use compares with similar facilities throughout the U.S. and in a specific region or state. Source use differs from site usage when comparing a building’s energy consumption with the national average. Site energy use is the energy consumed by the building at the building site only. Source energy use includes the site energy use as well as all of the losses to create and distribute the energy to the building. Source energy represents the total amount of raw fuel that is required to operate the building. It incorporates all transmission, delivery, and production losses, which allows for a complete assessment of energy efficiency in a building. The type of utility purchased has a substantial impact on the source energy use of a building. The EPA has determined that source energy is the most comparable unit for evaluation purposes and overall global impact. Both the site and source EUI ratings for the building are provided to understand and compare the differences in energy use. The site and source EUIs for this building are calculated as follows. (See Table 6.4 for details): Building Site EUI = (Electric Usage in kBtu + Fuel Oil Usage in kBtu) Building Square Footage Building Source EUI = (Electric Usage in kBtu X SS Ratio + Fuel Oil Usage in kBtu X SS Ratio) Building Square Footage where “SS Ratio” is the Source Energy to Site Energy ratio for the particular fuel. Energy Type Building Fuel Use per Year Site Energy Use per Year, kBTU Source/Site Ratio Source Energy Use per Year, kBTU Electricity 142,918 kWh 487,780 3.340 1,629,184 #2 Oil 15,617 gallons 2,155,117 1.010 2,176,668 Total 2,642,897 3,805,852 BUILDING AREA 28,692 Square Feet BUILDING SITE EUI 92 kBTU/Ft²/Yr BUILDING SOURCE EUI 133 kBTU/Ft²/Yr * Site - Source Ratio data is provided by the Energy Star Performance Rating Methodology for Incorporating Source Energy Use document issued March 2011. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 18 OF 22 The Energy Efficiency Measures are summarized below: Electrical & Appliance Measures The goal of this section is to present lighting energy efficiency measures that may be cost beneficial. It should be noted that replacing current bulbs with more energy-efficient equivalents will have a small effect on the building heating and cooling loads. The building cooling load will see a small decrease from an upgrade to more efficient bulbs and the heating load will see a small increase, as the more energy efficient bulbs give off less heat. Rank Location Existing Condition Recommendation 7 Gym 26 FLUOR (2) T8 4' F32T8 32W Standard Instant StdElectronic with Manual Switching Replace with 26 FLUOR (2) T5 45.2" F28T5 28W High Lumen (3050 L) HighEfficElectronic and Add new Occupancy Sensor, Multi-Level Switch Installation Cost $60,000 Estimated Life of Measure (yrs) 15 Energy Savings ($/yr) $544 Maintenance Savings ($/yr) $4,480 Breakeven Cost $59,871 Savings-to-Investment Ratio 1.0 Simple Payback (yrs) 110 Auditors Notes: This EEM recommends replacement of the gym lights with a modern efficient T5 High Output system. Installation of the more efficient lights and installation of a lighting control package with occupancy sensors and multi-level switching can reduce the gym lighting energy consumption. Below is an example picture of a recently re-lamped elementary gym showing the T5 HO light system. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 19 OF 22 Refrigeration Measures Rank Location Existing Condition Recommendation 8 HPS 9 HPS 70 Watt StdElectronic with Manual Switching Replace with 9 LED 25W Module StdElectronic and Add new Occupancy Sensor and Improve Manual Switching Installation Cost $30,000 Estimated Life of Measure (yrs) 15 Energy Savings ($/yr) $735 Maintenance Savings ($/yr) $1,440 Breakeven Cost $25,824 Savings-to-Investment Ratio 0.9 Simple Payback (yrs) 41 Auditors Notes: All of the high pressure sodium lights mounted on the outside of the building are considered to be good candidates for replacement as the heat they emit is wasted to the outdoors. There have been recent advances in LED technology and are recommended to replace the HPS systems. This recommendation assumes a Dark Campus environment where the lights are turned off during the late evening and early morning hours and are turned on under motion sensor activation, security alarm activation, or when controlled by the Building Automation System, when available. Rank Location Existing Condition Recommendation 9 2 bulb T12 18 FLUOR (2) T12 4' F40T12 40W Standard Magnetic with Manual Switching Replace with 18 FLUOR (2) T8 4' F32T8 25W Energy-Saver Program HighEfficElectronic and Add new Occupancy Sensor Installation Cost $17,000 Estimated Life of Measure (yrs) 15 Energy Savings ($/yr) $793 Maintenance Savings ($/yr) $288 Breakeven Cost $12,753 Savings-to-Investment Ratio 0.8 Simple Payback (yrs) 21 Auditors Notes: This EEM is recommending the existing 40-Watt T12 lights in the building be replaced with 25-Watt Energy Saver T8 bulbs and programmable start ballasts. Additionally, these lights should be installed with occupancy sensors, if not already, and controls for daylight harvesting. Rank Location Description of Existing Efficiency Recommendation 1 Vending Machine Vending Machine Add new Seasonal Shutdown Installation Cost $900 Estimated Life of Measure (yrs) 30 Energy Savings ($/yr) $420 Breakeven Cost $8,073 Savings-to-Investment Ratio 9.0 Simple Payback (yrs) 2 Auditors Notes: There are many no and low cost ways to cut the energy use of a refrigerated vending machine. Vending machines generate good savings in buildings that are not occupied around the clock. Installation of a Vending Miser Control System (or equivalent) is estimated to save 20% on electric energy costs. A refrigerated vending machine operates 24 hours, seven days per week. It was noted that during the summer months, the refrigerated vending machines were not unplugged thereby consuming energy year round. This case study evaluated the use of seasonal shutdown during the summer break months. If the vending machine is leased, then the cost of installation of a control system is recommended to be installed by the owner of the vending machine. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 20 OF 22 Heating/Cooling/Domestic Hot Water Measure Ventilation System Measures Rank Recommendation 5 Install new DDC system to reduce operating schedules of heating systems [$185,124]. Place timer on DHW circ pump [$3,000]. Installation Cost $188,124 Estimated Life of Measure (yrs) 30 Energy Savings ($/yr) $8,489 Maintenance Savings ($/yr) $2,000 Breakeven Cost $199,409 Savings-to-Investment Ratio 1.1 Simple Payback (yrs) 22 Auditors Notes: Implementing a reduced operating time scheme for the pumps throughout the heating water distribution system will reduce the amount of power used by motors during non-critical times of the day. It is also recommended that the current pneumatic control system be replaced with a modern DDC control system. This upgrade would include replacing the pneumatic controls throughout the school with the new system, as well as programming the new system to better manage the existing heating and ventilation equipment in the school. Rank Description Recommendation 6 Install new DDC system to reduce operating schedule of heating systems [$125,124]. Installation Cost $125,124 Estimated Life of Measure (yrs) 30 Energy Savings ($/yr) $3,000 Maintenance Savings ($/yr) $3,000 Breakeven Cost $125,306 Savings-to-Investment Ratio 1.0 Simple Payback (yrs) 42 Auditors Notes: The programming of ventilation equipment to reduce speed during unoccupied periods has the potential to save a portion of the total electric power cost. This can be done with no noticeable difference to the occupants of the building, which is vacant or near vacant during low speed periods. There is no need for fresh air when the building is vacant. Installation of demand control on the air handling unit by installing carbon dioxide controllers can be used to optimize run time. The entire DDC system will be spread across the heating and setback temperature controls and has some of the overall cost partitioned within these areas. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 21 OF 22 Night Setback Thermostat Measures Rank Building Space Recommendation 2 Gym Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Gym space. Installation Cost $16,757 Estimated Life of Measure (yrs) 15 Energy Savings ($/yr) $1,856 Breakeven Cost $24,808 Savings-to-Investment Ratio 1.5 Simple Payback (yrs) 9 Auditors Notes: There are economic reasons why the thermostatic controller set points should be setback during off peak use hours. However one important control data input concerns the water dew point of the air. The water dew point of the inside air varies with the seasons. Currently, there is no humidity measuring instruments normally available to or monitored by the control system or staff and this data is needed before choosing the ideal “setback” temperatures which varies with the season. As outside air temperatures rise, the inside air dew point also rises. The staff is likely to complain about mildew and mold smells if the temperature is dropped below the dew point and condensation occurs. In keeping with this mildew and mold concern, it is recommended that the control system monitor the water dew point within the building to select how far back the temperature can be set during low use periods. If the water dew point is above 70 oF, then set up the temperature not back. If the water dew point is 50 oF or below, then reduce the setback temperature control toward 60oF. Other parameters relating to the building setback temperature include warm-up time required to reheat the building and preventing any water pipes near the building perimeter from freezing. During extreme cold periods, reducing the setback temperature limit and time appropriately is required to prevent possible problems. Rank Building Space Recommendation 3 Main floor Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Main floor space. Installation Cost $40,495 Estimated Life of Measure (yrs) 15 Energy Savings ($/yr) $4,134 Breakeven Cost $55,266 Savings-to-Investment Ratio 1.4 Simple Payback (yrs) 10 Auditors Notes: See EEM #2 for similar notes. Rank Building Space Recommendation 4 2nd floor Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the 2nd floor space. Installation Cost $45,011 Estimated Life of Measure (yrs) 15 Energy Savings ($/yr) $4,500 Breakeven Cost $60,161 Savings-to-Investment Ratio 1.3 Simple Payback (yrs) 10 Auditors Notes: See EEM #2 for similar notes. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT AkWarm ID No. BBNC‐ILI‐CAEC‐01 PAGE 22 OF 22 Through inspection of the energy-using equipment on-site and discussions with site facilities personnel, this energy audit has identified several energy-saving measures. The measures will reduce the amount of fuel burned and electricity used at the site. The projects will not degrade the performance of the building and, in some cases, will improve it. Several types of EEMs can be implemented immediately by building staff, and others will require various amounts of lead time for engineering and equipment acquisition. In some cases, there are logical advantages to implementing EEMs concurrently. For example, if the same electrical contractor is used to install both lighting equipment and motors, implementation of these measures should be scheduled to occur simultaneously. The Alaska Housing Finance Corporation (AHFC) Alaska Energy Efficiency Revolving Loan Fund (AEERLF) is a State of Alaska program enacted by the Alaska Sustainable Energy Act (Senate Bill 220, A.S. 18.56.855, “Energy Efficiency Revolving Loan Fund”). The AEERLF will provide loans for energy efficiency retrofits to public facilities via the Retrofit Energy Assessment for Loan System (REAL). As defined in 15 AAC 155.605, the program may finance energy efficiency improvements to buildings owned by: a. Regional educational attendance areas; b. Municipal governments, including political subdivisions for municipal governments; c. The University of Alaska; d. Political subdivisions of the State of Alaska, or e. The State of Alaska Refer to the Retrofit Energy Assessment for Loans manual which can be obtained from AHFC for more information on this program. