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_____________________________________________________________________________ New Jersey BPU LGEA – William Paterson University - ATRIUM

WILLIAM PATERSON UNIVERSITY

ATRIUM BUILDING 300 Pompton Road, Wayne NJ 07470

LOCAL GOVERNMENT ENERGY AUDIT PROGRAM FOR

NEW JERSEY BOARD OF PUBLIC UTILITIES

July 2014

Prepared by:

6 Campus Drive Parsippany, NJ 07054

(973) 538-2120

CHA PROJECT NO. 28661


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TABLE OF CONTENTS

EXECUTIVE SUMMARY .................................................................................................... 1 1.0

BUILDING INFORMATION AND EXISTING CONDITIONS ................................................ 4 2.0

UTILITIES ........................................................................................................................... 7 3.0

BENCHMARKING ..............................................................................................................10 4.0

ENERGY CONSERVATION MEASURES ..........................................................................11 5.0

5.1 ECM-1 Replace Door Sweeps and Seals ...................................................................................... 12

5.2 ECM-2 Install De-stratification Fans ............................................................................................ 12

5.3 ECM-3 Replace Old RTUs with New RTUs ................................................................................... 13

5.4 ECM-4 Re-Activate the Dual Temp Pump Motor VFDs ............................................................... 13

5.5 ECM-5 Install VFDs on the Auditorium Air Handling Unit ........................................................... 14

5.6 ECM-6 Install Occupancy Sensors/DDC to Control Individual Fan Coil Units ............................. 15

5.7 ECM-7 Install Vending Misers ..................................................................................................... 15

5.8 ECM-8 Install Low Flow Plumbing Fixtures ................................................................................. 16

5.9.1 ECM-L1 Lighting Replacement / Upgrades ................................................................................. 16

5.9.2 ECM-L2 Install Lighting Controls (Occupancy Sensors) .............................................................. 17

5.9.3 ECM-L3 Lighting Replacements with Controls (Occupancy Sensors) ......................................... 17

5.10 Additional O&M Opportunities ................................................................................................... 18

PROJECT INCENTIVES ....................................................................................................19 6.0

6.1 Incentives Overview .................................................................................................................... 19

6.1.1 New Jersey Smart Start Program ................................................................................................ 19

6.1.2 Direct Install Program ................................................................................................................. 19

6.1.3 New Jersey Pay For Performance Program (P4P) ....................................................................... 20

6.1.4 Energy Savings Improvement Plan ............................................................................................. 21

6.1.5 Renewable Energy Incentive Program ........................................................................................ 22

ALTERNATIVE ENERGY SCREENING EVALUATION .....................................................23 7.0

7.1 Solar ............................................................................................................................................ 23

7.1.1 Photovoltaic Rooftop Solar Power Generation .......................................................................... 23

7.1.2 Solar Thermal Hot Water Generation......................................................................................... 23

7.2 Wind Powered Turbines ............................................................................................................. 23


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7.3 Combined Heat and Power Plant and Fuel Cell System .............................................................. 24

7.4 Demand Response Curtailment .................................................................................................. 25

CONCLUSIONS & RECOMMENDATIONS ........................................................................26 8.0

APPENDICES A Utility Usage Analysis and List of Third Party Energy Suppliers

B Equipment Inventory C ECM Calculations and Cost Estimates D New Jersey BPU Incentive Programs i. Smart Start ii. Direct Install iii. Pay For Performance Incentive Program (P4P) iv. Energy Savings Improvement Plan (ESIP) E Photovoltaic (PV) Solar Power Generation Analysis F Photos G EPA Benchmarking Report


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REPORT DISCLAIMER

This audit was conducted in accordance with the standards developed by the American Society of Heating, Refrigerating, and Air-Conditioning Engineers (ASHRAE) for a Level II audit. Cost and savings calculations for a given measure were estimated to within ±20%, and are based on data obtained from the owner, data obtained during site observations, professional experience, historical data, and standard engineering practice. Cost data does not include soft costs such as engineering fees, legal fees, project management fees, financing, etc. A thorough walkthrough of the building was performed, which included gathering nameplate information and operating parameters for all accessible equipment and lighting systems. Unless otherwise stated, model, efficiency, and capacity information included in this report were collected directly from equipment nameplates and /or from documentation provided by the owner during the site visit. Typical operation and scheduling information was obtained from interviewing staff and spot measurements taken in the field.


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List of Common Energy Audit Abbreviations

• A/C – Air Conditioning • AHS – Air Handling Unit • BMS – Building Management System • Btu – British thermal unit • CDW – Condenser Water • CFM – Cubic feet per minute • CHW – Chilled Water • DCV – Demand Control Ventilation • DDC – Direct Digital Control • DHW – Domestic Hot Water • DX – Direct Expansion • EER – Energy Efficiency Ratio • EF – Exhaust Fan • EUI – Energy Use Intensity • Gal – Gallon • GPD – Gallons per day • GPF – Gallons Per Flush • GPH – Gallons per hour • GPM – Gallons per minute • GPS – Gallons per second • HHW – Heating Hot Water • HID – High Intensity Discharge • HP – Horsepower • HRU – Heat Recovery Unit • HVAC – Heating, Ventilation, Air Conditioning • HX – Heat Exchanger • kbtu/mbtu – One thousand (1,000) Btu • kW – Kilowatt (1,000 watts) • kWh – Kilowatt-hours • LED – Light Emitting Diode • mbh – Thousand Btu per hour • mmbtu – One million (1,000,000) Btu • OCC – Occupancy Sensor • PSI – Pounds per square inch • RTU – Rooftop Unit • SBC – System Benefits Charge • SF – Square foot • UH – Unit Heater • V – Volts • VAV – Variable Air Volume • VSD – Variable Speed Drive • W – Watt

New Jersey BPU LGEA 1 | P a g e William Paterson University – ATRIUM

EXECUTIVE SUMMARY 1.0 This report summarizes the energy audit performed by CHA for William Patterson University (WPU) in connection with the New Jersey Board of Public Utilities (NJBPU) Local Government Energy Audit (LGEA) Program. The purpose of this report is to identify energy savings opportunities associated with major energy consumers and inefficient practices. Low-cost and no-cost are also identified during the study. This report details the results of the energy audit conducted for the building listed below:

Building Name Address Square Feet

Construction Date

Atrium 300 Pompton Road, Wayne NJ 07470 42,000 1996

The potential total annual energy and cost savings for the recommended energy conservation measures (ECM) identified in the survey are shown below:

Building Name Electric Savings (kWh)

NG Savings (therms)

Total Savings

($) Payback (years)

Atrium 256,430 3,050 43,216 10.0 Each individual measure’s annual savings are dependent on that measure alone, there are no interactive effects calculated. There are three options shown for Lighting ECM savings; only one option can be chosen. Incentives shown (if any) are based only on the SmartStart Incentive Program. Other NJBPU or local utility incentives may also be available/ applicable and are discussed in Section 6.0. Each measure recommended by CHA typically has a stand-alone simple payback period of 15 years or less. However, if the owner choses to pursue an Energy Savings Improvement Plan (ESIP), high payback measures could be bundled with lower payback measures which ultimately can result in a payback which is favorable for an ESIP project to proceed. Occasionally, we will recommend an ECM that has a longer payback period, based on the need to replace that piece(s) of equipment due to its age, such as a boiler for example.


The following table provides a detailed summary of each ECM for the building surveyed, including costs, savings, SmartStart incentives and payback.

Summary of Energy Conservation Measures

ECM

#

Energy Conservation Measure

Est. Costs

($)

Est. Savings ($/year)

Payback w/o

Incentive

Potential Incentive

($)*

Payback w/

Incentive

Rec

omm

ende

d

ECM-1 Install Door Seals 230 50 4.6 0 4.6 Y

ECM-2

Install Destratification Fans 19,900 1,150 17.3 0 17.3 Y

ECM-3

Replace the Two Old RTUs with New RTUs 94,327 7,763 12.2 2,600 11.8 Y

ECM-4

Re-Activate the Dual Temp Pump Motor

VFDs 30,390 10,276 3.0 0 3.0 Y

ECM-5

Install VFDs on the Auditorium Air Handling Unit 26,879 4,158 6.5 3,000 5.7 Y

ECM-6

Install Occupancy Sensors to Control Individual Fan Coil

Units 92,889 5,983 15.5 0 15.5 Y ECM-

7 Install Vending Misers 560 1,391 0.4 0 0.4 Y

ECM-8

Replace High Flow Plumbing Fixtures with

Low Flow Plumbing Fixtures 74,137 1,199 61.9 0 61.9 Y

ECM-L1**

Lighting Replacements / Upgrades 76,857 10,683 7.2 1,890 7.0 N

ECM-L2**

Install Lighting Controls (Add

Occupancy Sensors) 16,740 1,285 13.0 2,170 11.3 N

ECM-L3

Lighting Replacements with Controls

(Occupancy Sensors) 93,597 11,246 8.3 4,060 8.0 Y Total** 432,909 43,216 10.0 9,660 9.8 Total(Recommended) 432,909 43,216 10.0 9,660 9.8

* Incentive shown is per the New Jersey SmartStart Program. ** These ECMs are not included in the Total, as they are alternate measures not recommended.


If WPU implements the recommended ECMs, energy savings would be as follows:

Existing

Conditions

Post Recommended

ECMs Percent Savings

Costs ($) 140,485 97,269 31% Electricity (kWh) 838,400 581,970 31% Natural Gas (therms) 13,455 10,405 23% Site EUI (kbtu/SF/Yr) 100.1 72.1

Existing Conditions Post RecommnededECMs

0

100,000

200,000

300,000

400,000

500,000

600,000

700,000

800,000

900,000

Costs ($)

Electricity (kWh)

Natural Gas (therms)


BUILDING INFORMATION AND EXISTING CONDITIONS 2.0

The following is a summary of building information related to HVAC, plumbing, building envelope, lighting, kitchen equipment and domestic hot water systems as observed during CHAs site visit. See appendix B for detailed information on mechanical equipment, including capacities, model numbers and age. See appendix F for some representative photos of some of the existing conditions observed while onsite. Building Name: Atrium Address: 300 Pompton Road, Wayne NJ 07470 Gross Floor Area: 42,000 Number of Floors: 2 Year Built: 1996

Building Envelope

Description of Spaces: This is an academic and office building which has office rooms, classrooms, auditorium, computer labs and restrooms. Description of Occupancy: The facility serves about 100 college students. There are about 80 school faculty and staff members Number of Computers: The building has approximately 200 desktop and laptop computers. Building Usage: Operates approximately 51 weeks per year and typical operating hours are from 7:00AM to 5:00PM. Construction Materials: Structural steel, brick and concrete block. Façade: Brick. Roof: The roof consists of a pitched translucent plastic roof and a flat roof. The pitched translucent roof appears to be in good condition. The flat roof is covered with grey rubber membrane. It is believed that the roof is well insulated. The roof is in good condition and no ECMs associated with roof replacement.


Windows: The windows throughout the building are double pane aluminum framed windows. Windows are in good condition and no ECMs associated with window replacement were evaluated. Exterior Doors: Exterior doors throughout the school are Alumina frame with double pane safety glass. Sweeps on exterior doors are still in good condition except one side door. An ECM relative to replacing the seals on the side door is recommended. Heating Ventilation & Air Conditioning (HVAC) Systems Heating: Two Aerco Benchmark 2.0 high efficiency condensing boilers are used to provide heating hot water for the heating coils in the AHUs, fan coil (FC) units and cabinet heaters. The boilers have a rated 2,000 MBH input with efficiency ranging from 87% to 96% depending on the return water temperature. The building has a two-pipe system, therefore the boilers provide the hot water for the two-pipe system during the heating season and the control valve switches it to chilled water loop during the cooling system. Two water circulation loops are utilized in the building: one is circulated by two pumps driven by two 25HP premium efficiency motors and the other is circulated by two 10HP pumps. The classrooms, computer labs, hallways and offices have fan coil units with the HHW/CHW coils in them. The auditorium is heated and cooled by a Carrier AHU located in the mechanical room. The AHU has two 1HP inline pumps to booster the pressure for the HHW/CHW coils in them. Cooling: Two 80 ton Carrier roof mounted air cooled chillers provide the chilled water for the CHW coils in the AHUs and fan coil units. The chilled water share the same pumps with the HHW loop in the two-pipe system. Apart from the central chilled water system, there are two RTUs equipped with DX cooling system used to provide cooling for the hallways. These two Carrier RTUs have rated cooling capacity of 25 ton and EER of 8.7. During the site visit, it was observed that one of the RTUs was out of order. The auditorium is cooled by a designated Carrier AHU mentioned in the heating section. ECMs relative to installing VFDs on the HHW/CHW piping system/AHU, installing de-stratification fans and replacing the RTUs are recommended in this report. Ventilation: Each of the two RTUs has air intake to provide fresh air for the hallways. Similarly, the Carrier AHU located in the mechanical room has air intake to provide ventilation for the auditorium. Each fan coil unit also has an opening to the outdoor and ventilates the classrooms, offices and computer labs. An ECM relative operating the AHU/RTU in economizer mode has been included to reduce the HVAC cost. Exhaust: This building has multiple fractional HP exhaust fans serving restrooms and general exhaust all located on the roof. The fans are enclosed and therefore the capacities of fan motors are unknown. No ECMs were evaluated for the exhaust fans. Controls Systems The school has two central direct digital control (DDC) systems: the older Schneider Andover Continuum system and newer Automated Logic Control (ALC) system. The Atrium HVAC devices are currently controlled by the Andover system. Each room has its own thermostat to control the room temperature and setback the temperature during unoccupied hours. Reviewing


of the control screens, it was noted that the space temperature is typically set at 72 oF. The system has a temperature setback program; however, the temperature setback is only from 8PM to 12AM. An ECM associated with extending the temperature setback time range and including the fan coil units to DDC has been included. Domestic Hot Water Systems The Atrium has an electric DHW heater located in the janitor closet. The heater has a rated 2kW and 30 gallon storage capacity. The closet does not have gas piping assess and not easy space to vent the flue gas. Therefore, it is not practical to replace the electric heater with gas heater and no ECM is associated with DHW system. Kitchen Equipment There is no kitchen in the Atrium building. Plug Load This building has computers, LCD monitors copiers, residential appliances (microwave, refrigerator), printers, and vending machines which contribute to the plug load in the building. The installation of vending machine occupancy sensors has been evaluated in an effort to reduce the plug load in the building. Plumbing Systems The restrooms contain older style toilets and urinals that utilize a higher volume of water per flush (3.5 GPF) than currently available new units. The sink faucets are double handle type and do not appear to have low-flow type aerators, dispensing at 2.5 GPM. An ECM is included to evaluate the water savings potential of installing low- flow plumbing fixtures. Lighting Systems The building has a mixture of 32W T-8 fluorescent lighting, a few CFLs and some LED spot lights. The majority of lighting fixtures are T-8 fluorescent U-shape and linear fixtures. The Atrium area has LED spot lights and the lobby areas have CFL lights. All of the lights in this building are controlled by manual switches. The exterior lights are wall mounted induction lights fixtures. We have provided three alternatives for lighting that include adding occupancy sensors to the existing lights, replacing the lights with LED lights and a third ECM that evaluates adding occupancy sensors to the proposed LED lights.


UTILITIES 3.0 Natural gas and electricity are metered into this building under Account # 42-004-710-00. Utilities used by the building are delivered and supplied by the following utility companies:

Electric Natural Gas Deliverer PSE&G PSE&G Supplier Direct Energy HESS

For the 12-month period ending in January 2014, the utilities usages and costs for the building were as follows:

Electric Annual Consumption 838,400 kWh Annual Cost 125,339 $ Blended Unit Rate 0.149 $/kWh Supply Rate 0.122 $/kWh Demand Rate 11.93 $/kW Peak Demand 160.0 kW

Natural Gas Annual Consumption 13,455 Therms Annual Cost 15,146 $ Unit Rate 1.126 $/therm

Blended Rate: Average rate charged determined by the annual cost / annual usage Supply Rate: Actual rate charged for electricity usage in kWh (based on most recent electric bill) Demand Rate: Rate charged for actual electrical demand in kW (based on most recent electric bill) *Some months that do not have utility data and the missing demand usage are estimated and highlighted in the utility spreadsheet

The electric usage fluctuates with the building usage. The usage is higher when the building is utilized more.

020406080100120140160180

010,00020,00030,00040,00050,00060,00070,00080,00090,000

100,000

Feb-

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Apr

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May

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Jun-

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Jul-1

3

Aug

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Sep

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Oct

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Nov

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Jan-

14

Dem

and

(kW

)

Usa

ge (k

Wh)

Month

Atrium Electric Usage (kWh) (kW)


The natural gas usage in this building is for heating only and therefore there is no usage in the summer months. The gas usage during the heating season is correlated to winter weather conditions. See Appendix A for utility analysis. Under New Jersey’s energy deregulation law, the supply portion of the electric (or natural gas) bill is separated from the delivery portion. The supply portion is open to competition, and customers can shop around for the best price for their energy suppliers. The electric and natural gas distribution utilities will still deliver the gas/ electric supplies through their wires and pipes – and respond to emergencies, should they arise – regardless of where those supplies are purchased. Purchasing the energy supplies from a company other than your electric or gas utility is purely an economic decision; it has no impact on the reliability or safety of the service.

Comparison of Utility Rates to NJ State Average Rates* Recommended to Shop for Third Party Supplier?

Utility Units School Average Rate NJ Average Rate

Electricity $/kWh $0.15 $0.13 Y Natural Gas $/Therm $1.13 $0.96 Y

* Per U.S. Energy Information Administration (2013 data – Electricity and Natural Gas, 2012 data – Fuel Oil) Additional information on selecting a third party energy supplier is available here: http://www.state.nj.us/bpu/commercial/shopping.html. See Appendix A for a list of third-party energy suppliers licensed by the Board of Public Utilities to sell within the building’s service area. The charts below represent estimated utility end-use utility profiles for the building. The values used within the charts were estimated from a review of the utility analysis and the energy savings calculations.

0.00

0.20

0.40

0.60

0.80

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1.20

1.40

1.60

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1,000

1,500

2,000

2,500

3,000

3,500

Feb-

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-13

Apr-

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-13

Jun-

13

Jul-1

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Aug-

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Oct

-13

Nov

-13

Dec-

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Jan-

14

Uni

t Cos

t ($/

Ther

m)

Cons

umpt

ion

(The

rms)

Atrium Gas Usage Consumption (Therms) Total ($/Therm)

http://www.state.nj.us/bpu/commercial/shopping.html


Site End-Use Utility Profile

Lighting 19%

Motors 12%

Cooling/Heating

36% Plug Load

12%

Computers 6%

Other 9%

Electricity Use (kWh):

Boilers 100%

Natural Gas End Use

Boilers


BENCHMARKING 4.0 The EPA Portfolio Manager benchmarking tool provides a site and source Energy Use Intensity (EUI), as well as an Energy Star performance rating for qualifying building types. The EUIs are provided in kBtu/ft2/year, and the performance rating represents how energy efficient a building is on a scale of 1 to 100, with 100 being the most efficient. In order for a building to receive and Energy Star label, the energy benchmark rating must be at least 75. As energy use decreases from implementation of the proposed measures, the Energy Star rating will increase. However, the EPA does not have score for all types of buildings. The buildings that do not have energy rating now are compared with national median EUI. The site EUI is the amount of heat and electricity consumed by a building as reflected in utility bills. Site energy may be delivered to a facility in the form of primary energy, which is raw fuel burned to create heat or electricity, such as natural gas or oil; or as secondary energy, which is the product created from a raw fuel such as electricity or district steam. To provide an equitable comparison for different buildings with varying proportions of primary and secondary energy consumption, Portfolio Manager uses the convention of source EUIs. The source energy also accounts for losses incurred in production, storage, transmission, and delivery of energy to the site, which provide an equivalent measure for various types of buildings with differing energy sources. The results of the benchmarking are contained in the table below.

Site EUI kBtu/ft2/yr Source EUI (kBtu/ft2/yr)

Energy Star Rating (1-100)

100.1 247.5 N/A The building has lower EUIs than the national median EUIs (national median site EUI is 106.3 kBtu/ft2 and national median source EUI is 262.6 kBtu/ft2), and is considered an energy efficient building.


ENERGY CONSERVATION MEASURES 5.0 The following types of energy savings opportunities are identified in this section of the report:

• Energy conservation measures (ECMs) are energy savings recommendations

that typically require a financial investment. For these areas of opportunity, CHA prepared detailed calculations, as summarized in this section and in Appendix C. In general, additional savings may exist from reductions in maintenance activities associated with new equipment or better controls; however for conservatism, maintenance savings are not accounted for in this report; instead the only savings which are reported are those derived directly from reductions in energy which can be tracked by the utility bills.

• Operational and Maintenance measures (O&M) consist of low- or no-cost

operational opportunities, which if implemented would have positive impacts on overall building operation, comfort levels, and/or energy usage. There are no estimated savings, costs or paybacks associated with the O&M measures included as part of this study.

Energy savings were quantified in the form of:

• electrical usage (kWh=Kilowatt-hour), • electrical demand (kW=kilowatts), • natural gas (therms=100,000 Btu), • propane gas (gallons=91,650 Btu), • fuel oil (gallons =138,700 Btu), and • water (kgal=1,000 gallons).

These recommendations are influenced by the time period that it takes for a proposed project to “break even” referred to as “Simple Payback”. Simple payback is calculated by dividing the estimated cost of implementing the ECM by the energy cost savings (in dollars) of that ECM. Another financial indicator of the performance of a particular ECM is the Return on Investment or ROI, which represents the benefit (annual savings over the life of a project) of an investment divided by the cost of the investment. The result is expressed as a percentage or ratio. Two other financial analyses included in this report are Internal Rate of Return (IRR) and Net Present Value (NPV). Internal Rate of Return is the discount rate at which the present value of a project costs equals the present value of the project savings. Net Present Value is the difference between present value of an investment’s future net cash flows and the initial investment. If the NPV equals “0”, the project would equate to investing the same amount of dollars at the desired rate. NPV is sometimes referred to as Net Present Worth. These values are provided in the Summary Tab in Appendix C.


5.1 ECM-1 Replace Door Sweeps and Seals

Exterior doors have door sweeps and seals which have deteriorated over time. Presently, gaps exist which allow for infiltration of outdoor air or exfiltration of indoor air, wasting heating and cooling energy. This measure calls for the replacement of all exterior door seals. Replacement of these seals will result in a reduction of the buildings heating and cooling loads, therefore providing natural gas and electricity savings. The linear footage of gap and wind speed is used to estimate the infiltration rate, which is then multiplied by the BIN weather data and the equipment efficiencies to determine the annual energy savings. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-1 Replace Door Sweeps and Seals

Budgetary Cost

Annual Utility Savings ROI Potential

Incentive*

Payback (without

incentive)

Payback (with

incentive) Electricity Natural Gas Total

$ kW kWh Therms $ $ Years Years

230 0 56 37 50 5.5 0 4.6 4.6 * Does not qualify for Incentive from the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities This measure is recommended.

5.2 ECM-2 Install De-stratification Fans

Large open areas allow for air to become stratified between the ceiling and floor; meaning that in the air at the ceiling is hotter than the air at the floor. During the winter time, de-stratification fans will mix the cold air from the floor with the warm air at the ceiling to create more even temperatures in the space. During the summer time, the fans will induce a downward which will add an additional cooling effect through convection. De-stratification fans may reduce energy consumption of the air handling system by creating a more even temperature gradient within a space. The Atrium area is a large open space covered by an about 35 feet translucent ceiling. It is suggested to install de-stratification fans in this area. By implementing this measure energy savings will be realized, however a more detailed study is recommended to quantify annual savings. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below:


ECM-2 Install De-stratification Fans

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



19,900 0 5,929 236 1,150 0.4 0 17.3 17.3 * Does not qualify for Incentive from the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities This measure is recommended.

5.3 ECM-3 Replace Old RTUs with New RTUs

The two HVAC roof top units (RTU) serving the common areas contain DX cooling and electric heating. Each RTU is mounted on an extended curb. Supply and return ductwork is routed down through the roof curbs to a duct distribution system above the ceilings to each space. The capacities are received from the manufacturer based on the nameplate model and serial number was 25-tons. These two units are 1996 and one of them was found to be out of service due to repairs during the site visit. It is recommended that the RTUs be replaced with RTUs equipped with high efficiency heat pump. This ECM assesses the replacement of each size of RTU and gives the resulting energy savings. The assumption of this calculation is that the operating hours, number of units, and capacity stays the same. The energy savings result from operating higher efficiency units than the existing. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-3 Replace Old RTUs with New RTUs

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



94,327 0 52,101 0 7,763 0.6 2,600 12.2 11.8 * Incentive shown is per the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities. This measure is recommended.

5.4 ECM-4 Re-Activate the Dual Temp Pump Motor VFDs

The building has a two-pipe system, therefore the boilers provide the hot water for the two-pipe system during the heating season and the chillers provide the chilled water for the same piping system. The control valve switches it to chilled water loop during the cooling system. Two water circulation loops are utilized in the building: one is circulated by two pumps driven by two 25HP premium efficiency motors and the other is circulated by two 10HP pumps. It was observed that VFDs were installed to control the pump speed, however, the VFDs are in bypass mode, therefore operating at constant speed. This measure looks at reactivating the VFDs and installing two-way valves/pressure transducers if needed to utilize the energy savings from the VFD pumps.


The savings of this measure are calculated from the motor speed reduction when the HHW/CHW system is only partially loaded. The load percentage of the pumps is calculated by estimating the percentage of two-way valves open in each temperature bin. Therefore, partial energy savings in each bin can be calculated as the difference between the energy drawn by the full-load old motors and the energy drawn by the VFD driven motors. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-4 Re-Activate the Dual Temp Pump Motor VFDs

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



30,390 0 68,970 0 10,276 5.8 0 3.0 3.0 * Does not qualify for Incentive from the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities This measure is recommended.

5.5 ECM-5 Install VFDs on the Auditorium Air Handling Unit

The existing supply and return air fans on the Carrier AHU serving the Auditorium are not controlled by variable frequency drives (VFDs). Typically fans within air handling units are perfectly selected to match the ventilation needs of a space functioning at maximum capacity. Often enough there are times during the day when the space is at less than full occupancy. VFDs allow fans to run at slower RPMs to better meet the needs of the system and in the process, energy is saved. Ideally fans or pump motors are perfectly selected to match the needs of a system operating a maximum capacity. Typically units are over-sized somewhat for safety and the system is operating at less than full heating capacity. VFDs allow motors to run at slower RPMs to better meet the needs of the system and in the process, energy is saved. To implement this ECM, the existing motors can be removed and new inverter duty motors and VFDs installed in their place. Piping and wiring modifications may also be needed. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-5 Install VFDs on the Auditorium Air Handling Unit

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



26,879 0 25,570 309 4,158 2.1 3,000 6.5 5.7 * Incentive shown is per the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities.


This measure is recommended.

5.6 ECM-6 Install Occupancy Sensors/DDC to Control Individual Fan Coil Units

Each classroom and office in this building has a fan coil (FC) unit which is currently controlled by a wall mounted thermostat. The temperature in each room is set to 72 oF regardless if the rooms are occupied or not. During the site visit, it was found that most of the offices and classrooms were not occupied. Occupancy sensors that control both the lights and FC units would help reduce the energy usage in the building. The occupancy sensors would be connected to the DDC system and set the rooms to unoccupied mode when the room is not occupied for 15 minutes and return to the occupied mode once they sense occupancy. To implement this ECM, occupancy sensors, thermostats and a DDC system would be installed and connected to operate the fan coil units and reset the room temperature during unoccupied hours. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-6 Install Occupancy Sensors/DDC to Control Individual Fan Coil Units

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



92,889 0 21,502 2,468 5,983 0.3 0 15.5 15.5 * Does not qualify for Incentive from the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities This measure is recommended.

5.7 ECM-7 Install Vending Misers

Cold drink and snack vending machines are typically operating 24/7 regardless of occupancy. A Vending miser uses a passive infrared occupancy sensor technology to detect potential customers and cycles the compressors during unoccupied times to maintain desired product temperatures. This measure considered installing vending misers to save energy on (1) refrigerated machines and (1) dry product machines in the cafeteria. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-7 Install Vending Misers

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



560 0 9,338 0 1,391 48.7 0 0.4 0.4


* Does not qualify for Incentive from the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities This measure is recommended.

5.8 ECM-8 Install Low Flow Plumbing Fixtures The plumbing fixtures in this building are older high flow fixtures. The water savings associated from replacing existing high flow fixtures with low-flow fixtures was calculated by taking the difference of the annual water usage for the proposed and base case. The basis of this calculation is the estimate usage of each fixture, gallons per use, and number of fixtures. Replacing the existing fixtures in the restrooms with 1.28 Gals/flush toilets, 1.0 gal/flush urinals, and 0.5 gpm faucets will conserve water which will result in lower annual water and sewer charges. Faucets with low-flow push valves were not considered for replacement. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-8 Install Low Flow Plumbing Fixtures

Budgetary Cost

Annual Utility Savings

ROI Potential Incentive*

Payback (without

incentive)

Payback (with

incentive) Electricity Natural Gas Water Total

$ kW kWh Therms kGal $ $ Years Years

74,137 0 1,675 0 127 1,199 (0.7) 0 61.9 61.9 * Does not qualify for Incentive from the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities This measure is recommended since the total payback including this measure is less than 15 years.

5.9.1 ECM-L1 Lighting Replacement / Upgrades The existing lighting system consists of mostly 32 watt T8 linear fluorescent fixtures which until recently represented the most efficient lighting technology available. Recent technological improvements in light emitting diode (LED) technologies have driven down the initial costs making it a viable option for installation. Overall energy consumption can be reduced by replacing inefficient bulbs and linear fluorescent bulbs with more efficient LED technology. To compute the annual savings for this ECM, the energy consumption of the current lighting fixtures was established and compared to the proposed fixture power requirement with the same annual hours of operation. The difference between the existing and proposed annual energy consumption was the energy savings. These calculations are based on 1 to 1 replacements of the fixtures, and do not take into account lumen output requirements for a given space. A more comprehensive engineering study should be performed to determine correct lighting levels. Supporting calculations, including assumptions for lighting hours and annual energy usage for each fixture, are provided in Appendix C and summarized below:


ECM-L1 Lighting Replacement / Upgrades

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



76,857 18 66,671 0 10,683 0.6 1,890 7.2 7.0 * LED retrofits must go through the “custom” measures incentive option under New Jersey SmartStart Program. There are no “prescriptive” incentives for LED retrofits. Projects must achieve a minimum of 75,000 kWh annual savings to qualify for “custom” incentives. See section 6.0 for other incentive opportunities This measure is not recommended in lieu of ECM L3.

5.9.2 ECM-L2 Install Lighting Controls (Occupancy Sensors) Presently, all interior lighting fixtures are controlled by wall mounted switches. Review of the comprehensive lighting survey determined that lighting in some areas could benefit from installation of occupancy sensors to turn off lights when they are unoccupied. This measure recommends installing occupancy sensors for the current lighting system. Using a process similar to that utilized in Section ECM-L1, the energy savings for this measure was calculated by applying the known fixture wattages in the space to the estimated existing and proposed times of operation for each fixture. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below: ECM-L2 Install Lighting Controls (Occupancy Sensors)

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



16,740 0 10,532 0 1,285 (0.1) 2,170 13.0 11.3 * Incentive shown is per the New Jersey SmartStart Program. See section 6.0 for other incentive opportunities. This measure is not recommended in lieu of ECM L3.

5.9.3 ECM-L3 Lighting Replacements with Controls (Occupancy Sensors) This measure is a combination of ECM-L1 and ECM-L2; recommending replace/upgrade the current lighting fixtures to more efficient ones and installing occupancy sensors on the new lights. Interactive effects of the higher efficiency lights and occupancy sensors lead the energy and cost savings for this measure to not be cumulative or equivalent to the sum of replacing the lighting fixtures alone and installing occupancy sensors without the lighting upgrade. The implementation cost and savings related to this ECM are presented in Appendix C and summarized below:


ECM-L3 Lighting Replacements with Controls (Occupancy Sensors)

Budgetary Cost


Incentive*

Payback (without

incentive)

Payback (with



93,597 18 71,290 0 11,246 0.4 4,060 8.3 8.0 * LED retrofits must go through the “custom” measures incentive option under New Jersey SmartStart Program. There are no “prescriptive” incentives for LED retrofits. Projects must achieve a minimum of 75,000 kWh annual savings to qualify for “custom” incentives. See section 6.0 for other incentive opportunities This measure is recommended.

5.10 Additional O&M Opportunities This list of operations and maintenance (O&M) - type measures represent low-cost or no-cost opportunities, which if implemented will have a positive impact on the overall building operations, comfort and/or energy consumption. The recommended O&M measures for this building are as follows:

• O&M-1 Replace air filters in all fan coils and AHUs • O&M-2 Replace fan coil motors with ECM motors (when motors fail)


PROJECT INCENTIVES 6.0

6.1 Incentives Overview The following sections give detailed information on available incentive programs including New Jersey Smart Start, Direct Install, New Jersey Pay for Performance (P4P) and Energy Savings Improvement Plan (ESIP). If the School District wishes to and is eligible to participate in the Energy Savings Improvement Plan (ESIP) program and/or the Pay for Performance Incentive Program (P4P), it cannot participate in either the Smart Start or Direct Install Programs. Refer to Appendix D for more information on the Smart Start program.

6.1.1 New Jersey Smart Start Program For this energy audit, The New Jersey Smart Start Incentives are used in the energy savings calculations, where applicable. This program is intended for medium and large energy users and provides incentives for:

• Electric Chillers • Gas Chillers • Gas Heating • Unitary HVAC • Ground Source Heat Pumps • Variable frequency Drives/ motors • Refrigeration • Prescriptive and performance lighting and lighting controls

The equipment is procured using a typical bid- build method, installed and paid for and then the incentives are reimbursed to the owner. Refer to Appendix D for more information on the Smart Start program.

6.1.2 Direct Install Program The Direct Install Program applies to smaller facilities that have a peak electrical demand of 200 kW or less in any of the previous 12 months. Buildings must be located in New Jersey and served by one of the state’s public, regulated electric utility companies. Direct Install is funded through New Jersey’s Clean Energy Program and is designed to provide capital for building energy upgrade projects to fast track implementation. The program will pay up to 70% of the costs for lighting, HVAC, motors, refrigeration, and other equipment upgrades with higher efficiency alternatives. If a building is eligible for this funding, the Direct Install Program can reduce the implementation cost of energy conservation projects. The Direct Install program has specific HVAC equipment and lighting requirements and is generally applicable only to smaller package HVAC units, small boilers and lighting retrofits.


The program pays a maximum amount of $75,000 per building, and up to $250,000 per customer per year. Installations must be completed by an approved Direct Install participating contractor, a list of which can be found on the New Jersey Clean Energy Website. Contractors will coordinate with the applicant to arrange installation of recommended measures identified in a previous energy assessment, such as this energy audit. The incentive is reimbursed to the Owner upon successful replacement and payment of the equipment. The building qualifies for this program because its electrical demand is less than the maximum peak electrical demand of 200 kW for the last 12 month period. Refer to Appendix D for more information on this program.

6.1.3 New Jersey Pay For Performance Program (P4P) This building may be eligible for incentives from the New Jersey Office of Clean Energy. The most significant incentives are available from the New Jersey Pay for Performance (P4P) Program. The P4P program is designed to offset the cost of energy conservation projects for facilities that pay the Societal Benefits Charge (SBC) and whose demand (kW) in any of the preceding 12 months exceeds 100 kW. This demand minimum has been waived for buildings owned by local governments or municipalities and non-profit organizations and is not applicable to public schools. Facilities that meet this criterion must also achieve a minimum performance target of 15% energy reduction by using the EPA Portfolio Manager benchmarking tool before and after implementation of the measure(s). Additionally, the overall return on investment (ROI) must exceed 10%. If the participant is a municipal electric company customer, and a customer of a regulated gas New Jersey Utility, only gas measures will be eligible under the Program. Available incentives are as follows: Incentive #1: Energy Reduction Plan – This incentive is designed to offset the cost of services associated with the development of the Energy Reduction Plan (ERP). The ERP must include a detailed energy audit of the desired ECMs, energy savings calculations (using building modeling software) and inputting of all utility bills into the EPA Portfolio Manager website.

• Incentive Amount: $0.10/SF • Minimum incentive: $5,000 • Maximum Incentive: $50,000 or 50% of Facility annual energy cost

The standard incentive pays $0.10 per square foot, up to a maximum of $50,000, not to exceed 50% of facility annual energy cost, paid after approval of application. For building audits funded by the New Jersey Board of Public Utilities, which receive an initial 75% incentive toward performance of the energy audit, facilities are only eligible for an additional $0.05 per square foot, up to a maximum of $25,000, rather than the standard incentive noted above. The ERP must be completed by a Certified Energy Manager (CEM) and submitted along with the project application. Incentive #2: Installation of Recommended Measures – This incentive is based on projected energy savings as determined in Incentive #1 (Minimum 15% savings must be achieved), and is paid upon successful installation of recommended measures.


Electric • Base incentive based on 15% savings: $0.09/ per projected kWh saved. • For each % over 15% add: $0.005 per projected kWh saved. • Maximum incentive: $0.11/ kWh per projected kWh saved.

Gas • Base incentive based on 15% savings: $0.90/ per projected Therm saved. • For each % over 15% add: $0.05 per projected Therm saved. • Maximum incentive: $1.25 per projected Therm saved.

Incentive cap: 25% of total project cost Incentive #3: Post-Construction Benchmarking Report – This incentive is paid after acceptance of a report proving energy savings over one year utilizing the Environmental Protection Agency (EPA) Portfolio Manager benchmarking tool. Electric

• Base incentive based on 15% savings: $0.09/ per projected kWh saved. • For each % over 15% add: $0.005 per projected kWh saved. • Maximum incentive: $0.11/ kWh per projected kWh saved.

Gas

• Base incentive based on 15% savings: $0.90/ per projected Therm saved. • For each % over 15% add: $0.05 per projected Therm saved. • Maximum incentive: $1.25 per projected Therm saved.

Combining Incentives #2 and #3 will provide a total of $0.18/ kWh and $1.8/therm not to exceed 50% of total project cost. Additional Incentives for #2 and #3 are increased by $0.005/kWh and $0.05/therm for each percentage increase above the 15% minimum target to 20%, calculated with the EPA Portfolio Manager benchmarking tool, not to exceed 50% of total project cost. For the purpose of demonstrating the eligibility of the ECM’s to meet the minimum savings requirement of 15% annual savings and 10% ROI for the Pay for Performance Program, all ECM’s identified in this report have been included in the incentive calculations. The results for the building are shown in Appendix C, with more detailed program information in Appendix D.