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL K‐12 ENERGY AUDIT REPORT APPENDIX A Appendix A Benchmark Reports First Name Last Name Middle Name Phone Tim McDermott 246‐4280 ext 318 State Zip AK 99613 Monday‐ Friday Saturday Sunday Holidays 7 to 50 0 0 Average # of Occupants During 40 Renovations / Notes Date 1988 1993 2005 Note: PART II – ENERGY SOURCES Heating Oil Electricity Natural Gas Propane Wood Coal $ /gallon $ / kWh $ / CCF $ / gal $ / cord $ / ton Other energy sources? All utility data includes teacher housing and school building usage. 88.3% of utility data was allocated to school building, per LPSD estimates. Locker room addition Classroom addition Classroom addition Contact Person Email tmcdermott@lpsd.com Mailing Address City PO Box 498 King Salmon Primary Operating Hours Details 2. Provide utilities bills for the most recent two‐year period for each energy source you use. Regional Education Attendance 06/12/12 REAL Preliminary Benchmark Data Form PART I – FACILITY INFORMATION Facility Owner Facility Owned By Date Lake & Peninsula School Dist Building Name/ Identifier Building Usage Building Square Footage Newhalen School Education ‐ K ‐ 12 28,692 Building Type Community Population Year Built Wood Frame 1. Please check every energy source you use in the table below. If known, please enter the base rate you pay for the energy source. Facility Address Facility City Facility Zip 99606900 School Rd Newhalen 118 1980 Oil data provided for 2 years, and was divided in half. Newhalen K-12 Buiding Size Input (sf) =28,692 2009 Natural Gas Consumption (Therms)0.00 2009 Natural Gas Cost ($)0 2009 Electric Consumption (kWh)141,308 2009 Electric Cost ($)66,729 2009 Oil Consumption (Therms)20,375.15 2009 Oil Cost ($)83,956 2009 Propane Consumption (Therms)0.00 2009 Propane Cost ($)0.00 2009 Coal Consumption (Therms)0.00 2009 Coal Cost ($)0.00 2009 Wood Consumption (Therms)0.00 2009 Wood Cost ($)0.00 2009 Thermal Consumption (Therms)0.00 2009 Thermal Cost ($)0.00 2009 Steam Consumption (Therms)0.00 2009 Steam Cost ($)0.00 2009 Total Energy Use (kBtu)2,519,801 2009 Total Energy Cost ($)150,684 Annual Energy Use Intensity (EUI) 2009 Natural Gas (kBtu/sf) 0.0 2009 Electricity (kBtu/sf)16.8 2009 Oil (kBtu/sf) 71.0 2009 Propane (kBtu/sf) 0.0 2009 Coal (kBtu/sf) 0.0 2009 Wood (kBtu/sf) 0.0 2009 Thermal (kBtu/sf) 0.0 2009 Steam (kBtu/sf) 0.0 2009 Energy Utilization Index (kBtu/sf)87.8 Annual Energy Cost Index (ECI) 2009 Natural Gas Cost Index ($/sf)0.00 2009 Electric Cost Index ($/sf)2.33 2009 Oil Cost Index ($/sf)2.93 2009 Propane Cost Index ($/sf)0.00 2009 Coal Cost Index ($/sf)0.00 2009 Wood Cost Index ($/sf)0.00 2009 Thermal Cost Index ($/sf)0.00 2009 Steam Cost Index ($/sf)0.00 2009 Energy Cost Index ($/sf)5.25 2010 Natural Gas Consumption (Therms)0.00 2010 Natural Gas Cost ($)0 2010 Electric Consumption (kWh)145,116 2010 Electric Cost ($)73,911 2010 Oil Consumption (Therms)20,375.15 2010 Oil Cost ($)83,956 2010 Propane Consumption (Therms)0.00 2010 Propane Cost ($)0 2010 Coal Consumption (Therms)0.00 2010 Coal Cost ($)0 2010 Wood Consumption (Therms)0.00 2010 Wood Cost ($)0 2010 Thermal Consumption (Therms)0.00 2010 Thermal Cost ($)0 2010 Steam Consumption (Therms)0.00 2010 Steam Cost ($)0 2010 Total Energy Use (kBtu)2,532,795 2010 Total Energy Cost ($)157,866 Annual Energy Use Intensity (EUI) 2010 