6.1.4 Energy Savings Improvement Plan The Energy Savings Improvement Program (ESIP) allows government agencies to make energy related improvements to their facilities and pay for the costs using the value of energy savings that result from the improvements. Under the recently enacted Chapter 4 of the Laws of 2009 (the law), the ESIP provides all government agencies in New Jersey with a flexible tool to improve and reduce energy usage with minimal expenditure of new financial resources. ESIP allows local units to use “energy savings obligations” (ESO) to pay for the capital costs of energy improvements to their facilities. ESIP loans have a maximum loan term of 15 year. ESOs are not considered “new general obligation debt” of a local unit and do not count against debt limits or require voter approval. They may be issued as refunding


bonds or leases. Savings generated from the installation of energy conservation measures pay the principal of and interest on the bonds; for that reason, the debt service created by the ESOs is not paid from the debt service fund, but is paid from the general fund. For local governments interested in pursuing an ESIP, the first step is to perform an energy audit. Pursuing a Local Government Energy Audit through New Jersey's Clean Energy Program is a valuable first step to the ESIP approach. The “Local Finance Notice” outlines how local governments can develop and implement an ESIP for their facilities. The ESIP can be prepared internally if the entity has qualified staff. If not, the ESIP must be implemented by an independent contractor and not by the energy savings company producing the Energy Reduction Plan. The ESIP approach may not be appropriate for all energy conservation and energy efficiency improvements. Local units should carefully consider all alternatives to develop an approach that best meets their needs. Refer to Appendix D for more information on this program.

6.1.5 Renewable Energy Incentive Program The Renewable Energy Incentive Program (REIP) is part of New Jersey's efforts to reach its Energy Master Plan goals of striving to use 30 percent of electricity from renewable sources by 2020. Incentives for sustainable bio-power projects and for energy storage projects are currently under development, with competitive solicitations for each of those technologies expected to begin in the first quarter of 2014. The wind program is currently on hold. New solar projects are no longer eligible for REIP incentives, but can register for Solar Renewable Energy Certificates (SRECs) through the SREC Registration Program (SRP).


ALTERNATIVE ENERGY SCREENING EVALUATION 7.0

7.1 Solar

7.1.1 Photovoltaic Rooftop Solar Power Generation The building was evaluated for the potential to install rooftop photovoltaic (PV) solar panels for power generation. Present technology incorporates the use of solar cell arrays that produce direct current (DC) electricity. This DC current is converted to alternating current (AC) with the use of an electrical device known as an inverter. The amount of available roof area determines how large of a solar array can be installed on any given roof. Due to the unique shape of this building and the minimal available space, a solar PV system was determined to be not feasible.

7.1.2 Solar Thermal Hot Water Generation Active solar thermal systems use solar collectors to gather the sun’s energy to heat a fluid. An absorber in the collector (usually black colored piping) converts the sun’s energy into heat. The heat is transferred to circulating water, antifreeze, or air for immediate use or is storage for later utilization. Applications for active solar thermal energy include supplementing domestic hot water, heating swimming pools, space heating or preheating air in residential and commercial buildings. A standard solar hot water system is typically composed of solar collectors, heat storage vessel, piping, circulators, and controls. Systems are typically integrated to work alongside a conventional heating system that provides heat when solar resources are not sufficient. The solar collectors are usually placed on the roof of the building, oriented south, and tilted at the same angle as the site’s latitude, to maximize the amount of solar radiation collected on a yearly basis. Several options exist for using active solar thermal systems for space heating. The most common method is called a passive solar hot water system involves using glazed collectors to heat a liquid held in a storage tank (similar to an active solar hot water system described above which requires pumping). The most practical system would transfer the heat from the panels to thermal storage tanks and then use the pre-heated water for domestic hot water production. DHW is presently produced by natural gas fired water heaters and, therefore, this measure would offer natural gas utility savings. Unfortunately, the amount of domestic hot water that is currently used by this school is very small. Installing a solar domestic hot water system is not recommended due to the limited amount of domestic hot water presently consumed by the school. This measure is not recommended due to the relatively low domestic hot water usage.

7.2 Wind Powered Turbines Wind power is the conversion of kinetic energy from wind into mechanical power that is used to drive a generator which creates electricity by means of a wind turbine. A wind turbine consists of rotor and blades connected to a gearbox and generator that are


mounted onto a tower. Newer wind turbines also use advanced technology to generate electricity at a variety of frequencies depending on the wind speed, convert it to DC and then back to AC before sending it to the grid. Wind turbines range from 50 – 750 kW for utility scale turbines down to below 50 kW for residential use. On a scale of 1 (the lowest) to 7 (the highest), Class 3 and above (wind speeds of 13 mph or greater) are generally considered “good wind resource” according to the Wind Energy Development Programmatic EIS Information Center hosted by the Bureau of Land Management. According to the map below, published by NREL, Newark, NJ is classified as Class 1 at 50m, meaning the city would not be a good candidate for wind power.

This measure is not recommended due to the location of the school.

7.3 Combined Heat and Power Plant and Fuel Cell System

Combined heat and power (CHP), cogeneration, is self-production of electricity on-site with beneficial recovery of the heat byproduct from the electrical generator. Common CHP equipment includes reciprocating engine-driven, micro turbines, steam turbines, and fuel cells. Typical CHP customers include industrial, commercial, institutional, educational institutions, and multifamily residential facilities. CHP systems that are commercially viable at the present time are sized approximately 50 kW and above, with numerous options in blocks grouped around 300 kW, 800 kW, 1,200 kW and larger. Typically, CHP systems are used to produce a portion of the electricity needed by a facility some or all of the time, with the balance of electric needs satisfied by purchase from the grid.

Any proposed CHP project will need to consider many factors, such as existing system load, use of thermal energy produced, system size, natural gas fuel availability, and proposed plant location. The building has sufficient need for electrical generation and the ability to use most of the thermal byproduct during the winter; however thermal usage during the summer months does not exist. Thermal energy produced by the CHP


plant in the warmer months will be wasted. An absorption chiller could be installed to utilize the heat to produce chilled water; however, there is no chilled water distribution system in the building. CHP is not recommended due to the building’s limited summer thermal demand.

This measure is not recommended due to the absence of year-round thermal loads which are needed for efficiency CHP operation. However, a mini-size CHP could be an option for the school to consider. The sizing and energy savings of the mini-size CHP require further study.

A fuel cell system with recovery and productive use of waste heat is another alternative energy option viable in the market. A full analysis of all campus buildings would need to be completed to determine the economic viability. The several buildings included in the scope of work are not good candidates for CHP or Fuel cell technology based on their utility usage and geographic locations on their own relative to the main campus.

7.4 Demand Response Curtailment

Presently, electricity is delivered by PSE&G, which receives the electricity from regional power grid RFC. PSE&G is the regional transmission organization (RTO) that coordinates the movement of wholesale electricity in all or parts of 13 states and the District of Columbia including the State of New Jersey. Utility Curtailment is an agreement with the utility provider’s regional transmission organization and an approved Curtailment Service Provider (CSP) to shed electrical load by either turning major equipment off or energizing all or part of a facility utilizing an emergency generator; therefore, reducing the electrical demand on the utility grid. This program is to benefit the utility company during high demand periods and utility provider offers incentives to the CSP to participate in this program. Enrolling in the program will require program participants to drop electrical load or turn on emergency generators during high electrical demand conditions or during emergencies. Part of the program also will require that program participants reduce their required load or run emergency generators with notice to test the system. A pre-approved CSP will require a minimum of 100 kW of load reduction to participate in any curtailment program. From February 2013 through January 2014 the following table summarizes the electricity load profile for the building.

Building Electric Load Profile

Peak Demand kW

Min Demand kW

Avg Demand kW

Onsite Generation

Y/N Eligible?

Y/N 160 160 160 N Y

*the demand is estimated from one month bill This measure is not recommended due to the lack of onsite power generators.


CONCLUSIONS & RECOMMENDATIONS 8.0 The following section summarizes the LGEA energy audit conducted by CHA for the Atrium at William Patterson University. The following projects should be considered for implementation:

• Install Door Seals • Install Destratification Fans • Replace the Two Old RTUs with New RTUs • Re-Activate the Dual Temp Pump Motor VFDs • Install VFDs on the Auditorium Air Handling Unit • Install Occupancy Sensors to Control Individual Fan Coil Units • Install Vending Misers • Replace High Flow Plumbing Fixtures with Low Flow Plumbing Fixtures • Lighting Replacements with Controls (Occupancy Sensors)

The potential annual energy and cost savings for the recommended ECMs are shown in the following table.

Electric Savings (kWh)

Natural Gas Savings (therms)

Total Savings ($)

Payback (years)

256,430 3,050 43,216 10.0

If the school implements the recommended ECMs, energy savings would be as follows:

Existing

Conditions

Post Recommended

ECMs Percent Savings

Costs ($) 140,485 97,269 31% Electricity (kWh) 838,400 581,970 31% Natural Gas (therms) 13,455 10,405 23% Site EUI (kbtu/SF/Yr) 100.1 72.1


Next Steps: This energy audit has identified several areas of potential energy savings. William Paterson University can use this information to pursue incentives offered by the NJBPU's NJ Clean Energy Program. Additional meetings will be scheduled with WPU staff members to review possible options.

Existing Conditions Post RecommnededECMs

0

100,000

200,000

300,000

400,000

500,000

600,000

700,000

800,000

900,000

Costs ($)

Electricity (kWh)

Natural Gas (therms)

APPENDIX A

Utility Usage Analysis and Alternate Utility Suppliers

APPENDIX D

New Jersey Board of Public Utilities Incentives

i. Smart Start

ii. Direct Install

iii. Pay for Performance (P4P)

iv. Energy Savings Improvement Plan (ESIP)

William Patterson University LGEA

Atrium Electric Usage

Annual Utilities

12-month Summary

Annual Usage 838,400 kWh/yr

Annual Cost 125,339 $

Blended Rate 0.149 $/kWh

Consumption Rate 0.122 $/kWh

Demand Rate 11.93 $/kW

Peak Demand 160.0 kW

Min. Demand 160.0 kW

Avg. Demand 160.0 kW

Annual Usage 13,455 therms/yr

Annual Cost 15,146 $

Rate 1.126 $/therm

Electric

Natural Gas


Atrium

Utility Bills: Account Numbers

Account Number Building Name Location Type Notes

42-000-984-07 Atrium 300 Pompton Road, Wayne NJ 07470 Electricity

42-000-984-07 Atrium 301 Pompton Road, Wayne NJ 07470 Natural Gas



For Service at:

Account No.: 42-000-984-07 Delivery - PSE&G

Meter No.: 778015341 Supplier - Direct Energy

Electric Service

Consumption Demand Delivery Supplier Total Consumption Demand Blended Rate Consumption Demand

Month (kWh) (kW) ($) ($) ($) ($) ($) ($/kWh) ($/kWh) ($/kW)

February-13 62,000 160.00 6,116.55 2,827.37 8,943.92 7,035.79 1,908.13 0.14 0.11 11.93

March-13 86,400 160.00 8,523.71 3,525.37 12,049.08 10,140.95 1,908.13 0.14 0.12 11.93

April-13 70,400 160.00 6,945.24 3,009.61 9,954.85 8,046.72 1,908.13 0.14 0.11 11.93

May-13 50,800 160.00 5,011.62 2,887.04 7,898.66 5,990.53 1,908.13 0.16 0.12 11.93

June-13 73,200 160.00 7,221.47 5,555.82 12,777.29 10,869.16 1,908.13 0.17 0.15 11.93

July-13 76,400 160.00 7,537.17 4,684.89 12,222.06 10,313.93 1,908.13 0.16 0.13 11.93

August-13 64,000 160.00 6,313.86 4,071.08 10,384.94 8,476.81 1,908.13 0.16 0.13 11.93

September-13 69,600 160.00 6,866.32 4,649.64 11,515.96 9,607.83 1,908.13 0.17 0.14 11.93

October-13 57,200 160.00 5,643.01 2,566.45 8,209.46 6,301.33 1,908.13 0.14 0.11 11.93

November-13 67,200 160.00 6,629.55 2,915.77 9,545.32 7,637.19 1,908.13 0.14 0.11 11.93

December-13 83,200 160.00 8,208.01 3,072.35 11,280.36 9,372.23 1,908.13 0.14 0.11 11.93

January-14 78,000 160.00 7,695.01 2,862.47 10,557.48 8,649.35 1,908.13 0.14 0.11 11.93

Total (All) 838,400 160.00 $82,711.51 $42,627.87 $125,339.38 $102,441.82 $22,897.56 $0.15 $0.12 $11.93

Notes 1 2 3 4 5 6 7 8 9 10

1.) Number of kWh of electric energy used per month

2.) Number of kW of power measured

3.) Electric charges from Delivery provider

4.) Electric charges from Supply provider

5.) Total charges (Delivery + Supplier)

6.) Charges based on the number of kWh of electric energy used

7.) Charges based on the number of kW of power measured

8.) Total Charges ($) / Consumption (kWh)

9.) Consumption Charges ($) / Consumption (kWh)

10.) Demand Charges ($) / Demand (kW)

Provider Charges Unit CostsUsage (kWh) vs. Demand (kW) Charges

Atrium Utility Data - YY

Electric

Atrium Utility Data - YY

Electric Graph

0

20

40

60

80

100

120

140

160

180

0

10,000

20,000

30,000

40,000

50,000

60,000

70,000

80,000

90,000

100,000

Feb

-13

Ma

r-1

3

Apr-

13

Ma

y-1

3

Jun-1

3

Jul-1

3

Aug-1

3

Sep-1

3

Oct-

13

No

v-1

3

De

c-1

3

Jan-1

4

Dem

an

d (

kW

)

Usag

e (

kW

h)

Month


(kWh) (kW)


Atrium Gas Usage

For Service at:

Account No.: 42-000-984-07

Meter No: 3165582

Natural Gas Service Delivery - PSE&G

Supplier - HESS

Consumption Delivery Supply Total Delivery Supply Total(Therms) ($) ($) ($) ($/Therm) ($/Therm) ($/Therm)

February-13 3,076 1,933.55$ 1,717.38$ 3,650.93$ 0.629$ 0.558$ 1.187$ March-13 2,007 1,449.36$ 1,120.58$ 2,569.94$ 0.722$ 0.558$ 1.280$ April-13 1,307 576.09$ 729.92$ 1,306.01$ 0.441$ 0.558$ 0.999$ May-13 231 189.52$ 129.00$ 318.52$ 0.820$ 0.558$ 1.378$ June-13 0 104.24$ -$ 104.24$ -$ -$ -$ July-13 0 104.24$ -$ 104.24$ -$ -$ -$ August-13 0 104.24$ -$ 104.24$ -$ -$ -$ September-13 0 104.24$ -$ 104.24$ -$ -$ -$ October-13 0 104.24$ -$ 104.24$ -$ -$ -$ November-13 1,212 785.82$ 676.78$ 1,462.60$ 0.648$ 0.558$ 1.207$ December-13 2,410 1,041.49$ 1,345.54$ 2,387.03$ 0.432$ 0.558$ 0.990$ January-14 3,211 1,136.95$ 1,792.65$ 2,929.60$ 0.354$ 0.558$ 0.912$ Total 13,455.02 15,145.83$ 1.126$

Charges Unit Costs

Month

0.00

0.20

0.40

0.60

0.80

1.00

1.20

1.40

1.60

0

500

1,000

1,500

2,000

2,500

3,000

3,500

Feb

-13

Mar

-13

Ap

r-1

3

May

-13

Jun

-13

Jul-

13

Au

g-1

3

Sep

-13

Oct

-13

No

v-1

3

De

c-1

3

Jan

-14

Un

it C

ost

($

/Th

erm

)

Co

nsu

mp

tio

n (

The

rms)

Atrium Gas Usage

Consumption (Therms) Total ($/Therm)

PSE&G ELECTRIC SERVICE TERRITORY

Last Updated: 10/24/12

*CUSTOMER CLASS - R – RESIDENTIAL C – COMMERCIAL I –INDUSTRIAL

Supplier Telephone

& Web Site

*Customer

Class

AEP Energy, Inc.

309 Fellowship Road, Fl. 2

Mount Laurel, NJ 08054

(866) 258-3782

www.aepenergy.com

C/I

ACTIVE

Alpha Gas and Electric, LLC

641 5th

Street

Lakewood, NJ 08701

(855) 553-6374

www.alphagasandelectric.com

R/C

ACTIVE

Ambit Northeast, LLC

103 Carnegie Center

Suite 300

Princeton, NJ 08540

(877)-30-AMBIT

(877) 302-6248

www.ambitenergy.com

R/C

ACTIVE

American Powernet

Management, LP 437 North Grove St.

Berlin, NJ 08009

(877) 977-2636

www.americanpowernet.com

C

ACTIVE

Amerigreen Energy, Inc.

1463 Lamberton Road

Trenton, NJ 08611

888-423-8357

www.amerigreen.com

R/C

ACTIVE

AP Gas & Electric, LLC

10 North Park Place, Suite 420

Morristown, NJ 07960

(855) 544-4895

www.apge.com

R/C/I

ACTIVE

Astral Energy LLC

16 Tyson Place

Bergenfield, NJ 07621

(201) 384-5552

www.astralenergyllc.com

R/C/I

ACTIVE

Barclays Capital Services,

Inc.

70 Hudson Street

Jersey City, NJ 07302-4585

(888) 978-9974

www.group.barclays.com

C

ACTIVE

BBPC, LLC d/b/a Great

Eastern Energy

116 Village Blvd. Suite 200

Princeton, NJ 08540

(888) 651-4121

www.greateasternenergy.com

C/I

ACTIVE

Champion Energy Services,

LLC

72 Avenue L

Newark, NJ 07105

(877) 653-5090

www.championenergyservices.com

R/C/I

ACTIVE

http://www.aepenergy.com/

http://www.alphagasandelectric.com/

http://www.ambitenergy.com/

http://www.hess.com/

http://www.amerigreen.com/

http://www.apge.com/

http://www.astralenergyllc.com/

http://www.group.barclays.com/

http://www.greateasternenergy.com/

http://www.championenergyservices.com/

Choice Energy, LLC

4257 US Highway 9, Suite 6C

Freehold, NJ 07728

888-565-4490

www.4choiceenergy.com

R/C

ACTIVE

Clearview Electric, Inc.

505 Park Drive

Woodbury, NJ 08096

(888) CLR-VIEW

(800) 746-4702

www.clearviewenergy.com

R/C/I

ACTIVE

Commerce Energy, Inc. 7 Cedar Terrace

Ramsey, NJ 07446

1-866-587-8674

www.commerceenergy.com

R

ACTIVE

ConEdison Solutions

Cherry Tree Corporate Center

535 State Highway

Suite 180

Cherry Hill, NJ 08002

(888) 665-0955

www.conedsolutions.com

C/I

ACTIVE

Constellation NewEnergy,

Inc.

900A Lake Street, Suite 2

Ramsey, NJ 07446

(866) 237-7693

www.constellation.com

R/C/I

ACTIVE

Constellation Energy


Ramsey, NJ 07446

(877) 997-9995


R

ACTIVE

Credit Suisse, (USA) Inc.

700 College Road East

Princeton, NJ 08450

(212) 538-3124

www.creditsuisse.com

C

ACTIVE

Direct Energy Business, LLC

120 Wood Avenue, Suite 611

Iselin, NJ 08830

(888) 925-9115

www.directenergybusiness.com

C/I

ACTIVE

Direct Energy Services, LLC


Iselin, NJ 08830

(866) 348-4193

www.directenergy.com

R

ACTIVE

Discount Energy Group,

LLC

811 Church Road, Suite 149

Cherry Hill, New Jersey

08002

(800) 282-3331

www.discountenergygroup.com

R/C

ACTIVE

Dominion Retail, Inc.

d/b/a Dominion Energy

Solutions

395 Route #70 West

Suite 125

Lakewood, NJ 08701

(866) 275-4240

www.dom.com/products

R/C

ACTIVE

http://www.4choiceenergy.com/

http://www.clearviewenergy.com/

http://www.commerceenergy.com/

http://www.conedsolutions.com/

http://www.constellation.com/


http://www.creditsuisse.com/

http://www.directenergybusiness.com/

http://www.directenergy.com/

http://www.discountenergygroup.com/

http://www.dom.com/products

DTE Energy Supply, Inc.

One Gateway Center,

Suite 2600

Newark, NJ 07102

(877) 332-2450

www.dtesupply.com

C/I

ACTIVE

Energy.me Midwest LLC

90 Washington Blvd

Bedminster, NJ 07921

(855) 243-7270

www.energy.me

R/C/I

ACTIVE

Energy Plus Holdings LLC 309 Fellowship Road

East Gate Center, Suite 200

Mt. Laurel, NJ 08054

(877) 866-9193

www.energypluscompany.com

R/C

ACTIVE

Ethical Electric Benefit Co.

d/b/a Ethical Electric

100 Overlook Center, 2nd

Fl.

Princeton, NJ 08540

(888) 444-9452

www.ethicalelectric.com

R/C

ACTIVE

FirstEnergy Solutions

300 Madison Avenue


(800) 977-0500

www.fes.com

C/I

ACTIVE

Gateway Energy Services

Corp.

44 Whispering Pines Lane

Lakewood, NJ 08701

(800) 805-8586

www.gesc.com

R/C/I

ACTIVE

GDF SUEZ Energy

Resources NA, Inc.

333 Thornall Street

Sixth Floor

Edison, NJ 08837

(866) 999-8374

www.gdfsuezenergyresources.com

C/I

ACTIVE

Glacial Energy of New

Jersey, Inc.

75 Route 15 Building E

Lafayette, NJ 07848

(888) 452-2425

www.glacialenergy.com

C/I

ACTIVE

Global Energy Marketing

LLC

129 Wentz Avenue

Springfield, NJ 07081

(800) 542-0778

www.globalp.com

C/I

ACTIVE

Green Mountain Energy

Company

211 Carnegie Center Drive

Princeton, NJ 08540

(866) 767-5818

www.greenmountain.com/commercial-

home

C/I

ACTIVE

http://www.dtesupply.com/

http://www.energy.me/

http://www.energypluscompany.com/

http://www.ethicalelectric.com/

http://www.gesc.com/

http://www.suezenergyresources.com/

http://www.glacialenergy.com/

http://www.globalp.com/

http://www.greenmountain.com/commercial-home

http://www.greenmountain.com/commercial-home

Hess Corporation

1 Hess Plaza

Woodbridge, NJ 07095

(800) 437-7872

www.hess.com

C/I

ACTIVE

HIKO Energy, LLC

655 Suffern Road

Teaneck, NJ 07666

(888) 264-4908

www.hikoenergy.com

R/C

ACTIVE

HOP Energy, LLC d/b/a

Metro Energy, HOP Fleet

Fueling, HOP Energy Fleet

Fueling

1011 Hudson Avenue

Ridgefield, NJ 07657

(877) 390-7155

www.hopenergy.com

R/C/I

ACTIVE

Hudson Energy Services,

LLC

7 Cedar Street

Ramsey, New Jersey 07446

(877) Hudson 9

www.hudsonenergyservices.com

C

ACTIVE

IDT Energy, Inc.

550 Broad Street

Newark, NJ 07102

(877) 887-6866

www.idtenergy.com

R/C

ACTIVE

Independence Energy Group,

LLC

3711 Market Street, 10th

Fl.

Philadelphia, PA 19104

(877) 235-6708

www.chooseindependence.com

R/C

ACTIVE

Integrys Energy Services,

Inc.

99 Wood Ave, South, Suite

802

Iselin, NJ 08830

(877) 763-9977

www.integrysenergy.com

C/I

ACTIVE

Keil & Sons, Inc.

d/b/a Systrum Energy 1 Bergen Blvd.

Fairview, NJ 07022

(877) 797-8786

www.systrumenergy.com

R/C/I

ACTIVE

Liberty Power Delaware,

LLC

1973 Highway 34, Suite 211

Wall, NJ 07719

(866) 769-3799

www.libertypowercorp.com

C/I

ACTIVE

Liberty Power Holdings,

LLC

1973 Highway 34, Suite 211

Wall, NJ 07719

(866) 769-3799

www.libertypowercorp.com

C/I

ACTIVE


http://www.hikoenergy.com/

http://www.hopenergy.com/

http://www.hudsonenergyservices.com/

http://www.idtenergy.com/

http://www.chooseindependence.com/

http://www.firstenergyservices.com/

http://www.systrumenergy.com/

http://www.libertypowercorp.com/

http://www.libertypowercorp.com/

Linde Energy Services

575 Mountain Avenue

Murray Hill, NJ 07974

(800) 247-2644

www.linde.com

C/I

ACTIVE

Marathon Power LLC

302 Main Street

Paterson, NJ 07505

( 888) 779-7255

www.mecny.com

R/C/I

ACTIVE

MXenergy Electric Inc.

900 Lake Street

Ramsey, NJ 07446

(800) 785-4374

www.mxenergy.com

R/C/I

ACTIVE

NATGASCO, Inc.

532 Freeman St.

Orange, NJ 07050

(973) 678-1800 x. 251

www.supremeenergyinc.com

R/C

ACTIVE

NextEra Energy Services

New Jersey, LLC

651 Jernee Mill Road

Sayreville, NJ 08872

(877) 528-2890 Commercial

(800) 882-1276 Residential

www.nexteraenergyservices.com

R/C/I

ACTIVE

New Jersey Gas & Electric

1 Bridge Plaza fl. 2

Fort Lee, NJ 07024

(866) 568-0290

www.NJGandE.com

R/C

ACTIVE

Noble Americas Energy

Solutions

The Mac-Cali Building

581 Main Street, 8th Floor


(877) 273-6772

www.noblesolutions.com

C/I

ACTIVE

North American Power and

Gas, LLC

222 Ridgedale Avenue

Cedar Knolls, NJ 07927

(888) 313-9086

www.napower.com

R/C/I

ACTIVE

Palmco Power NJ, LLC

One Greentree Centre

10,000 Lincoln Drive East,

Suite 201

Marlton, NJ 08053

(877) 726-5862

www.PalmcoEnergy.com

R/C/I

ACTIVE

Pepco Energy Services, Inc.

112 Main St.

Lebanon, NJ 08833

(800) ENERGY-9 (363-7499)

www.pepco-services.com

C/I

ACTIVE

Plymouth Rock Energy, LLC

338 Maitland Avenue

Teaneck, NJ 07666

(855) 32-POWER (76937)

www.plymouthenergy.com

R/C/I

ACTIVE

http://www.linde.com/

http://www.mecny.com/

http://www.mxenergy.com/

http://www.supremeenergyinc.com/

http://www.nexteraenergyservices.com/

http://www.njgande.com/

http://www.noblesolutions.com/

http://www.napower.com/

http://www.palmcoenergy.com/

http://www.pepco-services.com/

http://www.plymouthenergy.com/

PPL Energy Plus, LLC

811 Church Road


(800) 281-2000

www.pplenergyplus.com

C/I

ACTIVE

Public Power & Utility of

New Jersey, LLC

39 Old Ridgebury Rd. Suite 14

Danbury, CT 06810

(888) 354-4415

www.ppandu.com

R/C/I

ACTIVE

Reliant Energy

211 Carnegie Center

Princeton, NJ 08540

(877) 297-3795

(877) 297-3780

www.reliant.com/pjm

R/C/I

ACTIVE

ResCom Energy LLC

18C Wave Crest Ave.

Winfield Park, NJ 07036

(888) 238-4041

http://rescomenergy.com

R/C/I

ACTIVE

Respond Power LLC

10 Regency CT

Lakewood, NJ 08701

(877) 973-7763

www.respondpower.com

R/C/I

ACTIVE

South Jersey Energy

Company

1 South Jersey Plaza, Route 54

Folsom, NJ 08037

(800) 266-6020

www.southjerseyenergy.com

C/I

ACTIVE

Sperian Energy Corp.

1200 Route 22 East, Suite 2000

Bridgewater, NJ 08807

(888) 682-8082 R/C/I

ACTIVE

S.J. Energy Partners, Inc.

208 White Horse Pike, Suite 4

Barrington, N.J. 08007

(800) 695-0666

www.sjnaturalgas.com

R/C

ACTIVE

Spark Energy, L.P.

2105 CityWest Blvd., Ste 100

Houston, Texas 77042

(800) 441-7514

www.sparkenergy.com

R/C/I

ACTIVE

Sprague Energy Corp.

12 Ridge Road

Chatham Township, NJ 07928

(800) 225-1560

www.spragueenergy.com

C/I

ACTIVE

Starion Energy PA Inc.

101 Warburton Avenue

Hawthorne, NJ 07506

(800) 600-3040

www.starionenergy.com

R/C/I

ACTIVE

Stream Energy

309 Fellowship Rd., Suite 200


(877) 39-8150

www.streamenergy.net

R

ACTIVE

http://www.pplenergyplus.com/

http://www.ppandu.com/

http://www.reliant.com/pjm

http://rescomenergy.com/

http://www.respondpower.com/

http://www.southjerseyenergy.com/

http://www.sjnaturalgas.com/

http://www.sparkenergy.com/

http://www.spragueenergy.com/

http://www.starionenergy.com/

http://www.streamenergy.net/

UGI Energy Services, Inc.

d/b/a GASMARK

224 Strawbridge Drive

Suite 107

Moorestown, NJ 08057

(856) 273-9995

www.ugienergyservices.com

C/I

ACTIVE

Verde Energy USA, Inc.

50 East Palisades Avenue

Englewood, NJ 07631

(800) 388-3862

www.lowcostpower.com

R/C/I

ACTIVE

Viridian Energy

2001 Route 46, Waterview

Plaza

Suite 310

Parsippany, NJ 07054

(866) 663-2508

www.viridian.com

R/C/I

ACTIVE

Xoom Energy New Jersey,

LLC

744 Broad Street

Newark, NJ 07102

(888) 997-8979

www.xoomenergy.com

R/C/I

ACTIVE

YEP Energy

89 Headquarters Plaza North

#1463


(855) 363-7736

www.yepenergyNJ.com

R/C/I

ACTIVE

Your Energy Holdings, LLC

One International Boulevard

Suite 400

Mahwah, NJ 07495-0400

(855) 732-2493

www.thisisyourenergy.com

R/C/I

ACTIVE

Back to the main supplier page

http://www.ugienergyservices.com/

http://www.lowcostpower.com/

http://www.viridian.com/

http://www.xoomenergy.com/

http://www.yepenergynj.com/

http://www.thisisyourenergy.com/

http://www.bpu.state.nj.us/wwwroot/energy/supplierlist.htm

PSE&G GAS SERVICE TERRITORY

Last Updated: 10/24/12

*CUSTOMER CLASS - R – RESIDENTIAL C – COMMERCIAL I - INDUSTRIAL

Supplier Telephone

& Web Site

*Customer

Class

Ambit Northeast, LLC

103 Carnegie Center

Suite 300

Princeton, NJ 08540

(877)-30-AMBIT

(877) 302-6248

www.ambitenergy.com

R/C

ACTIVE

Astral Energy LLC

16 Tyson Place

Bergenfield, NJ 07621

888-850-1872

www.astralenergyllc.com

R/C/I

ACTIVE

BBPC, LLC Great Eastern Energy

116 Village Blvd. Suite 200

Princeton, NJ 08540

888-651-4121

www.greateasternenergy.com

C/I

ACTIVE

Clearview Electric Inc.

d/b/a Clearview Gas

1744 Lexington Ave.

Pennsauken, NJ 08110

800-746-4720

www.clearviewenergy.com

R/C

ACTIVE

Colonial Energy, Inc.

83 Harding Road

Wyckoff, NJ 07481

845-429-3229

www.colonialgroupinc.com

C/I

ACTIVE

Commerce Energy, Inc.

7 Cedar Terrace

Ramsey, NJ 07746

(888) 817-8572

www.commerceenergy.com

R

ACTIVE

Compass Energy Services, Inc.

1085 Morris Avenue, Suite 150

Union, NJ 07083

866-867-8328

908-638-6605

www.compassenergy.net

C/I

ACTIVE

ConocoPhillips Company

224 Strawbridge Drive, Suite 107


800-646-4427

www.conocophillips.com

C/I

ACTIVE

Consolidated Edison Energy, Inc.

d/b/a Con Edison Solutions

535 State Highway 38, Suite 140


888-686-1383 x2130

www.conedenergy.com

http://www.ambitenergy.com/

http://www.astralenergyllc.com/

http://www.greateasternenergy.com/

http://www.clearviewenergy.com/

http://www.colonialgroupinc.com/

http://www.commerceenergy.com/

http://www.compassenergy.net/

http://www.conocophillips.com/

http://www.conedenergy.com/

Consolidated Edison Solutions, Inc.

Cherry Tree Corporate Center

535 State Highway 38, Suite 140


888-665-0955

www.conedsolutions.com

C/I

ACTIVE

Constellation NewEnergy-Gas

Division, LLC


Ramsey, NJ 07466

(800) 900-1982


C/I

ACTIVE

Direct Energy Business, LLC


Iselin, NJ 08830

888-925-9115


C/I

ACTIVE

Direct Energy Services, LLP


Iselin, NJ 08830

866-348-4193


R

ACTIVE

Gateway Energy Services Corp. 44 Whispering Pines Lane

Lakewood, NJ 08701

800-805-8586

www.gesc.com

R/C/I

ACTIVE

UGI Energy Services, Inc.

d/b/a GASMARK 224 Strawbridge Drive, Suite 107


856-273-9995

www.ugienergyservices.com

C/I

ACTIVE

Global Energy Marketing, LLC

129 Wentz Avenue

Springfield, NJ 07081

800-542-0778

www.globalp.com

C/I

ACTIVE

Great Eastern Energy 116 Village Blvd., Suite 200

Princeton, NJ 08540

888-651-4121

www.greateastern.com

C/I

ACTIVE

Greenlight Energy

330 Hudson Street, Suite 4

Hoboken, NJ 07030

718-204-7467

www.greenlightenergy.us

C

ACTIVE

Hess Energy, Inc. One Hess Plaza


800-437-7872

www.hess.com

C/I

ACTIVE

Hess Small Business Services, LLC

One Hess Plaza


888-494-4377

www.hessenergy.com

C/I

ACTIVE

HIKO Energy, LLC

655 Suffern Road

Teaneck, NJ 07666

(888) 264-4908

www.hikoenergy.com

R/C

ACTIVE

http://www.conedsolutions.com/


http://www.directenergy.com/

http://www.cooperativenet.com/

http://www.econnergy.com/

http://www.gasmark.com/

http://www.globalp.com/

http://www.ugienergyservices.com/

http://www.greenlightenergy.us/


http://www.hessenergy.com/

http://www.hikoenergy.com/

Hudson Energy Services, LLC 7 Cedar Street

Ramsey, NJ 07446

877- Hudson 9

www.hudsonenergyservices.com

C

ACTIVE

IDT Energy, Inc.

550 Broad Street

Newark, NJ 07102

877-887-6866

www.idtenergy.com

R/C

ACTIVE

Integrys Energy Services – Natural

Gas, LLC

99 Wood Avenue South

Suite #802

Iselin, NJ 08830

800-536-0151

www.integrysenergy.com

C/I

ACTIVE

Intelligent Energy 2050 Center Avenue, Suite 500

Fort Lee, NJ 07024

800-927-9794

www.intelligentenergy.org

R/C/I

ACTIVE

Keil & Sons, Inc.

d/b/a Systrum Energy

1 Bergen Blvd.

Fairview, NJ 07022

1-877-797-8786


R/C/I

ACTIVE

Major Energy Services, LLC

10 Regency CT

Lakewood, NJ 08701

888-625-6760

www.majorenergy.com

R/C/I

ACTIVE

Marathon Power LLC

302 Main Street

Paterson, NJ 07505

888-779-7255

www.mecny.com

R/C/I

ACTIVE

Metromedia Energy, Inc. 6 Industrial Way

Eatontown, NJ 07724

800-828-9427

www.metromediaenergy.com

C

ACTIVE

Metro Energy Group, LLC 14 Washington Place

Hackensack, NJ 07601

888-53-Metro

www.metroenergy.com

R/C

ACTIVE

MxEnergy, Inc.

900 Lake Street

Ramsey, NJ 07446

800-758-4374

www.mxenergy.com R/C/I

ACTIVE

NATGASCO (Mitchell Supreme)

532 Freeman Street

Orange, NJ 07050

800-840-4GAS

www.natgasco.com

C

ACTIVE

New Energy Services LLC

101 Neptune Avenue

Deal, New Jersey 07723

800-660-3643

www.newenergyservicesllc.com

R/C/I

ACTIVE


http://www.idtenergy.com/

http://www.integrysenergy.com/

http://www.intelligentenergy.org/


http://www.majorenergy.com/

http://www.mecny.com/

http://www.metromediaenergy.com/

http://www.metromediaenergy.com/

http://www.mxenergy.com/

http://www.mitchellsupreme.com/

http://www.newenergyservicesllc.com/

New Jersey Gas & Electric

1 Bridge Plaza, Fl. 2

Fort Lee, NJ 07024

866-568-0290

www.NJGandE.com

R/C

ACTIVE

Noble Americas Energy Solutions

The Mac-Cali Building

581 Main Street, 8th fl.


877-273-6772

www.noblesolutions.com

C/I

ACTIVE

North American Power & Gas,

LLC d/b/a North American Power

197 Route 18 South Ste. 3000

East Brunswick, NJ 08816

(888) 313-9086

www.napower.com

R/C/I

ACTIVE

Palmco Energy NJ, LLC

One Greentree Centre

10,000 Lincoln Drive East, Suite 201

Marlton, NJ 08053

877-726-5862

www.PalmcoEnergy.com

R/C/I

ACTIVE

Pepco Energy Services, Inc.

112 Main Street

Lebanon, NJ 08833

800-363-7499

www.pepco-services.com

C/I

ACTIVE

Plymouth Rock Energy, LLC

338 Maitland Avenue

Teaneck, NJ 07666

855-32-POWER (76937)

www.plymouthenergy.com

R/C/I

ACTIVE

PPL EnergyPlus, LLC

811 Church Road - Office 105


800-281-2000

www.pplenergyplus.com

C/I

ACTIVE

Respond Power LLC

10 Regency CT

Lakewood, NJ 08701

(877) 973-7763

www.respondpower.com

R/C/I

ACTIVE

South Jersey Energy Company

1 South Jersey Plaza, Route 54

Folsom, NJ 08037

800-266-6020

www.southjerseyenergy.com

C/I

ACTIVE

S.J. Energy Partners, Inc.

208 White Horse Pike, Suite 4

Barrington, NJ 08007

800-695-0666

www.sjnaturalgas.com

R/C

ACTIVE

Spark Energy Gas, L.P.

2105 CityWest Blvd, Ste 100

Houston, Texas 77042

800-411-7514

www.sparkenergy.com

R/C/I

ACTIVE

Sprague Energy Corp.