Natural Gas (kBtu/sf)0.0 2010 Electricity (kBtu/sf)17.3 2010 Oil (kBtu/sf)71.0 2010 Propane (kBtu/sf)0.0 2010 Coal (kBtu/sf)0.0 2010 Wood (kBtu/sf)0.0 2010 Thermal (kBtu/sf)0.0 2010 Steam (kBtu/sf)0.0 2010 Energy Utilization Index (kBtu/sf)88.3 Annual Energy Cost Index (ECI) 2010 Natural Gas Cost Index ($/sf)0.00 2010 Electric Cost Index ($/sf)2.58 2010 Oil Cost Index ($/sf)2.93 2010 Propane Cost Index ($/sf)0.00 2010 Coal Cost Index ($/sf)0.00 2010 Wood Cost Index ($/sf)0.00 2010 Thermal Cost Index ($/sf)0.00 2010 Steam Cost Index ($/sf)0.00 2010 Energy Cost Index ($/sf)5.50 Note: 1 kWh = 3,413 Btu's 1 Therm = 100,000 Btu's 1 CF ≈ 1,000 Btu's Newhalen K-12ElectricityBtus/kWh =3,413Provider Customer # Month Start Date End Date Billing Days Consumption (kWh) Consumption (Therms) Demand Use Electric Cost ($) Unit Cost ($/kWh) Demand Cost ($)NEA Jul‐08 7/1/2008 7/31/2008319057309$3,996$0.44NEAAug‐08 8/1/2008 8/31/2008313617123$4,230$1.17NEASep‐08 9/1/2008 9/30/20083013973477$5,373$0.38NEAOct‐08 10/1/2008 10/31/20083112746435$5,767$0.45NEANov‐08 11/1/2008 11/30/20083016996580$6,856$0.40NEADec‐08 12/1/2008 12/31/20083112887440$5,256$0.41NEAJan‐09 1/1/2009 1/31/20093111045377$5,344$0.48NEAFeb‐09 2/1/2009 2/28/20092814557497$6,804$0.47NEAMar‐09 3/1/2009 3/31/20093117210587$7,879$0.46NEAApr‐09 4/1/2009 4/30/20093014736503$6,834$0.46NEAMay‐09 5/1/2009 5/31/2009319529325$5,425$0.57NEAJun‐09 6/1/2009 6/30/2009304955169$2,965$0.60NEAJul‐09 7/1/2009 7/31/2009313773129$2,267$0.60NEAAug‐09 8/1/2009 8/31/2009318423287$4,695$0.56NEASep‐09 9/1/2009 9/30/20093012056411$6,397$0.53NEAOct‐09 10/1/2009 10/31/20093111266385$6,328$0.56NEANov‐09 11/1/2009 11/30/20093015446527$7,903$0.51NEADec‐09 12/1/2009 12/31/20093115168518$7,465$0.49NEAJan‐10 1/1/2010 1/31/20103115105516$7,392$0.49NEAFeb‐10 2/1/2010 2/28/20102818570634$8,819$0.47NEAMar‐10 3/1/2010 3/31/20103115081515$7,364$0.49NEAApr‐10 4/1/2010 4/30/20103015538530$7,515$0.48NEAMay‐10 5/1/2010 5/31/20103112210417$6,219$0.51NEAJun‐10 6/1/2010 6/30/201030247985$1,546$0.62Jul ‐ 08 to Jun ‐ 09 total:141,3084,8230$66,729$0Jul ‐ 09 to Jun ‐ 10 total:145,1164,9530$73,911$0$0.47$0.51Jul ‐ 09 to Jun ‐ 10 avg:Jul ‐ 08 to Jun ‐ 09 avg: $0$1,000$2,000$3,000$4,000$5,000$6,000$7,000$8,000$9,000$10,00002000400060008000100001200014000160001800020000Electric Cost ($)Electric Consumption (kWh)Date (Mon ‐Yr)Newhalen K‐12 ‐Electric Consumption (kWh) vs. Electric Cost ($)Electric Consumption (kWh)Electric Cost ($) Newhalen K-12OilBtus/Gal =132,000Provider Customer # Month Start Date End Date Billing Days Consumption (Gal) Consumption (Therms) Demand Use Oil Cost ($) Unit Cost ($/Therm) Demand Cost ($)Jan‐09 1/1/2009 1/31/20093115,43620,375$83,9564.12Feb‐09 2/1/2009 2/28/20093100$00.00Mar‐09 3/1/2009 3/31/20093000$00.00Apr‐09 4/1/2009 4/30/20093100$00.00May‐09 5/1/2009 5/31/20093000$00.00Jun‐09 6/1/2009 6/30/20093100$00.00Jul‐09 7/1/2009 7/31/20093100$00.00Aug‐09 8/1/2009 8/31/20092800$00.00Sep‐09 9/1/2009 9/30/20093100$00.00Oct‐09 10/1/2009 10/31/20093000$00.00Nov‐09 11/1/2009 11/30/20093100$00.00Dec‐09 12/1/2009 12/31/20093000$00.00Jan‐10 1/1/2010 1/31/20103115,43620,375$83,9564.12Feb‐10 2/1/2010 2/28/20103100$00.00Mar‐10 3/1/2010 3/31/20103000$00.00Apr‐10 4/1/2010 4/30/20103100$00.00May‐10 5/1/2010 5/31/20103000$00.00Jun‐10 6/1/20106/30/20103100$00.00Jul‐10 7/1/20107/31/20103100$00.00Aug‐10 8/1/20108/31/20102800$00.00Sep‐10 9/1/20109/30/20103100$00.00Oct‐10 10/1/201010/31/20103000$00.00Nov‐10 11/1/201011/30/20103100$00.00Dec‐10 12/1/201012/31/20103000$00.00Jul ‐ 08 to Jun ‐ 09 total:15,43620,3750$83,956$0Jul ‐ 09 to Jun ‐ 10 total:15,43620,3750$83,956$04.124.12Jul ‐ 08 to Jun ‐ 09 avg:Jul ‐ 09 to Jun ‐ 10 avg: $0.00$10,000.00$20,000.00$30,000.00$40,000.00$50,000.00$60,000.00$70,000.00$80,000.00$90,000.0005,00010,00015,00020,00025,000Oil Cost ($)Oil Consumption (Therms)Date (Mon ‐Yr)Newhalen K‐12 ‐Oil Consumption (Therms) vs. Oil Cost ($)Oil Consumption (Therms)Oil Cost ($) CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX B Appendix B AkWarm Short Report Energy Audit – Energy Analysis and Cost Comparison AkWarm Commercial Audit Software NEWHALEN SCHOOL Page 1 APPENDIX B ENERGY AUDIT REPORT – PROJECT SUMMARY – Created 6/28/2012 11:22 AM General Project Information PROJECT INFORMATION AUDITOR INFORMATION Building: Newhalen K-12 Auditor Company: Central Alaska Engineering Co. Address: 900 School Road Auditor Name: Jerry P. Herring, PE, CEA City: Newhalen Auditor Address: 32215 Lakefront Dr Soldotna, AK 99669 Client Name: Tim McDermott Client Address: P.O. Box 498 King Salmon, AK 99613 Auditor Phone: (907) 260-5311 Auditor FAX: ( ) - Client Phone: (907) 246-4280 Auditor Comment: Client FAX: ( ) - Design Data Building Area: 28,692 square feet Design Heating Load: Design Loss at Space: 760,803 Btu/hour with Distribution Losses: 800,845 Btu/hour Plant Input Rating assuming 82.0% Plant Efficiency and 25% Safety Margin: 1,220,800 Btu/hour Note: Additional Capacity should be added for DHW load, if served. Typical Occupancy: 40 people Design Indoor Temperature: 70 deg F (building average) Actual City: Newhalen Design Outdoor Temperature: -19.1 deg F Weather/Fuel City: Newhalen Heating Degree Days: 11,130 deg F-days Utility Information Electric Utility: I-N-N Electric Cooperative, Inc - Commercial - Lg Fuel Oil Provider: Local Provider Average Annual Cost/kWh: $0.490/kWh Average Annual Cost/Gal: $5.44/Gal Annual Energy Cost Estimate Description Space Heating Space Cooling Water Heating Lighting Refriger ation Other Electric al Cooking Clothes Drying Ventilatio n Fans Service Fees Total Cost Existing Building $111,35 5 $0 $14,149 $17,539 $4,552 $1,171 $0 $0 $6,218 $0 $154,985 With Proposed Retrofits $96,992 $0 $7,315 $15,467 $4,132 $1,171 $0 $0 $5,437 $0 $130,514 SAVINGS $14,363 $0 $6,835 $2,072 $420 $0 $0 $0 $781 $0 $24,471 Energy Audit – Energy Analysis and Cost Comparison AkWarm Commercial Audit Software NEWHALEN SCHOOL Page 2 APPENDIX B $0 $50,000 $100,000 $150,000 $200,000 Existing Retrofit Ventilation and Fans Space Heating Refrigeration Other Electrical Lighting Domestic Hot Water Annual Energy Costs by End Use Energy Audit – Energy Analysis and Cost Comparison AkWarm Commercial Audit Software NEWHALEN SCHOOL Page 3 APPENDIX B PRIORITY LIST – RECOMMENDED ENERGY EFFICIENCY MEASURES Ran k Feature Recommendation Annual Energy Savings Installed Cost SIR Payback (Years) 1 Refrigeration - Controls Retrofit: Vending Machine Add new Seasonal Shutdown $420 $900 8.97 2.1 2 Setback Thermostat: Gym Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Gym space. $1,856 $16,757 1.48 9 3 Setback Thermostat: Main floor Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Main floor space. $4,134 $40,495 1.36 9.8 4 Setback Thermostat: 2nd floor Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the 2nd floor space. $4,500 $45,011 1.34 10 5 HVAC And DHW Install new DDC system to reduce operating schedules of heating systems [$155,124]. Place timer on DHW circ pump [$3,000]. $8,489 + $2,000 Maint. Savings $188,124 1.06 22.2 6 Ventilation Install new DDC system to reduce operating schedule of heating systems [$155,124]. $3,000 + $3,000 Maint. Savings $125,124 1.00 41.7 7 Lighting - Combined Retrofit: Gym Replace with 26 FLUOR (2) T5 45.2" F28T5 28W High Lumen (3050 L) HighEfficElectronic and Add new Occupancy Sensor, Multi-Level Switch $544 + $4,480 Maint. Savings $60,000 1.00 110.3 8 Lighting - Combined Retrofit: HPS Replace with 9 LED 25W Module StdElectronic and Add new Occupancy Sensor and Improve Manual Switching $735 + $1,440 Maint. Savings $30,000 0.86 40.8 Energy Audit – Energy Analysis and Cost Comparison AkWarm Commercial Audit Software NEWHALEN SCHOOL Page 4 APPENDIX B PRIORITY LIST – RECOMMENDED ENERGY EFFICIENCY MEASURES Ran k Feature Recommendation Annual Energy Savings Installed Cost SIR Payback (Years) 9 Lighting - Combined