12 Ridge Road

Chatham Township, NJ 07928

855-466-2842

www.spragueenergy.com

C/I

ACTIVE

http://www.njgande.com/

http://www.noblesolutions.com/

http://www.napower.com/

http://www.palmcoenergy.com/


http://www.plymouthenergy.com/


http://www.respondpower.com/

http://www.southjerseyenergy.com/

http://www.sjnaturalgas.com/

http://www.sparkenergy.com/


Stuyvesant Energy LLC

10 West Ivy Lane, Suite 4

Englewood, NJ 07631

800-640-6457

www.stuyfuel.com

C

ACTIVE

Stream Energy New Jersey, LLC

309 Fellowship Road

Suite 200


(973) 494-8097

www.streamenergy.net

R/C

ACTIVE

Systrum Energy

1 Bergen Blvd.

Fairview, NJ 07022

877-797-8786


R/C/I

ACTIVE

Woodruff Energy 73 Water Street

Bridgeton, NJ 08302

800-557-1121

www.woodruffenergy.com

R/C/I

ACTIVE

Woodruff Energy US LLC

73 Water Street, P.O. Box 777

Bridgeton, NJ 08302

856-455-1111

800-557-1121

www.woodruffenergy.com

C/I

ACTIVE

Xoom Energy New Jersey, LLC

744 Broad Street

Newark, NJ 07102

888-997-8979

www.xoomenergy.com

R/C/I

ACTIVE

Your Energy Holdings, LLC

One International Boulevard

Suite 400

Mahwah, NJ 07495-0400

(855) 732-2493

www.thisisyourenergy.com

R/C/I

ACTIVE

Back to main supplier information page


http://www.streamenergy.net/


http://www.woodruffenergy.com/

http://www.woodruffenergy.com/

http://www.xoomenergy.com/

http://www.thisisyourenergy.com/

APPENDIX B

Equipment Inventory

CHA Project # 28661

Atrium

William Paterson University

Description QTY Manufacturer Name Model No. Serial No.Equipment Type /

Utility

Capacity/Size

/EfficiencyEfficiency Location Areas/Equipment Served Date Installed Remaining Useful Life (years) Other Info.

Current year Years Old ASHRAE life expectancy

Boiler 2 AERCO Benchmark 2000 N/A HHW Boiler2000 MBH input, 1740-

1900 MBH output 87%-98% Eff. Atrium Boiler RM

HHW Loop for HHW Coils and

HHW Heaters1996 7 2014 18 25

Pump Motor 1 Toshiba B0254VLE10SH N/AHHW.CHW

Pump/Motor25HP 93.6% efficiency Atrium Boiler RM HHW/CHW Coils 1996 2 2014 18 20

Pump Motor 1 Toshiba B0254VLE10SH N/AHHW.CHW

Pump/Motor25HP 93.6% efficiency Atrium Boiler RM HHW/CHW Coils 1996 2 2014 18 20

Pump Motor 1 N/A N/A N/AHHW.CHW

Pump/Motor10HP 89.50% Atrium Boiler RM HHW/CHW Coils 1996 2 2014 18 20

Pump Motor 1 N/A N/A N/AHHW.CHW

Pump/Motor10HP 89.50% Atrium Boiler RM HHW/CHW Coils 1996 2 2014 18 20

AHU 1 Carrier Flex39 2895T70863 AHU

Blow-through Type

Cooling Tower with Fan

Motor Enclosed

N/A

On the Outside

Ground next to the

Mechanical Room

High School Heat Pump Loop 1996 2 2014 18 20

DHW-1 1 Bradford White D100T1993N JH16991781Natural Gas DHW

Heater199,999 BTH N/A High School MR One Section of High School 1996 2 2014 18 20

Chiller 2 Carrier 30RBB0806 2011Q75819Electric Air Cooled

Chiller80 ton N/A Roof The Whole Building 1996 2 2014 18 20

RTU 2 Carrier 50TJ-028-600QA 3295F62430 RTU

25 ton cooling capacity

and EER of 8.7 , one

10HP supply and two

outdoor 1HP exhuast fans

EER of 8.7 Roof Hallways 1996 2 2014 18 20

Fan Coil Units many Airtherm 061-2L-FCFF November 1995 STD FCU0.06HP Fan Comtor and

HHW/CHW CoilN/A

Classrooms,

Offfices, Computer

Labs and some

Hallways

Classrooms, Offfices, Computer

Labs and some Hallways1995 1 2014 19 20

Energy Audit of Atrium

CHA Project No.28661 Cost of Electricity: $0.122 $/kWh

Existing Lighting & Audit Input $11.93 $/kW

Area Description Usage

No. of

Fixtures Standard Fixture Code Fixture Code

Watts per

Fixture kW/Space Exist Control Annual Hours Annual kWh

Field

Code

Unique description of the location - Room number/Room

name: Floor number (if applicable)

Describe Usage Type

using Operating Hours

No. of

fixtures

before the

retrofit

Lighting Fixture Code Code from Table of Standard Fixture

Wattages

Value from

Table of

Standard

Fixture

Wattages

(Watts/Fixt) * (Fixt

No.)

Pre-inst. control

device

Estimated

annual hours for

the usage group

(kW/space) *

(Annual Hours)

Retrofit control

device

Notes

15LED Mechanical Room 03 Mechanical Room 2 S 32 C F 2 (ELE) F42LL 60 0.12 SW 8736 1,048 C-OCC

35LED Room 100 Computer Room 4 T 32 R F 3 (ELE) F43ILL/2 90 0.36 OCC 8760 3,154 NONE

35LED Room 102 Offices 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 OCC 4368 786 NONE

35LED Room 104 Copy Room 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 OCC 2125 383 NONE

35LED Room 106 Offices 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 OCC 4368 786 NONE Wall Mounted


71 Room 108 Offices 4 I 60 I60/1 60 0.24 OCC 4368 1,048 NONE

5LED Room 110 Offices 4 2T 32 R F 2 (u) (ELE) FU2LL 60 0.24 OCC 4368 1,048 NONE

35LED Room 103 Offices 4 T 32 R F 3 (ELE) F43ILL/2 90 0.36 OCC 4368 1,572 C-OCC

35LED Room 105 Offices 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 OCC 4368 786 C-OCC Wall Mounted




25 Room 113 Offices 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.03 OCC 4368 122 NONE

300 Room 113 Offices 4 ID85 ID85 85 0.34 SW 4368 1,485 NONE

25 Lobby Hallways 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.25 SW 8736 2,201 C-OCC

35LED Room 122 Classrooms 6 T 32 R F 3 (ELE) F43ILL/2 90 0.54 SW 2400 1,296 NONE


71 Room 122 Classrooms 2 I 60 I60/1 60 0.12 SW 2400 288 NONE

35LED Room 124 Classrooms 3 T 32 R F 3 (ELE) F43ILL/2 90 0.27 SW 2400 648 NONE


71 Room 126 Classrooms 5 I 60 I60/1 60 0.30 SW 2400 720 NONE


32LED Men's Room Restroom 2 1T 32 R F 2 (ELE) F42LL 60 0.12 SW 4368 524 NONE

20LED Men's Room Restroom 3 S 28 P F 1 (ELE) F41ILL 31 0.09 SW 4368 406 NONE

32LED Women's Room Restroom 2 1T 32 R F 2 (ELE) F42LL 60 0.12 SW 4368 524 NONE

20LED Women's Room Restroom 3 S 28 P F 1 (ELE) F41ILL 31 0.09 SW 4368 406 NONE

25 Foyer 138 Hallways 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.50 SW 8736 4,403 NONE

32LED Auditorium 144 Classrooms 14 1T 32 R F 2 (ELE) F42LL 60 0.84 SW 2400 2,016 NONE

25 Auditorium 144 Classrooms 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.01 SW 2400 2,419 NONE

25 Auditorium 144 Classrooms 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.39 SW 2400 941 C-OCC

35LED Multimedia Room 131 Classrooms 5 T 32 R F 3 (ELE) F43ILL/2 90 0.45 SW 2400 1,080 C-OCC

35LED Multimedia Room 131 Classrooms 10 T 32 R F 3 (ELE) F43ILL/2 90 0.90 SW 2400 2,160 C-OCC

35LED Computer Room 127 Classrooms 3 T 32 R F 3 (ELE) F43ILL/2 90 0.27 SW 2400 648 NONE


35LED Computer Room 125 Classrooms 11 T 32 R F 3 (ELE) F43ILL/2 90 0.99 SW 2400 2,376 NONE








35LED Room 116 Copy Room 3 T 32 R F 3 (ELE) F43ILL/2 90 0.27 SW 2125 574 NONE

35LED Room 120 Copy Room 3 T 32 R F 3 (ELE) F43ILL/2 90 0.27 SW 2125 574 NONE

35LED Room 200 Offices 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 SW 4368 786 C-OCC














32LED Men's Room Restroom 2 1T 32 R F 2 (ELE) F42LL 60 0.12 SW 4368 524 C-OCC

32LED Women's Room Restroom 2 1T 32 R F 2 (ELE) F42LL 60 0.12 SW 4368 524 C-OCC

35LED Room 214 Offices 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 SW 4368 786 C-OCC Locked










Retrofit

Control

EXISTING CONDITIONS

7/25/2014 Page 2, Existing



Existing Lighting & Audit Input $11.93 $/kW

Area Description Usage

No. of

Fixtures Standard Fixture Code Fixture Code

Watts per

Fixture kW/Space Exist Control Annual Hours Annual kWh

Field

Code

Unique description of the location - Room number/Room


Describe Usage Type

using Operating Hours

No. of

fixtures

before the

retrofit

Lighting Fixture Code Code from Table of Standard Fixture

Wattages

Value from

Table of

Standard

Fixture

Wattages


No.)

Pre-inst. control

device

Estimated

annual hours for

the usage group

(kW/space) *

(Annual Hours)

Retrofit control

device

Notes

Retrofit

Control

EXISTING CONDITIONS




35LED Room 240/242 Offices 4 T 32 R F 3 (ELE) F43ILL/2 90 0.36 SW 4368 1,572 C-OCC

35LED Room 244 Copy Room 2 T 32 R F 3 (ELE) F43ILL/2 90 0.18 OCC 2125 383 NONE



















32LED Men's Room Restroom 2 1T 32 R F 2 (ELE) F42LL 60 0.12 SW 4368 524 C-OCC

32LED Women's Room Restroom 2 1T 32 R F 2 (ELE) F42LL 60 0.12 SW 4368 524 NONE



35LED Room 267/269 Offices 4 T 32 R F 3 (ELE) F43ILL/2 90 0.36 OCC 4368 1,572 NONE





71 Room 258 Conference 12 I 60 I60/1 60 0.72 SW 8760 6,307 C-OCC

35LED Room 260 Offices 8 T 32 R F 3 (ELE) F43ILL/2 90 0.72 SW 4368 3,145 C-OCC

71 Room 262 Offices 6 I 60 I60/1 60 0.36 SW 4368 1,572 C-OCC

35LED Room 262 Offices 6 T 32 R F 3 (ELE) F43ILL/2 90 0.54 SW 4368 2,359 C-OCC

300 Outside Outdoor Lighting 2 ID85 ID85 85 0.17 SW 4368 743 C-OCC

231LED Outside Outdoor Lighting 5 WP400MH1 MH400/1 458 2.29 SW 4368 10,003 C-OCC

Total 424 32.95 125,227

7/25/2014 Page 3, Existing

APPENDIX C

ECM Calculations

William Paterson University - AtriumCHA Project Numer: 28661 Rate of Discount (used for NPV) 3.0%

Yearly UsageMetric Ton Carbon Dioxide Equivalent Building Area

0.149$ $/kWh blended 0.000420205 42,000 Electric Natural Gas Fuel Oil0.122$ $/kWh supply 838,400 0.000420205 125,339$ 15,146$ 11.93$ $/kW 160.0 01.13$ $/Therm 13,455 0.00533471

Estimated 7.50$ $/kgals 0$/Gal

Item Cost Simple Life Equivalent CO2 NJ Smart Start Direct Install Payback w/ ROI NPV IRRY or N kW kWh therms No. 2 Oil gal Water kgal $ Payback Expectancy (Metric tons) Incentives Eligible (Y/N) Incentives kW kWh therms kgal/yr $

Y ECM-1 Install Door Seals 0.0 56 37 0 0 50 230$ 4.6 30 0.2 -$ N 4.6 0.0 1,671 1,099 0 $ 1,487 5.5 $741 21.4%Y ECM-2 Install Destratification Fans 0.0 5,929 236 0 0 1,150 19,900$ 17.3 18 3.8 -$ N 17.3 0.0 106,716 4,256 0 $ 20,693 0.0 ($4,089) 0.4%Y ECM-3 Replace the Two Old RTUs with New RTUs 0.0 52,101 0 0 0 7,763 94,327$ 12.2 15 21.9 2,600$ N 11.8 0.0 781,519 0 0 $ 116,446 0.2 $949 3.1%Y ECM-4 Re-Activate the Dual Temp Pump Motor VFDs 0.0 68,970 0 0 0 10,276 30,390$ 3.0 15 29.0 -$ N 3.0 0.0 1,034,547 0 0 $ 154,147 4.1 $92,290 33.4%Y ECM-5 Install VFDs on the Auditorium Air Handling Unit 0.0 25,570 309 0 0 4,158 26,879$ 6.5 15 12.4 3,000$ N 5.7 0.0 383,546 4,641 0 $ 62,374 1.3 $25,762 15.4%Y ECM-6 Install Occupancy Sensors to Control Individual Fan Coil Units 0.0 21,502 2,468 0 0 5,983 92,889$ 15.5 15 22.2 -$ N 15.5 0.0 322,531 37,017 0 $ 89,738 (0.0) ($21,470) -0.4%Y ECM-7 Install Vending Misers 0.0 9,338 0 0 0 1,391 560$ 0.4 18 3.9 -$ N 0.4 0.0 168,081 0 0 $ 25,044 43.7 $18,576 248.4%Y ECM-8 Replace High Flow Plumbing Fixtures with Low Flow Plumbing Fixtures 0.0 1,675 0 0 127 1,199 74,137$ 61.9 20 0.7 -$ N 61.9 0.0 33,504 0 2,531 $ 23,972 (0.7) ($56,305) -9.0%N ECM-L1 Lighting Replacements / Upgrades 17.8 66,671 0 0 0 10,683 76,857$ 7.2 15 28.0 1,890$ N 7.0 267.1 1,000,065 0 0 $ 187,242 1.4 $52,562 11.4%N ECM-L2 Install Lighting Controls (Add Occupancy Sensors) 0.0 10,532 0 0 0 1,285 16,740$ 13.0 15 4.4 2,170$ N 11.3 0.0 157,980 0 0 $ 23,539 0.4 $769 3.7%Y ECM-L3 Lighting Replacements with Controls (Occupancy Sensors) 17.8 71,290 0 0 0 11,246 93,597$ 8.3 15 30.0 4,060$ N 8.0 267.1 1,069,350 0 0 $ 197,565 1.1 $44,719 9.2%

Total (Does Not Include ECM-L1 & ECM-L2) 17.8 256,430 3,050 0 127 $ 43,216 $ 432,909 10.0 17.9 124 $ 9,660 9.8 267 3,901,466 47,013 2,531 $ 691,467 0.6 145733.59 7.0%Recommended Measures (highlighted green above) 17.8 256,430 3,050 0 127 $ 43,216 $ 432,909 10.0 17.9 124 $ 9,660 0 9.8 267 3,901,466 47,013 2,531 $ 691,467 0.6 145733.59 7.0%

% of Existing 11% 31% 23% 0 0

Multipliers48 Material: 1.027

Building Auditorium Gymnasium Library Classrooms Labor: 1.246Enthalpy Operating Occupied Occupied Occupied Occupied Equipment: 1.124

Temp h (Btu/lb) Bin Hours Hours Hours Hours Hours Hours102.5 Heating System Efficiency 80%97.5 35.4 6 2 0 0 0 0 Cooling Eff (kW/ton) 1.292.5 37.4 31 9 0 0 0 087.5 35.0 131 37 0 0 0 082.5 33.0 500 143 0 0 0 077.5 31.5 620 177 0 0 0 072.5 29.9 664 190 0 0 0 067.5 27.2 854 244 0 0 0 062.5 24.0 927 265 0 0 0 0 Hours 4,427 Hrs57.5 20.3 600 171 0 0 0 0 Weighted Avg 40 F52.5 18.2 730 209 0 0 0 0 Avg 28 F47.5 16.0 491 140 0 0 0 042.5 14.5 656 187 0 0 0 037.5 12.5 1,023 292 0 0 0 0 Hours 4,333 Hrs32.5 10.5 734 210 0 0 0 0 Weighted Avg 68 F27.5 8.7 334 95 0 0 0 0 Avg 78 F22.5 7.0 252 72 0 0 0 017.5 5.4 125 36 0 0 0 012.5 3.7 47 13 0 0 0 07.5 2.1 34 10 0 0 0 02.5 1.3 1 0 0 0 0 0-2.5-7.5

Recommend?

Cooling

Simple Projected Lifetime Savings

Utility Costs

Atrium

Annual Utility Cost

Heating

Newark, NJOccupied Hours/Week

City:

Savings

William Paterson University - AtriumCHA Project Numer: 28661Atrium

Notes/Comments:838,400 Total Based on utility analysis160,000 Lighting From Lighting Calculations 19%100,000 Motors Estimated 12%300,000 Cooling/Heating Estimated 36%100,000 Plug Load Estimated 12%100,000 Computers Estimated 12%78,400 Other Remaining 9%

Notes/Comments:13,455 Total Based on utility analysis 13,455 Boilers Therms/SF x Square Feet Served 100%

0 DHW Based on utility analysis 0%

Utility End Use AnalysisElectricity Use (kWh):

Natural Gas Use (Therms):

Lighting 19%

Motors 12%

Cooling/Heating 36%

Plug Load 12%

Computers 6%

Other 9%

Electricity Use (kWh):

Boilers 100%

DHW 0%

Natural Gas End Use

Boilers

DHW


ECM-1 Install Door SealsDescription: This ECM evaluates the thermal and electrical savings associate with adding door seals and sweeps to prevent infiltration of cold (hot) outdoor air.

Heating System Efficiency 88% Ex Occupied Clng Temp. 72 *F Ex Occupied Htg Temp. 72 *FCooling System Efficiency 1.00 kW/ton Ex Unoccupied Clng Temp. 76 *F Ex Unoccupied Htg Temp. 66 *FLinear Feet of Door Edge 20 LF Cooling Occ Enthalpy Setpoint 27.5 Btu/lb Electricity 0.15$ $/kWh Existing Infiltration Factor* 1.5 cfm/LF Cooling Unocc Enthalpy Setpoint 27.5 Btu/lb Natural Gas 1.13$ $/thermProposed Infiltration Factor* 0.45 cfm/LF*Infiltration Factor per Carrier Handbook of Air Conditioning System Designbased on average door seal gap calculated below.

Occupied Unoccupied Occupied Unoccupied

Avg Outdoor Air Temp.

Bins °FAvg Outdoor Air Enthalpy

Existing Equipment Bin

Hours

Occupied Equipment Bin

Hours

Unoccupied Equipment Bin

HoursDoor Infiltration Load BTUH

Door Infiltration

Load BTUHDoor Infiltration Load BTUH

Door Infiltration

Load BTUH

Existing Cooling Energy

kWh

Proposed Cooling Energy

kWh

Existing Heating Energy therms

Proposed Heating Energy therms

A B C D E F G H I J K L

102.5 0.0 0 0 0 3,713 3,713 1,114 1,114 0 0 0 097.5 35.4 6 2 4 -1,067 -1,067 -320 -320 1 0 0 092.5 37.4 31 9 22 -1,337 -1,337 -401 -401 3 1 0 087.5 35.0 131 37 94 -1,010 -1,010 -303 -303 11 3 0 082.5 33.0 500 143 357 -749 -749 -225 -225 31 9 0 077.5 31.5 620 177 443 -546 -546 -164 -164 28 8 0 072.5 29.9 664 190 474 -325 0 -97 0 5 2 0 067.5 27.2 854 244 610 146 0 44 0 0 0 0 062.5 24.0 927 265 662 308 113 92 34 0 0 2 157.5 20.3 600 171 429 470 275 141 83 0 0 2 152.5 18.2 730 209 521 632 437 190 131 0 0 4 147.5 16.0 491 140 351 794 599 238 180 0 0 4 142.5 14.5 656 187 469 956 761 287 228 0 0 6 237.5 12.5 1,023 292 731 1,118 923 335 277 0 0 11 332.5 10.5 734 210 524 1,280 1,085 384 326 0 0 10 327.5 8.7 334 95 239 1,442 1,247 433 374 0 0 5 122.5 7.0 252 72 180 1,604 1,409 481 423 0 0 4 117.5 5.4 125 36 89 1,766 1,571 530 471 0 0 2 112.5 3.7 47 13 34 1,928 1,733 578 520 0 0 1 07.5 2.1 34 10 24 2,090 1,895 627 569 0 0 1 02.5 1.3 1 0 1 2,252 2,057 676 617 0 0 0 0-2.5 0.0 0 0 0 2,414 2,219 724 666 0 0 0 0-7.5 0.0 0 0 0 2,576 2,381 773 714 0 0 0 0

TOTALS 8,760 2,503 6,257 80 24 52 16

Existing Door Infiltration 30 cfm Savings 37 therms 41$ Existing Unoccupied Door Infiltration 30 cfm 56 kWh 8$ Proposed Door Infiltration 9 cfm 50$ Proposed Unoccupied Door Infiltration 9 cfm

Door Width (ft)

Height (ft) Linear Feet (LF) gap

(in) gap location LF of gap % door w/ gap Average gap for door (in)

Side Door 1 6 8 28 0.25 bottom/seam 20 71% 0.1785714290 0.25 bottom/seam #DIV/0! #DIV/0!0 0.25 all sides #DIV/0! #DIV/0!0 0.25 all sides #DIV/0! #DIV/0!0 0.125 all sides #DIV/0! #DIV/0!0 0.125 all sides #DIV/0! #DIV/0!0 0.125 all sides #DIV/0! #DIV/0!0 0.0625 all sides #DIV/0! #DIV/0!0 0.25 bottom/seam #DIV/0! #DIV/0!0 0.25 bottom/seam #DIV/0! #DIV/0!0 0.0625 all sides #DIV/0! #DIV/0!0 0.25 bottom/seam #DIV/0! #DIV/0!0 0.25 bottom/seam #DIV/0! #DIV/0!0 0.25 bottom/seam #DIV/0! #DIV/0!0 0.25 bottom/seam #DIV/0! #DIV/0!0 0.0625 all sides #DIV/0! #DIV/0!

Total 6 8 28 0.191 20 71% #DIV/0!Note: Doors labeled 'a', 'b', etc. are a part of the same door assembly.

EXISTING LOADS PROPOSED LOADS COOLING ENERGY HEATING ENERGY

William Paterson University - AtriumCHA Project Numer: 28661 MultipliersAtrium Material: 1.03

Labor: 1.25ECM-1 Install Door Seals - Cost Equipment: 1.12

MAT. LABOR EQUIP. MAT. LABOR EQUIP.-$

Door Weatherization Seals & Sweeps 1 EA 40$ 115$ -$ 41$ 143$ -$ 184$ -$ -$ -$ -$

184$ Subtotal**Cost Estimates are for Energy Savings calculations only, do not use for procurement 46$ 25% Contingency

230$

Description QTY UNIT UNIT COSTS

Total

SUBTOTAL COSTS TOTAL COST REMARKS

RS Means 2012


ECM-2 Install Destratification Fans

838,400 kWh13,455 Therms

Media Center HVAC Electric Use 32,937 kWhMedia Center HVAC Gas Use 1,313 Therms

0.15$ $/kWh1.13$ $/Therm

5,929 kWh7

236 Therms7

1,150$

Assumptions1 33% Percent of total facility electric usage for HVAC 2 82% Percent of total facility natural gas usage for HVAC 3 42,000 Total Facility Area (SF)4 5,000 Media Center Area (SF)5 6 Estimated floor to ceiling Δt (°F)6 25 Estimated floor to ceiling height (Ft)7 18.0% Percent HVAC savings for destratification per manufacturer (see table below), Source: http://www.theairpear.com/hvacenergysavings.html

ΔT (°F) 5.4 7.2 9 10.8 12.6 14.4 16.2 18 19.8

20 ft. Ceiling 12.7% 14.7% 16.2% 17.5% 18.7% 19.8% 21.0% 22.0% 23.0%

26 ft. Ceiling 15.8% 17.6% 19.0% 20.8% 22.1% 23.3% 24.4% 26.0% 27.0%

33 ft. Ceiling 18.0% 20.0% 21.8% 23.2% 24.8% 26.3% 27.6% 28.8% 30.5%

40 ft. Ceiling 20.0% 22.0% 23.6% 25.6% 27.0% 28.4% 30.0% 31.8% 33.2%

Source: http://www.theairpear.com/hvacenergysavings.html

Percentage of Energy Savings

S A V I N G SAnnual Destratification Electric savingsAnnual Destratification Natural Gas savingsTotal Cost Savings

Potential Energy Savings Table

Description: This ECM evaluates the energy savings associated with the implementation of de-stratification fans for the Atrium Area. Without De-stratification fans , heated air is trapped at the ceiling due to bouyancy. By forcing this heated air back to the floor, the space temperatures will be more even resulting in the space thermostat being satisfied.

Cost of Natural Gas

E X I S T I N G C O N D I T I O N SExisting Facility Total Electric usageExisting Facility Natural Gas Usage

Cost of Electricty


Labor: 1.25ECM-2 Install Destratification Fans - Cost Equipment: 1.12

QTY UNITMAT. LABOR EQUIP. MAT. LABOR EQUIP.

-$ -$ -$ -$ New Air Pear Model 25 Destratification Fans 8 EA 450$ 1,000$ 3,697$ 9,968$ -$ 13,665$ Vendor EstimationElectrical - misc. 1 LS 1,000$ 1,000$ 1,027$ 1,246$ -$ 2,273$ RS Means 2012

-$ -$ -$ -$

15,938$ Subtotal3,985$ 25% Contingency

**Cost Estimates are for Energy Savings calculations only, do not use for procurement 19,900$ Total

Description UNIT COSTS SUBTOTAL COSTS TOTAL COST REMARKS


ECM-3 Replace the Two Old RTUs with New RTUs

The existing RTUs are in poor condition and one is under repairing. New RTUs with heat pump have higher EERs to save energy

Cooling Savings

Electric Cost $0.149 / kWhSpace Balance Point 55 FSpace Temperature Setpoint 72 deg FBTU / Hr Rating of Existing DXs 300,000 Btu / HrAverage EER 8.7 Nameplate

Item Value UnitsTotal Number of Units 2Existing Annual Electric Usage 80,404 kWhProposed EER 14.0Proposed Annual Electric Usage 49,966 kWh

Heating Savings

Electric Cost $0.149 / kWhSpace Balance Point 55 FSpace Temperature Setpoint 72 deg FkW Rating of Existing Electric Heaters 10 kW

Item Value UnitsTotal Number of Units 2Existing Annual Electric Usage 38,941 kWhProposed Heating EER 14.0Proposed Annual Electric Usage 17,279 kWh

Annual Electric Savings 52,101 kWhAnnual Cost Savings $7,763

OAT - DB Annual Assumed AssumedBin Enthalpy Hours hrs of hrs of

Temp F Cooling Operation Heating Operation0 0 0 0% 0 0% 0

97.5 35 6 77% 5 0% 092.5 37 31 68% 21 0% 087.5 35 131 59% 77 0% 082.5 33 500 50% 250 0% 077.5 32 620 41% 254 0% 072.5 30 664 32% 211 0% 067.5 27 854 23% 194 0% 062.5 24 927 14% 126 50% 46457.5 20 600 5% 27 54% 32552.5 18 730 0% 0 58% 42647.5 16 491 0% 0 63% 30742.5 15 656 0% 0 67% 43737.5 13 1023 0% 0 71% 72532.5 10 734 0% 0 75% 55127.5 9 334 0% 0 79% 26422.5 7 252 0% 0 83% 21017.5 5 125 0% 0 88% 10912.5 4 47 0% 0 92% 437.5 2 34 0% 0 96% 332.5 1 1 0% 0 100% 1-2.5 0 0 0% 0 100% 0

Heat Pump with Supplemental HeatUnit will cycle on w/ temp of room. Possible operating time

ANNUAL SAVINGS

Assumed % of time of

operationAssumed % of time of

operation

Comments

Heat PumpUnit will cycle on w/ temp of room. Possible operating time

setpointEstimated

Comments

ASSUMPTIONS Comments

ASSUMPTIONS Comments

setpointTotal Cooling BTU/H of split systems

-7.5 0 0 0% 0 100% 0

Total 374 8,760 13% 1166 44% 3894


Labor: 1.25ECM-3 Replace the Two Old RTUs with New RTUs - Cost Equipment: 1.12

MAT. LABOR EQUIP. MAT. LABOR EQUIP.

25 Ton RTU 2 EA 22,700$ 2,450$ -$ 46,626$ 6,105$ -$ 52,731$ Piping & Misc. 1 EA 10,000$ 10,000$ 10,270$ 12,460$ -$ 22,730$

-$ -$ -$ -$ -$ -$ -$ -$ -$ -$ -$ -$

75,461$ Subtotal**Cost Estimates are for Energy Savings calculations only, do not use for procurement 18,865$ 25% Contingency

94,327$ Total

Description QTY UNIT UNIT COSTS SUBTOTAL COSTS TOTAL COST REMARKS

RS Means 2012Estimated


ECM-4 Re-Activate the Dual Temp Pump Motor VFDs

Variable InputsSupply Electric Rate $0.149Demand Rate $11.930

Heating System "On" Point 55 Electric Savings 68,970VFD Efficiency 98.5% Demand Savings 0.0

Cost Savings 10,276$

Pump ID Qty HP Total HPExisting Motor

Motor Eff. Motor Motor Eff. Exist. Motor kW

Note 1New Motor kW

Note 2P-1 1 25.0 25.0 93.6% 93.6% 15.94 15.94 <Lead/LagP-2 1 25.0 25.0 93.6% 93.6%P-3 1 10.0 10.0 89.5% 89.5% 6.67 6.67 <Lead/LagP-4 1 10.0 10.0 89.5% 89.5%

Total: 22.61 22.61

OAT - DB Annual Running Pump Existing Proposed Speed Proposed ProposedAvg Hours in Hours Load Pump Pump efficiency Pump Savings

Temp F Bin Bin % kWh kW % kWh kWh(A) (B ) (C) (D) (E) (F) (G) (H) (I)

=IF(A>TP,0,C) =0.5+0.5* =D*AA =BB*E^2.5/CC =C*F/G =E-H(55-A)/(55-12))

See Note 3 See Note 3 See Note 4 See Note 5

102.5 0 0 0% 0 0.0 0.0% 0 097.5 0 0 0% 0 0.0 0.0% 0 092.5 3 3 100% 48 23.0 99.0% 70 -2287.5 34 34 82% 542 13.9 100.0% 473 6982.5 131 131 65% 2,088 7.8 93.4% 1,096 99277.5 500 500 65% 7,970 7.8 93.4% 4,184 3,78672.5 620 620 65% 9,883 7.8 93.4% 5,189 4,69467.5 664 664 65% 10,584 7.8 93.4% 5,557 5,02762.5 854 854 0% 0 0.0 0.0% 0 057.5 927 927 0% 0 0.0 0.0% 0 052.5 600 600 65% 13,565 7.8 93.4% 5,021 8,54447.5 610 610 65% 13,791 7.8 93.4% 5,105 8,68642.5 611 611 65% 13,814 7.8 93.4% 5,113 8,70037.5 656 656 70% 14,831 9.5 96.3% 6,491 8,34032.5 1,023 1,023 76% 23,128 11.6 98.6% 12,057 11,07127.5 734 734 82% 16,595 14.0 100.0% 10,251 6,34422.5 334 334 88% 7,551 16.6 100.0% 5,536 2,01517.5 252 252 94% 5,697 19.5 100.0% 4,903 79412.5 125 125 99% 2,826 22.6 99.2% 2,851 -257.5 47 47 100% 1,063 23.0 99.0% 1,089 -272.5 22 22 100% 497 23.0 99.0% 510 -13-2.5 13 13 100% 294 23.0 99.0% 301 -7-7.5 0 0 0% 0 0.0 0.0% 0 0

8,760 8,760 144,767 75,797 68,970

Notes: 1) Existing motor power was determined using motor nameplate data. Formula: Motor HP x 0.746 x 0.8 / Exist. Motor Eff. 2) New motor power is the same as existing motor power adjusted for the new efficiency, if a new motor is proposed. 3) Weather data from NOAA for Newark, NJ 4) The pump load is estimated at 100% at 12 deg. OAT and 50% at 55 deg. OAT and varies linearly in between. 5) The required VFD motor draw is based on a 2.5 power relationship to load.

This measure looks at reactiving the VFDs and replacing 3 way valves with 2-way valves to reduce pump energy consumption

PUMP SCHEDULE

SAVINGS ANALYSIS


Labor: 1.25ECM-4 Re-Activate the Dual Temp Pump Motor VFDs - Cost Equipment: 1.12


Repair VFDs 4 3,500$ 500$ 14,378$ 2,492$ -$ 16,870$ New Drive Electrical - misc. 4 500$ 500$ 2,054$ 2,492$ -$ 4,546$ Reprogramming 1 -$ 500$ -$ 623$ -$ 623$ Pressure Transducer Recalibration 2 500$ 500$ 1,027$ 1,246$ -$ 2,273$ re-use existing


**Cost Estimates are for Energy Savings calculations only, do not use for procurement 30,390$

REMARKS

Total

Description QTY UNIT UNIT COSTS SUBTOTAL COSTS TOTAL COST


ECM-5 Install VFDs on the Auditorium Air Handling Unit

Utility CostsBlended Electric Rate $0.15 / kWhBlended Natural Gas Rate $1.13 / Therm

Supply & Return Fan Inputs

Supply Fans:Fan ID AHUFan HP 20 HP <Estimated Fan# Fan HP CFM CFM OA % SpeedEstimated Load Factor @ Full Flow 98% LF 1 20 5,000 1,500 80 40 City:Motor Efficiency 93.6% Eff. Occupied Un Occ Occupied Occupied OccupiedAverage kW = 15.62 kW Temp Bin Hours Hours Hours Hours Hours HoursDesign Air Flow 5,000 CFMdes 102.5 0 0 0 0 0 0

97.5 6 4 2 1 0 092.5 31 20 11 4 1 0

Return Fans: 87.5 131 86 45 16 6 2Fan ID AHU 82.5 500 327 173 62 22 8Fan HP 10 HP <Estimated 77.5 620 405 215 77 27 10Estimated Load Factor @ Full Flow 98% LF 72.5 664 434 230 82 29 10Motor Efficiency 92.4% Eff. 67.5 854 558 296 106 38 13Average kW = 7.91 kW 62.5 927 606 321 115 41 15Design Air Flow 4,500 CFMdes 57.5 600 392 208 74 26 9

52.5 730 477 253 90 32 12Airflow, Setpoint, & Efficiency Inputs 47.5 491 321 170 61 22 8

Total CFM O.A. CFM O.A. % 42.5 656 429 227 81 29 10Design Total CFM 5,000 1,500 30% 37.5 1,023 669 354 126 45 16Actual Avg CFM 5,000 1,500 30% 32.5 734 480 254 91 32 12SA Enthalpy, Cooling 24.0 BTU/lbma 27.5 334 218 116 41 15 5Setpoint Cooling 72.0 1 20 5,000 1,500 22.5 252 165 87 31 11 4Setpoint, Heating 72.0 °F 17.5 125 82 43 15 6 2Summer RA Enthalpy 28.9 BTU/lbma 12.5 47 31 16 6 2 1Winter RA Temp 70.0 °F 7.5 34 22 12 4 2 1Balance Point 55.0 °F 2.5 1 1 0 0 0 0Chiller Plant Efficiency 1.000 kW/Ton (Includes Ancillary Equipment) -2.5 0 0 0 0 0 0Boiler Efficiency 88% -7.5 0 0 0 0 0 0

8,760 5,728 3,032Savings Calculations:

Avg. DB Bin Temp

°F

OA Enthalpy

Btu/lbUn-Occupied Bin HOURS Total Supply CFM

Winter MA Temp

Summer MA Enthalpy

Cooling Load MBH

Heating Load MBH

Cooling ton day Heating therms

Fan Power kW

Fan Energy kWh

VAV Load %

Total Supply CFM

Cooling Load MBH

Heating Load MBH

Cooling ton day Heating therms

Fan Power kW

Fan Energy kWh

Annual Cooling ton day

Annual Heating therms

Annual Fan Energy kWh

97 40.0 0 5,000 78 32.2 185 - 0 - 23.5 - 100% 5,000 185 0 0 - 23.5 - - - - 92 38.3 2 5,000 77 31.7 174 - 1 - 23.5 49 95% 4,750 165 0 1 - 21.2 44 0 - 5 87 35.9 11 5,000 75 31.0 158 - 6 - 23.5 253 85% 4,250 134 0 5 - 17.0 182 1 - 70 82 33.8 45 5,000 74 30.4 143 - 23 - 23.5 1,067 85% 4,250 122 0 19 - 17.0 771 3 - 296 77 32.0 173 5,000 72 29.8 131 - 79 - 23.5 4,073 80% 4,000 105 0 63 - 15.1 2,607 16 - 1,466 72 30.3 215 5,000 71 29.3 120 - 89 - 23.5 5,051 75% 3,750 90 0 67 - 13.2 2,841 22 - 2,210 67 27.4 230 5,000 69 28.5 100 - 80 - 23.5 5,409 70% 3,500 70 0 56 - 11.8 2,705 24 - 2,705 62 24.5 296 5,000 68 27.6 0 - 0 - 23.5 6,957 65% 3,250 0 0 0 - 11.8 3,478 - - 3,478 57 21.7 321 5,000 66 26.7 0 - 0 - 23.5 7,552 100% 5,000 0 0 0 - 23.5 7,552 - - - 52 19.0 208 5,000 65 25.9 0 40 0 94.31 23.5 4,888 100% 5,000 0 40 0 94 23.5 4,888 - - - 47 16.5 253 5,000 63 25.2 0 48 0 138.00 23.5 5,947 60% 3,000 0 29 0 83 11.8 2,973 - 55 2,973 42 14.4 170 5,000 62 24.6 0 56 0 108.47 23.5 4,000 65% 3,250 0 37 0 71 11.8 2,000 - 38 2,000 37 12.3 227 5,000 60 23.9 0 64 0 165.82 23.5 5,344 70% 3,500 0 45 0 116 11.8 2,672 - 50 2,672 32 7.7 354 5,000 59 22.5 0 72 0 291.18 23.5 8,334 75% 3,750 0 54 0 218 13.2 4,688 - 73 3,646 27 6.5 254 5,000 57 22.2 0 80 0 232.31 23.5 5,979 80% 4,000 0 64 0 186 15.1 3,827 - 46 2,153 22 5.3 116 5,000 56 21.8 0 89 0 116.35 23.5 2,721 80% 4,000 0 71 0 93 15.1 1,741 - 23 980 17 4.1 87 5,000 54 21.5 0 97 0 95.82 23.5 2,053 85% 4,250 0 82 0 81 17.0 1,483 - 14 570 12 2.9 43 5,000 53 21.1 0 105 0 51.51 23.5 1,018 85% 4,250 0 89 0 44 17.0 736 - 8 283 7 1.7 16 5,000 51 20.7 0 113 0 20.87 23.5 383 95% 4,750 0 107 0 20 21.2 346 - 1 37 2 0.5 12 5,000 50 20.4 0 121 0 16.18 23.5 277 95% 4,750 0 115 0 15 21.2 250 - 1 27 -3 -0.7 0 5,000 48 20.0 0 129 0 0.51 23.5 8 100% 5,000 0 129 0 1 23.5 8 - - - -8 -1.9 3 5,000 47 19.7 0 137 0 4.68 23.5 71 100% 5,000 0 137 0 5 23.5 71 - - -

Total 3,035 1,011 1,151 278 1,336 71,431 92,250 871 999 211 1,027 45,862 66 309 25,570

Electric Demand

ElectricUsage

Nat Gas Usage Maint.