Retrofit: 2 bulb T12 Replace with 18 FLUOR (2) T8 4' F32T8 25W Energy-Saver Program HighEfficElectronic and Add new Occupancy Sensor $793 + $288 Maint. Savings $17,000 0.75 21.4 TOTAL $24,471 + $11,208 Maint. Savings $523,411 1.09 21.4 ENERGY AUDIT REPORT – ENERGY EFFICIENT RECOMMENDATIONS 1. Building Envelope Insulation Rank Location Existing Type/R-Value Recommendation Type/R- Value Installed Cost Annual Energy Savings Exterior Doors – Replacement Rank Location Size/Type/Condition Recommendation Installed Cost Annual Energy Savings Windows and Glass Doors – Replacement Rank Location Size/Type/Condition Recommendation Installed Cost Annual Energy Savings Air Leakage Rank Location Estimated Air Leakage Recommended Air Leakage Target Installed Cost Annual Energy Savings 2. Mechanical Equipment Mechanical Rank Recommendation Installed Cost Annual Energy Savings 5 Install new DDC system to reduce operating schedules of heating systems [$155,124]. Place timer on DHW circ pump [$3,000]. $188,124 $8,489 + $2,000 Maint. Savings Setback Thermostat Energy Audit – Energy Analysis and Cost Comparison AkWarm Commercial Audit Software NEWHALEN SCHOOL Page 5 APPENDIX B Rank Location Size/Type/Condition Recommendation Installed Cost Annual Energy Savings 2 Gym Existing Unoccupied Heating Setpoint: 65.0 deg F Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Gym space. $16,757 $1,856 3 Main floor Existing Unoccupied Heating Setpoint: 65.0 deg F Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the Main floor space. $40,495 $4,134 4 2nd floor Existing Unoccupied Heating Setpoint: 65.0 deg F Implement a Heating Temperature Unoccupied Setback to 60.0 deg F for the 2nd floor space. $45,011 $4,500 Ventilation Rank Recommendation Cost Annual Energy Savings 6 Install new DDC system to reduce operating schedule of heating systems [$155,124]. $125,124 $3,000 + $3,000 Maint. Savings 3. Appliances and Lighting Lighting Fixtures and Controls Rank Location Existing Recommended Installed Cost Annual Energy Savings 7 Gym 26 FLUOR (2) T8 4' F32T8 32W Standard Instant StdElectronic with Manual Switching Replace with 26 FLUOR (2) T5 45.2" F28T5 28W High Lumen (3050 L) HighEfficElectronic and Add new Occupancy Sensor, Multi-Level Switch $60,000 $544 + $4,480 Maint. Savings 8 HPS 9 HPS 70 Watt StdElectronic with Manual Switching Replace with 9 LED 25W Module StdElectronic and Add new Occupancy Sensor and Improve Manual Switching $30,000 $735 + $1,440 Maint. Savings Energy Audit – Energy Analysis and Cost Comparison AkWarm Commercial Audit Software NEWHALEN SCHOOL Page 6 APPENDIX B 9 2 bulb T12 18 FLUOR (2) T12 4' F40T12 40W Standard Magnetic with Manual Switching Replace with 18 FLUOR (2) T8 4' F32T8 25W Energy-Saver Program HighEfficElectronic and Add new Occupancy Sensor $17,000 $793 + $288 Maint. Savings Refrigeration Rank Location Existing Recommended Installed Cost Annual Energy Savings 1 Vending Machine Vending Machine Add new Seasonal Shutdown $900 $420 Other Electrical Equipment Rank Location Existing Recommended Installed Cost Annual Energy Savings Cooking/Clothes Drying Rank Recommended Installed Cost Annual Energy Savings ------------------------------------------ AkWarmCalc Ver 2.2.0.3, Energy Lib 5/18/2012 CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL K‐12 ENERGY AUDIT REPORT APPENDIX C Appendix C Major Equipment List CENTRAL ALASKA ENGINEERING COMPANYNEWHALEN SCHOOL ENERGY AUDIT REPORTTAG LOCATIONFUNCTIONMAKEMODELTYPECAPACITY EFFICIENCY MOTOR SIZEASHRAE SERVICE LIFEESTIMATED REMAINING USEFUL LIFENOTESB-1 BOILER RM BUILDING HEAT BURNHAM V-904A OIL/CAST IRON 4.2 GPH OIL 82% - 35 30B-2 BOILER RM BUILDING HEAT BURNHAM V-904A OIL/CAST IRON 4.2 GPH OIL 82% - 35 30B-3 BOILER RM BUILDING HEAT BURNHAM V-904A OIL/CAST IRON 4.2 GPH OIL 82% - 35 30B-4 BOILER RM BUILDING HEAT FULTON ICW-015-W ELECTRIC 150 kW 95% - 15 4WH-1 GYM FAN RM DHW SUPPLY A.O. SMITH EES 120 913 ELECTRIC SOTRAGE 4500 W 