Total Cost

( kW ) ( kWh ) ( Therms ) ( $ ) ( $)Savings 0 25,570 309 $0 $0Savins $ 0 $3,810 $348

Savings

Proposed % Speed Night time

Newark

8,760Existing Proposed

VAV CONVERSION - SAVINGS SUMMARY

$4,158


Labor: 1.25Equipment: 1.12

ECM-5 Install VFDs on the Auditorium Air Handling Unit - Cost


20 HP VFD 1 Ea 2,336$ 772$ 2,399$ 962$ -$ 3,361$ RS Means 201220 HP Motor 1 Ea 861$ 110$ 884$ 137$ -$ 1,022$ RS Means 201210 HP VFD 1 Ea 2,021$ 509$ 2,076$ 634$ -$ 2,710$ RS Means 201310 HP Motor 1 Ea 646$ 88$ 663$ 110$ -$ 773$ RS Means 2014Electrical - misc. 1 ls 3,000$ 3,000$ 3,081$ 3,738$ -$ 6,819$ Engineering EstimateControls 1 Ea 3,000$ 3,000$ 3,081$ 3,738$ -$ 6,819$ Engineering Estimate


**Cost Estimates are for Energy Savings calculations only, do not use for procurement 26,879$

REMARKS

Total

Description QTY UNIT UNIT COSTS SUBTOTAL COSTS TOTAL COST


ECM-6 Install Occupancy Sensors to Control Individual Fan Coil Units

Equipment Tag

Equipment Description General Type

Total Cooling Capacity (ton)

Total Heating Capacity (MBH)

Fan Coil Units HVAC 48 720 <Estimated

Item Value UnitsGas Rate 1.13$ /thremElectricity Rate 0.15$ /kWh

Load "on" Factor 60%Cooling Occupied % 80%Heating Occupied % 90%

Heating Capacity 720 MBHBaseline Heating Efficiency 88%Existing Run Hours 3,016 hrsProposed Run Hours 2,715 hrs

Heating Savings 2,468 therm

Cooling Capacity 48 tonExisting Run Hours 2,240 hrsProposed Run Hours 1,792 hrsChiller Efficiency 1.0 kW/ton

Cooling Savings 21,502 kWh

Gas Savings 2,468 thermElectric Savings 21,502 kWh

Cost Savings 5,983$

Savings calculation formulas are taken from NJ Protocols document for Electric HVAC Equipment

COOLING - FCUs

Estimated

Estimated Based on School HoursEstimated

Estimated

SAVINGS

HEATING - FCUs

Estimated Estimated

Description: This ECM evaluates the energy savings associated with installing an occupancy sensor to control the space temperature 2 F higher (cooling)or 2 F lower(heating) during regularly occupied times when there are no occupants in the room.

Estimated Based on School Hours

Estimated

Formula/Comments

FORMULA CONSTANTSNJ Protocols

Estimated


Labor: 1.25ECM-6 Install Occupancy Sensors to Control Individual Fan Coil Units - Cost Equipment: 1.12


Thermostat with Occupancy Sensors 60 EA 460$ 200$ -$ 28,345$ 14,952$ -$ 43,297$ Connect to DDC system 60 EA 200$ 250$ 12,324$ 18,690$ -$ 31,014$

-$ -$ -$ -$ -$ -$ -$ -$ -$ -$ -$ -$


92,889$ Total

Description QTY UNIT UNIT COSTS SUBTOTAL COSTS TOTAL COST REMARKS

Internet Price


ECM-7 Install Vending Misers

Description :

Unit Cost: $0.149 $/kWh blended

Energy Savings Calculations:

Cold Beverage Vending Machine Electric usage 3,504 kWh1,4,7

Snack Vending Machine Electric usage 1,752 kWh2,5,7

Dual Vending Machine Electric Usage - kWh3,6,7

Total Vending Machine Electric Usage 5,256 kWh

Cold Beverage Vending Machine Electric usage 378 kWh8

Snack Vending Machine Electric usage 216 kWhDual Vending Machine Electric Usage 0 kWhTotal Vending Machine Electric Usage 594 kWh

Vending Machine Controls Usage Savings 4,662 kWhTotal cost savings 695$ Estimated Total Project Cost 560$ 9

Simple Payback 1 years

Assumptions1 1 Number of cold beverage vending machines2 1 Number of snack vending machines3 0 Number of dual snack/beverage vending machines4 400 Average wattage, typical of cold beverage machines based on prior project experience5 200 Average wattage, typical of snack machines based on prior project experience6 300 Average wattage, typical of dual snack/beverage machines based on prior project experience7 8760 Hours per year vending machine plugged in8 2160 Building Occupied Hours9 0.50 Vending Machine Traffic Factor (0.75 for High Traffic, 0.5 for Medium, 0.25 for low)

Vending machines generally operate 24/7 regardless of the actual usage. This measure proposes installing vending machine controls to reduce the total run time of these units. Cold beverage machines will cycle on for 15 minutes every two hours in order to keep beverages at a desired temperature. The result is a reduction in total electrical energy usage.

Existing

Proposed


Labor: 1.25ECM-7 Install Vending Misers - Cost Equipment: 1.12


Vending Miser 2 EA 200$ 15$ -$ 411$ 37$ -$ 448$ -$ -$ -$ -$

448$ Subtotal**Cost Estimates are for Energy Savings calculations only, do not use for procurement 112$ 25% Contingency

560$

REMARKS

Vendor Estimation

Total

TOTAL COSTDescription QTY UNIT UNIT COSTS SUBTOTAL COSTS


ECM: Replace urinals and flush valves with low flow

$7.50 $ / kGal3

201.5 Gal

30.125 Gal

$1,200 RS Means 2012$1,000 RS Means 2012

32.85 kGal / year2.74 kGal / year

30.11 kGal / year$226 / year

**Cost Estimates are for Energy Savings calculations only, do not use for procurement

Total cost of new urinals & valvesProposed Installation Cost of new urinal & valveProposed Material Cost of new urinal & valve

Description: This ECM evaluates the water savings associated with replacing/ upgrading urinals with 0.125 GPF urinals and or flush valves.

Proposed Gallons / FlushProposed Urinals to be Replaced

Average Gallons / Flush

E X I S T I N G C O N D I T I O N S

P R O P O S E D C O N D I T I O N S

Cost of Water / 1000 GallonsUrinals in Building to be replacedAverage Flushes / Urinal (per Day)

S A V I N G SCurrent Urinal Water UseProposed Urinal Water UseWater SavingsCost Savings


ECM: Replace toilets and flush valves with low flow

$7.50 $ / kGal12

83.5 Gal

121.28 Gal

122.64 kGal / year44.85 kGal / year77.79 kGal / year$583 / year

Current Toilet Water UseProposed Toilet Water UseWater SavingsCost Savings

Description: This ECM evaluates the water savings associated with repalcing/ upgrading toilets to 1.28 GPF fixtures and/or flush valves.

S A V I N G S

Proposed Gallons / FlushProposed Toilets to be Replaced



Cost of Water / 1000 GallonsToilets in BuildingAverage Flushes / Toilet (per Day)Average Gallons / Flush


ECM: Replace faucets with low flow

$7.50 $ / kGal18

6 # Uses30 seconds

2.0 gpm

180.5 gpm

0.15$ /kWh18

0.050 hrs230 days2.0 gpm0.5 gpm

8.33 Btu/gal/F35 F

95%3,413 btu/kWh

24.84 kGal / year6.21 kGal / year

18.63 kGal / year1,675 kWh$389 / year

Savings calculation formulas are taken from NJ Protocols document for Faucet

**Cost Estimates are for Energy Savings calculations only, do not use for procurement

Current Faucet Water UseProposed Faucet Water UseWater Savings

Cost SavingsHeating Savings

S A V I N G S

Proposed FlowrateProposed Faucets to be Replaced



Cost of Water / 1000 GallonsFaucets in BuildingAverage Uses / Faucet (per day)

Average FlowrateAverage Time of Use

Number of FaucetsHours per Day of UsageDays per Year of Facility Usage

Description; This ECM evaluates the water savings resulting from replacing/ upgrading faucets to 0.5 gallon per minute flow

Fuel Cost

Temperature Difference (Intake and Output)Water Heating Equipment EfficiencyConversion Factor

Average FlowrateProposed FlowrateHeat Content of Water

H E A T I N G S A V I N G S


Labor: 1.25ECM-8 Replace High Flow Plumbing Fixtures with Low Flow Plumbing Fixtures - Cost Equipment: 1.12


Low-Flow Urinal 3 EA 1,200$ 1,000$ -$ 3,697$ 3,738$ -$ 7,435$ Low-Flow Toilet 12 EA 1,400$ 1,000$ -$ 17,254$ 14,952$ -$ 32,206$ Low-Flow Faucet 18 EA 700$ 300$ -$ 12,940$ 6,728$ -$ 19,669$

-$ -$ -$ -$


74,137$

REMARKS

Vendor Estimate

Total

Vendor EstimateVendor Estimate

TOTAL COSTDescription QTY UNIT UNIT COSTS SUBTOTAL COSTS


New Jersey Pay For Performance Incentive Program

Note: The following calculation is based on the New Jersey Pay For Performance Incentive Program per April, 2012. Building must have a minimum average electric demand of 100 kW. This minimum is waived for buildings owned by localgovernements or non-profit organizations. At a minimum, all recommended measures were used for this calculation. To qualify for P4P incentives, the following P4P requirements must be met: - At least 15% source energy savings - No more than 50% savings from lighting measures - Scope includes more than one measure - Project has at least a 10% internal rate of return - At least 50% of the source energy savings must come from investor-owned electricity and/or natural gas (note: exemption for fuel conversions)

Total Building Area (Square Feet) 42,000 $0.05 $/sqftIs this audit funded by NJ BPU (Y/N) YesBoard of Public Utilites (BPU)

kWh ThermsExisting Cost (from utility) $125,339 $15,146

Existing Usage (from utility) 838,400 13,455Proposed Savings 256,430 3,050

Existing Total MMBtusProposed Savings MMBtus

% Energy ReductionProposed Annual Savings

$/kWh $/therm $/kWh $/therm $/kWh $/therm $/kWh $/thermIncentive #2 $0.09 $0.90 $0.005 $0.05 $0.11 $1.25 $0.11 $1.25Incentive #3 $0.09 $0.90 $0.005 $0.05 $0.11 $1.25 $0.11 $1.25

Elec Gas Total

Incentive #1 $0 $0 $5,000Incentive #2 $28,207 $3,813 $32,020Incentive #3 $28,207 $3,813 $32,020

Total All Incentives $56,415 $7,626 $69,040

Total Project Cost $432,909

Allowable Incentive

% Incentives #1 of Utility Cost* 3.6% $5,000% Incentives #2 of Project Cost** 7.4% $32,020% Incentives #3 of Project Cost** 7.4% $32,020

Total Eligible Incentives*** w/o Incentives w/ IncentivesProject Cost w/ Incentives 10.0 8.4

* Maximum allowable incentive is 50% of annual utility cost if not funded by NJ BPU, and %25 if it is.** Maximum allowable amount of Incentive #2 is 25% of total project cost.Maximum allowable amount of Incentive #3 is 25% of total project cost.*** Maximum allowable amount of Incentive #1 is $50,000 if not funded by NJ BPU, and $25,000 if it is. Maximum allowable amount of Incentive #2 & #3 is $1 million per gas account and $1 million per electric account; maximum 2 million per project

$363,869

Max Incentive

1,18028.1%

$43,216

Min (Savings = 15%) Increase (Savings > 15%) Achieved Incentive

Incentives $

Project Payback (years)$69,040

Incentive #1Audit is funded by NJ BPU

Annual Utilities

4,207

Energy Audit of Atrium ACCEPT

CHA Project No.28661

Budgetary Estimated Total New Jersey Payback Payback

Cost Maintenance Savings Incentive

(without

incentive) (with incentive)

Savings

$ kW kWh therms $ $ $ $ Years Years

$76,857 17.804 66,671 0 $10,683 0 $10,683 $1,890 7.2 7.0



(without


Savings


$16,740 0.0 10,532 0 $1,285 0 $1,285 $2,170 13.0 11.3



(without


Savings


$93,597 17.8 71,290 0 $11,246 0 $11,246 $4,060 8.3 8.0


*Incentive based on New Jersey Smart Start Prescriptive Lighting Measures

ECM-L1 Lighting Replacements




ECM-L3 Lighting Replacements with Occupancy Sensors

ECM-L2 Install Occupancy Sensors


7/25/2014 Page 1, Summary



ECM-L1 Lighting Replacements $11.93 $/kW

Area Description No. of Fixtures Standard Fixture Code Fixture Code

Watts per

Fixture kW/Space Exist Control Annual Hours Annual kWh Number of Fixtures Standard Fixture Code Fixture Code

Watts per

Fixture kW/Space

Retrofit

Control Annual Hours Annual kWh

Annual kWh

Saved Annual kW Saved Annual $ Saved Retrofit Cost

NJ Smart Start

Lighting Incentive

Simple Payback

With Out

Incentive Simple Payback

Field Code Unique description of the location - Room number/Room


No. of fixtures

before the retrofit

"Lighting Fixture Code" Example 2T

40 R F(U) = 2'x2' Troff 40 w Recess. Floor 2

lamps U shape

Code from Table of Standard

Fixture Wattages

Value from

Table of

Standard

Fixture

Wattages


No.)

Pre-inst.

control device

Estimated daily

hours for the

usage group

(kW/space) *

(Annual Hours)

No. of fixtures after

the retrofit

"Lighting Fixture Code" Example

2T 40 R F(U) = 2'x2' Troff 40 w

Recess. Floor 2 lamps U shape

Code from Table of

Standard Fixture

Wattages

Value from

Table of

Standard

Fixture

Wattages

(Watts/Fixt) *

(Number of

Fixtures)

Retrofit control

device

Estimated

annual hours

for the usage

group

(kW/space) *

(Annual

Hours)

(Original Annual

kWh) - (Retrofit

Annual kWh)

(Original Annual

kW) - (Retrofit

Annual kW)

(kWh Saved) *

($/kWh)

Cost for

renovations to

lighting system

Prescriptive

Lighting

Measures

Length of time

for renovations

cost to be

recovered

Length of time for

renovations cost to

be recovered

15LED Mechanical Room 03 2 S 32 C F 2 (ELE) F42LL 60 0.1 SW 8736 1,048 2 4 ft LED Tube 200732x2 30 0.1 SW 8,736 524 524 0.1 72.54$ 467.40$ $70 6.4 5.5

35LED Room 100 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 8760 3,154 4 T 59 R LED RTLED38 38 0.2 OCC 8,760 1,332 1,822 0.2 252.07$ 945.00$ $0 3.7 3.7

35LED Room 102 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 OCC 4368 786 2 T 59 R LED RTLED38 38 0.1 OCC 4,368 332 454 0.1 70.31$ 472.50$ $0 6.7 6.7




71 Room 108 4 I 60 I60/1 60 0.2 OCC 4368 1,048 4 CF 26 CFQ26/1-L 27 0.1 OCC 4,368 472 577 0.1 89.24$ 27.00$ $0 0.3 0.3

5LED Room 110 4 2T 32 R F 2 (u) (ELE) FU2LL 60 0.2 OCC 4368 1,048 4 2T XX R LED 2RTLED 25 0.1 OCC 4,368 437 612 0.1 94.65$ 810.00$ $200 8.6 6.4

35LED Room 103 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 4368 1,572 4 T 59 R LED RTLED38 38 0.2 OCC 4,368 664 909 0.2 140.62$ 945.00$ $0 6.7 6.7





25 Room 113 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.0 OCC 4368 122 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.0 OCC 4,368 122 - 0.0 -$ -$ $0 #DIV/0!

300 Room 113 4 ID85 ID85 85 0.3 SW 4368 1,485 4 ID85 ID85 85 0.3 SW 4,368 1,485 - 0.0 -$ -$ $0 #DIV/0!

25 Lobby 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.3 SW 8736 2,201 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.3 SW 8,736 2,201 - 0.0 -$ -$ $0 #DIV/0!

35LED Room 122 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296 6 T 59 R LED RTLED38 38 0.2 SW 2,400 547 749 0.3 136.02$ 1,417.50$ $0 10.4 10.4

35LED Room 122 9 T 32 R F 3 (ELE) F43ILL/2 90 0.8 SW 2400 1,944 9 T 59 R LED RTLED38 38 0.3 SW 2,400 821 1,123 0.5 204.03$ 2,126.25$ $0 10.4 10.4

71 Room 122 2 I 60 I60/1 60 0.1 SW 2400 288 2 CF 26 CFQ26/1-L 27 0.1 SW 2,400 130 158 0.1 28.77$ 13.50$ $0 0.5 0.5

35LED Room 124 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 SW 2400 648 3 T 59 R LED RTLED38 38 0.1 SW 2,400 274 374 0.2 68.01$ 708.75$ $0 10.4 10.4

35LED Room 126 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296 6 T 59 R LED RTLED38 38 0.2 SW 2,400 547 749 0.3 136.02$ 1,417.50$ $0 10.4 10.4

71 Room 126 5 I 60 I60/1 60 0.3 SW 2400 720 5 CF 26 CFQ26/1-L 27 0.1 SW 2,400 324 396 0.2 71.93$ 33.75$ $0 0.5 0.5

35LED Room 128 12 T 32 R F 3 (ELE) F43ILL/2 90 1.1 SW 2400 2,592 12 T 59 R LED RTLED38 38 0.5 SW 2,400 1,094 1,498 0.6 272.04$ 2,835.00$ $0 10.4 10.4

32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 SW 4,368 262 262 0.1 40.56$ 467.40$ $70 11.5 9.8

20LED Men's Room 3 S 28 P F 1 (ELE) F41ILL 31 0.1 SW 4368 406 3 4 ft LED Tube 200732x1 15 0.0 SW 4,368 197 210 0.0 32.45$ 435.60$ $105 13.4 10.2

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 SW 4,368 262 262 0.1 40.56$ 467.40$ $70 11.5 9.8

20LED Women's Room 3 S 28 P F 1 (ELE) F41ILL 31 0.1 SW 4368 406 3 4 ft LED Tube 200732x1 15 0.0 SW 4,368 197 210 0.0 32.45$ 435.60$ $105 13.4 10.2

25 Foyer 138 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.5 SW 8736 4,403 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.5 SW 8,736 4,403 - 0.0 -$ -$ $0 #DIV/0!

32LED Auditorium 144 14 1T 32 R F 2 (ELE) F42LL 60 0.8 SW 2400 2,016 14 4 ft LED Tube 200732x2 30 0.4 SW 2,400 1,008 1,008 0.4 183.10$ 3,271.80$ $490 17.9 15.2

25 Auditorium 144 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.0 SW 2400 2,419 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.0 SW 2,400 2,419 - 0.0 -$ -$ $0 #DIV/0!

25 Auditorium 144 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.4 SW 2400 941 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.4 SW 2,400 941 - 0.0 -$ -$ $0 #DIV/0!