80% - 24 13 119 GALLONSCOMP-1 GYM MECH RM CONTROL AIR QUINCY N/A RECIPROCATING N/A 86.5% 3.0 HP 20 6COMP-2 GYM MECH RM CONTROL AIR QUINCY N/A RECIPROCATING N/A 70.0% 0.33 HP 20 6CP-1 BOILER RM BUILDING HEAT GRUNDFOS UPC 80-160 INLINE EST 225 GPM EST 82% 900-2400 W 10 5CP-2 BOILER RM BUILDING HEAT GRUNDFOS UPS 50-160 F INLINE EST 125 GPM EST 82% 950-1300 W 10 5CP-3 BOILER RM BUILDING HEAT GRUNDFOS UPS 50-40 F INLINE EST 25 GPM EST 82% 210-280 W 10 5CP-4 KITCHEN MECH BUILDING HEAT GRUNDFOS UMC 50-80 INLINE EST 50 GPM EST 82% 340-520 W 10 5CP-5 KITCHEN MECH BUILDING HEAT GRUNDFOS UMC 65-80 INLINE EST 75 GPM EST 82% 300-810 W 10 5EF-1 RESTROOMS EA N/A N/A CENTRIFUGAL EST 80 CFM NEMA EST 50 W 20 15 INFO FROM DRAWINGSEF-2 FAN CHASE EA PACE SCF-57A CENTRIFUGAL EST 450 CFM NEMA 0.25 HP 20 15 INFO FROM DRAWINGSEF-3 FAN CHASE EA PENN ZC-10 AXIAL EST 560 CFM NEMA 0.25 HP 20 15 INFO FROM DRAWINGSEF-4 KITCHEN EA PENN FUMEX FMX 13B AXIAL 1154 CFM @ 1.0" NEMA 0.5 HP 20 15 INFO FROM DRAWINGSAHU-1 GYM FAN RM GYM SA FLEXAIRE SDF20-02FI AXIAL 3680 CFM NEMA 3 HP 20 15AHU-2 GYM FAN RM SCHOOL SA FLEXAIRE SDF20-02FI AXIAL 3680 CFM NEMA 3 HP 20 15AHU-3 KITCHEN MECH SA TRANE 3A AXIAL 1080 CFM @ 1.5" NEMA 0.75 HP 20 15 INFO FROM DRAWINGSAHU-4 FAN CHASE SA PACE N/A CENTRIFUGAL EST 6,000 CFM 85.5% 3 HP 20 15 INFO FROM DRAWINGSAHU-5 FAN CHASE SA TRANE N/A CENTRIFUGAL EST 1,500 CFM EST 85.0% 0.75 HP 20 15 INFO FROM DRAWINGSMAJOR EQUIPMENT INVENTORYAPPENDIX C CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX D Appendix D Site Visit Photos CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX D 1. View of the main entrance of the school. 2. View of the south side of the school. 3. View of the east of the school. 4. View of the north side of the school. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX D 5. View of the school gym lighting. 6. View of the classroom lighting 7. View of the library lighting. 8. View of the bathroom lighting. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX D 9. View of the DW fuel oil tank in place. 10. Overall view of the boilers. 11. Close-up of boiler 1. 12. Close-up of electric boiler. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX D 13. Heated water circulation pumps. 14. Electric hot water maker. 15. Air handler AHU-5 in ventilation chase of school. 16. Air handlers AHU-1 & AHU-2. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX D 17. DDC system 18. Kitchen range hood. 19. Storage room unit heater. 20. Individual meters for separate school components. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E Appendix E Thermal Site Visit Photos CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 1. Restroom addition. Heat loss exhibited through the wall. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 2. Close-up view of the northwest entrance. Heat loss exhibited from the doorway. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 3. Overall view of the west side of the school. (A) Heat loss exhibited from the wall. (B) Expected heat loss from air handler. B A CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 4. Western entrance of the school. Heat loss exhibited from the wall. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 5. South side of the school. Heat loss exhibited from (A) foundation insulation (B) school doorway. B A B CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 6. East side of the school. Heat loss exhibited from (A) foundation insulation (B) school window. A B CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 7. Northeast entrance of the school. Heat loss exhibited from the doorway. CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 8. East side of the gymnasium. Heat loss exhibited from (A) the wall (B) school doorway. A B CENTRAL ALASKA ENGINEERING COMPANY NEWHALEN SCHOOL ENERGY AUDIT REPORT APPENDIX E 9. Overall view of the north side of the school. Heat loss exhibited from the wall.