35LED Multimedia Room 131 5 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,080 5 T 59 R LED RTLED38 38 0.2 SW 2,400 456 624 0.3 113.35$ 1,181.25$ $0 10.4 10.4

35LED Multimedia Room 131 10 T 32 R F 3 (ELE) F43ILL/2 90 0.9 SW 2400 2,160 10 T 59 R LED RTLED38 38 0.4 SW 2,400 912 1,248 0.5 226.70$ 2,362.50$ $0 10.4 10.4

35LED Computer Room 127 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 SW 2400 648 3 T 59 R LED RTLED38 38 0.1 SW 2,400 274 374 0.2 68.01$ 708.75$ $0 10.4 10.4


35LED Computer Room 125 11 T 32 R F 3 (ELE) F43ILL/2 90 1.0 SW 2400 2,376 11 T 59 R LED RTLED38 38 0.4 SW 2,400 1,003 1,373 0.6 249.37$ 2,598.75$ $0 10.4 10.4

35LED Computer Room 125 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296 6 T 59 R LED RTLED38 38 0.2 SW 2,400 547 749 0.3 136.02$ 1,417.50$ $0 10.4 10.4






35LED Computer Room 114 11 T 32 R F 3 (ELE) F43ILL/2 90 1.0 SW 2400 2,376 11 T 59 R LED RTLED38 38 0.4 SW 2,400 1,003 1,373 0.6 249.37$ 2,598.75$ $0 10.4 10.4
































35LED Room 240/242 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 SW 4368 1,572 4 T 59 R LED RTLED38 38 0.2 SW 4,368 664 909 0.2 140.62$ 945.00$ $0 6.7 6.7
























35LED Room 267/269 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 4368 1,572 4 T 59 R LED RTLED38 38 0.2 OCC 4,368 664 909 0.2 140.62$ 945.00$ $0 6.7 6.7





71 Room 258 12 I 60 I60/1 60 0.7 SW 8760 6,307 12 CF 26 CFQ26/1-L 27 0.3 SW 8,760 2,838 3,469 0.4 479.90$ 81.00$ $0 0.2 0.2

35LED Room 260 8 T 32 R F 3 (ELE) F43ILL/2 90 0.7 SW 4368 3,145 8 T 59 R LED RTLED38 38 0.3 SW 4,368 1,328 1,817 0.4 281.24$ 1,890.00$ $0 6.7 6.7

71 Room 262 6 I 60 I60/1 60 0.4 SW 4368 1,572 6 CF 26 CFQ26/1-L 27 0.2 SW 4,368 708 865 0.2 133.86$ 40.50$ $0 0.3 0.3

35LED Room 262 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 4368 2,359 6 T 59 R LED RTLED38 38 0.2 SW 4,368 996 1,363 0.3 210.93$ 1,417.50$ $0 6.7 6.7

300 Outside 2 ID85 ID85 85 0.2 SW 4368 743 2 ID85 ID85 85 0.2 SW 4,368 743 - 0.0 -$ -$ $0 #DIV/0!

231LED Outside 5 WP400MH1 MH400/1 458 2.3 SW 4368 10,003 5 WPLED2T78 WPLED2T78 91 0.5 SW 4,368 1,987 8,015 1.8 1,240.56$ 5,120.96$ $500 4.1 3.7

Total 424 33.0 125,227 424 4,061 15.1 58,556 66,671 17.8 $10,683 $76,857 $1,890

17.8 $2,549

66,671 $8,134

$10,683 7.2 7.0Total savings

COST & SAVINGS ANALYSISRETROFIT CONDITIONSEXISTING CONDITIONS

Demand Savings

kWh Savings

7/25/2014 Page 4, ECM-L1



ECM-L2 Install Occupancy Sensors $11.93 $/kW


Watts per


Watts per

Fixture kW/Space

Retrofit


Annual kWh


NJ Smart Start

Lighting

Incentive

Simple Payback

With Out




No. of fixtures

before the retrofit

Lighting Fixture Code Code from Table of Standard

Fixture Wattages

Value from

Table of

Standard

Fixture

Wattages


No.)

Pre-inst.

control device

Estimated annual

hours for the

usage group

(kW/space) *

(Annual Hours)


the retrofit


2T 40 R F(U) = 2'x2' Troff 40 w


Code from Table of

Standard Fixture

Wattages

Value from

Table of

Standard

Fixture

Wattages

(Watts/Fixt) *

(Number of

Fixtures)

Retrofit control

device

Estimated

annual hours

for the usage

group

(kW/space) *

(Annual Hours)

(Original Annual

kWh) - (Retrofit

Annual kWh)

(Original Annual

kW) - (Retrofit

Annual kW)

(kW Saved) *

($/kWh)

Cost for

renovations to

lighting system

Length of time

for renovations

cost to be

recovered

Length of time for

renovations cost to

be recovered

15LED Mechanical Room 03 2 S 32 C F 2 (ELE) F42LL 60 0.1 SW 8736 1,048.3 2 S 32 C F 2 (ELE) F42LL 60 0.1 C-OCC 8736 1,048.3 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

35LED Room 100 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 8760 3,153.6 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 NONE 8760 3,153.6 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

35LED Room 102 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 OCC 4368 786.2 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 NONE 4368 786.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!




71 Room 108 4 I 60 I60/1 60 0.2 OCC 4368 1,048.3 4 I 60 I60/1 60 0.2 NONE 4368 1,048.3 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

5LED Room 110 4 2T 32 R F 2 (u) (ELE) FU2LL 60 0.2 OCC 4368 1,048.3 4 2T 32 R F 2 (u) (ELE) FU2LL 60 0.2 NONE 4368 1,048.3 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

35LED Room 103 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 4368 1,572.5 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 C-OCC 3494.4 1,258.0 314.5 0.0 $38.37 $270.00 $35.00 7.0 6.1

35LED Room 105 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 OCC 4368 786.2 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 C-OCC 3494.4 629.0 157.2 0.0 $19.18 $270.00 $35.00 14.1 12.2




25 Room 113 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.0 OCC 4368 122.3 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.0 NONE 4368 122.3 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

300 Room 113 4 ID85 ID85 85 0.3 SW 4368 1,485.1 4 ID85 ID85 85 0.3 NONE 4368 1,485.1 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

25 Lobby 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.3 SW 8736 2,201.5 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.3 C-OCC 8736 2,201.5 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

35LED Room 122 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296.0 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 NONE 2400 1,296.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!


71 Room 122 2 I 60 I60/1 60 0.1 SW 2400 288.0 2 I 60 I60/1 60 0.1 NONE 2400 288.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

35LED Room 124 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 SW 2400 648.0 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 NONE 2400 648.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!


71 Room 126 5 I 60 I60/1 60 0.3 SW 2400 720.0 5 I 60 I60/1 60 0.3 NONE 2400 720.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!


32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524.2 2 1T 32 R F 2 (ELE) F42LL 60 0.1 NONE 4368 524.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

20LED Men's Room 3 S 28 P F 1 (ELE) F41ILL 31 0.1 SW 4368 406.2 3 S 28 P F 1 (ELE) F41ILL 31 0.1 NONE 4368 406.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524.2 2 1T 32 R F 2 (ELE) F42LL 60 0.1 NONE 4368 524.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

20LED Women's Room 3 S 28 P F 1 (ELE) F41ILL 31 0.1 SW 4368 406.2 3 S 28 P F 1 (ELE) F41ILL 31 0.1 NONE 4368 406.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

25 Foyer 138 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.5 SW 8736 4,402.9 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.5 NONE 8736 4,402.9 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

32LED Auditorium 144 14 1T 32 R F 2 (ELE) F42LL 60 0.8 SW 2400 2,016.0 14 1T 32 R F 2 (ELE) F42LL 60 0.8 NONE 2400 2,016.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

25 Auditorium 144 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.0 SW 2400 2,419.2 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.0 NONE 2400 2,419.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!

25 Auditorium 144 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.4 SW 2400 940.8 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.4 C-OCC 1680 658.6 282.2 0.0 $34.43 $270.00 $35.00 7.8 6.8

35LED Multimedia Room 131 5 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,080.0 5 T 32 R F 3 (ELE) F43ILL/2 90 0.5 C-OCC 1680 756.0 324.0 0.0 $39.53 $270.00 $35.00 6.8 5.9

35LED Multimedia Room 131 10 T 32 R F 3 (ELE) F43ILL/2 90 0.9 SW 2400 2,160.0 10 T 32 R F 3 (ELE) F43ILL/2 90 0.9 C-OCC 1680 1,512.0 648.0 0.0 $79.06 $270.00 $35.00 3.4 3.0

35LED Computer Room 127 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 SW 2400 648.0 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 NONE 2400 648.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!


35LED Computer Room 125 11 T 32 R F 3 (ELE) F43ILL/2 90 1.0 SW 2400 2,376.0 11 T 32 R F 3 (ELE) F43ILL/2 90 1.0 NONE 2400 2,376.0 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!










35LED Room 200 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 SW 4368 786.2 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 C-OCC 3494.4 629.0 157.2 0.0 $19.18 $270.00 $35.00 14.1 12.2














32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524.2 2 1T 32 R F 2 (ELE) F42LL 60 0.1 C-OCC 4368 524.2 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524.2 2 1T 32 R F 2 (ELE) F42LL 60 0.1 C-OCC 4368 524.2 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!














35LED Room 240/242 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 SW 4368 1,572.5 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 C-OCC 3494.4 1,258.0 314.5 0.0 $38.37 $270.00 $35.00 7.0 6.1




















32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524.2 2 1T 32 R F 2 (ELE) F42LL 60 0.1 C-OCC 4368 524.2 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524.2 2 1T 32 R F 2 (ELE) F42LL 60 0.1 NONE 4368 524.2 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!



35LED Room 267/269 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 4368 1,572.5 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 NONE 4368 1,572.5 0.0 0.0 $0.00 $0.00 $0.00 #DIV/0!





71 Room 258 12 I 60 I60/1 60 0.7 SW 8760 6,307.2 12 I 60 I60/1 60 0.7 C-OCC 8760 6,307.2 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

35LED Room 260 8 T 32 R F 3 (ELE) F43ILL/2 90 0.7 SW 4368 3,145.0 8 T 32 R F 3 (ELE) F43ILL/2 90 0.7 C-OCC 3494.4 2,516.0 629.0 0.0 $76.74 $270.00 $35.00 3.5 3.1

71 Room 262 6 I 60 I60/1 60 0.4 SW 4368 1,572.5 6 I 60 I60/1 60 0.4 C-OCC 3494.4 1,258.0 314.5 0.0 $38.37 $270.00 $35.00 7.0 6.1

35LED Room 262 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 4368 2,358.7 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 C-OCC 3494.4 1,887.0 471.7 0.0 $57.55 $270.00 $35.00 4.7 4.1

300 Outside 2 ID85 ID85 85 0.2 SW 4368 742.6 2 ID85 ID85 85 0.2 C-OCC 4368 742.6 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

231LED Outside 5 WP400MH1 MH400/1 458 2.3 SW 4368 10,002.7 5 WP400MH1 MH400/1 458 2.3 C-OCC 4368 10,002.7 0.0 0.0 $0.00 $270.00 $35.00 #DIV/0!

0 #N/A #VALUE! #VALUE! #N/A #VALUE! #VALUE! #VALUE!





Total 424 33.0 125,227.19 424.0 33.0 114695.3 10531.9 0.0 1284.9 16740.0 2170.0

0.0 $0

10,532 $1,285

$1,285 13.0 11.3

Demand Savings

kWh Savings

Total Savings

COST & SAVINGS ANALYSISEXISTING CONDITIONS RETROFIT CONDITIONS

7/25/2014 Page 5, ECM-L2



ECM-L2 Install Occupancy Sensors $11.93 $/kW


Watts per


Watts per

Fixture kW/Space

Retrofit


Annual kWh


NJ Smart Start

Lighting

Incentive

Simple Payback

With Out




No. of fixtures

before the retrofit


Fixture Wattages

Value from

Table of

Standard

Fixture

Wattages


No.)

Pre-inst.

control device

Estimated annual

hours for the

usage group

(kW/space) *

(Annual Hours)


the retrofit


2T 40 R F(U) = 2'x2' Troff 40 w


Code from Table of

Standard Fixture

Wattages

Value from

Table of

Standard

Fixture

Wattages

(Watts/Fixt) *

(Number of

Fixtures)

Retrofit control

device

Estimated

annual hours

for the usage

group

(kW/space) *

(Annual Hours)

(Original Annual

kWh) - (Retrofit

Annual kWh)

(Original Annual

kW) - (Retrofit

Annual kW)

(kW Saved) *

($/kWh)

Cost for

renovations to

lighting system

Length of time

for renovations

cost to be

recovered

Length of time for

renovations cost to

be recovered

COST & SAVINGS ANALYSISEXISTING CONDITIONS RETROFIT CONDITIONS

7/25/2014 Page 6, ECM-L2



ECM-L3 Lighting Replacements with Occupancy Sensors $11.93 $/kW


Watts per


Watts per

Fixture kW/Space

Retrofit


Annual kWh


NJ Smart Start

Lighting

Incentive

Simple Payback

With Out




No. of fixtures

before the retrofit


Fixture Wattages

Value from

Table of

Standard

Fixture

Wattages


No.)

Pre-inst.

control device

Estimated daily

hours for the

usage group

(kW/space) *

(Annual Hours)


the retrofit

Lighting Fixture Code Code from Table of

Standard Fixture

Wattages

Value from

Table of

Standard

Fixture

Wattages

(Watts/Fixt) *

(Number of

Fixtures)

Retrofit control

device

Estimated

annual hours

for the usage

group

(kW/space) *

(Annual

Hours)

(Original Annual

kWh) - (Retrofit

Annual kWh)

(Original Annual

kW) - (Retrofit

Annual kW)

(kWh Saved) *

($/kWh)

Cost for

renovations to

lighting system

Prescriptive

Lighting

Measures

Length of time

for renovations

cost to be

recovered

Length of time for

renovations cost to

be recovered

15LED Mechanical Room 03 2 S 32 C F 2 (ELE) F42LL 60 0.1 SW 8736 1,048 2 4 ft LED Tube 200732x2 30 0.1 C-OCC 8,736 524 524 0.1 72.54$ 737.40$ 105$ 10.2 8.7

35LED Room 100 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 8760 3,154 4 T 59 R LED RTLED38 38 0.2 NONE 8,760 1,332 1,822 0.2 252.07$ 945.00$ -$ 3.7 3.7

35LED Room 102 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 OCC 4368 786 2 T 59 R LED RTLED38 38 0.1 NONE 4,368 332 454 0.1 70.31$ 472.50$ -$ 6.7 6.7




71 Room 108 4 I 60 I60/1 60 0.2 OCC 4368 1,048 4 CF 26 CFQ26/1-L 27 0.1 NONE 4,368 472 577 0.1 89.24$ 27.00$ -$ 0.3 0.3

5LED Room 110 4 2T 32 R F 2 (u) (ELE) FU2LL 60 0.2 OCC 4368 1,048 4 2T XX R LED 2RTLED 25 0.1 NONE 4,368 437 612 0.1 94.65$ 810.00$ 200$ 8.6 6.4

35LED Room 103 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 4368 1,572 4 T 59 R LED RTLED38 38 0.2 C-OCC 3,494 531 1,041 0.2 156.82$ 1,215.00$ 35$ 7.7 7.5

35LED Room 105 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 OCC 4368 786 2 T 59 R LED RTLED38 38 0.1 C-OCC 3,494 266 521 0.1 78.41$ 742.50$ 35$ 9.5 9.0




25 Room 113 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.0 OCC 4368 122 1 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.0 NONE 4,368 122 - 0.0 -$ -$ -$

300 Room 113 4 ID85 ID85 85 0.3 SW 4368 1,485 4 ID85 ID85 85 0.3 NONE 4,368 1,485 - 0.0 -$ -$ -$

25 Lobby 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.3 SW 8736 2,201 9 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.3 C-OCC 8,736 2,201 - 0.0 -$ 270.00$ 35$

35LED Room 122 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296 6 T 59 R LED RTLED38 38 0.2 NONE 2,400 547 749 0.3 136.02$ 1,417.50$ -$ 10.4 10.4

35LED Room 122 9 T 32 R F 3 (ELE) F43ILL/2 90 0.8 SW 2400 1,944 9 T 59 R LED RTLED38 38 0.3 NONE 2,400 821 1,123 0.5 204.03$ 2,126.25$ -$ 10.4 10.4

71 Room 122 2 I 60 I60/1 60 0.1 SW 2400 288 2 CF 26 CFQ26/1-L 27 0.1 NONE 2,400 130 158 0.1 28.77$ 13.50$ -$ 0.5 0.5

35LED Room 124 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 SW 2400 648 3 T 59 R LED RTLED38 38 0.1 NONE 2,400 274 374 0.2 68.01$ 708.75$ -$ 10.4 10.4

35LED Room 126 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296 6 T 59 R LED RTLED38 38 0.2 NONE 2,400 547 749 0.3 136.02$ 1,417.50$ -$ 10.4 10.4

71 Room 126 5 I 60 I60/1 60 0.3 SW 2400 720 5 CF 26 CFQ26/1-L 27 0.1 NONE 2,400 324 396 0.2 71.93$ 33.75$ -$ 0.5 0.5

35LED Room 128 12 T 32 R F 3 (ELE) F43ILL/2 90 1.1 SW 2400 2,592 12 T 59 R LED RTLED38 38 0.5 NONE 2,400 1,094 1,498 0.6 272.04$ 2,835.00$ -$ 10.4 10.4

32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 NONE 4,368 262 262 0.1 40.56$ 467.40$ 70$ 11.5 9.8

20LED Men's Room 3 S 28 P F 1 (ELE) F41ILL 31 0.1 SW 4368 406 3 4 ft LED Tube 200732x1 15 0.0 NONE 4,368 197 210 0.0 32.45$ 435.60$ 105$ 13.4 10.2

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 NONE 4,368 262 262 0.1 40.56$ 467.40$ 70$ 11.5 9.8

20LED Women's Room 3 S 28 P F 1 (ELE) F41ILL 31 0.1 SW 4368 406 3 4 ft LED Tube 200732x1 15 0.0 NONE 4,368 197 210 0.0 32.45$ 435.60$ 105$ 13.4 10.2

25 Foyer 138 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.5 SW 8736 4,403 18 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.5 NONE 8,736 4,403 - 0.0 -$ -$ -$

32LED Auditorium 144 14 1T 32 R F 2 (ELE) F42LL 60 0.8 SW 2400 2,016 14 4 ft LED Tube 200732x2 30 0.4 NONE 2,400 1,008 1,008 0.4 183.10$ 3,271.80$ 490$ 17.9 15.2

25 Auditorium 144 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.0 SW 2400 2,419 36 R 13 C CF 2 (ELE) CFQ13/2-L 28 1.0 NONE 2,400 2,419 - 0.0 -$ -$ -$

25 Auditorium 144 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.4 SW 2400 941 14 R 13 C CF 2 (ELE) CFQ13/2-L 28 0.4 C-OCC 1,680 659 282 0.0 34.43$ 270.00$ 35$ 7.8 6.8

35LED Multimedia Room 131 5 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,080 5 T 59 R LED RTLED38 38 0.2 C-OCC 1,680 319 761 0.3 130.04$ 1,451.25$ 35$ 11.2 10.9

35LED Multimedia Room 131 10 T 32 R F 3 (ELE) F43ILL/2 90 0.9 SW 2400 2,160 10 T 59 R LED RTLED38 38 0.4 C-OCC 1,680 638 1,522 0.5 260.08$ 2,632.50$ 35$ 10.1 10.0

35LED Computer Room 127 3 T 32 R F 3 (ELE) F43ILL/2 90 0.3 SW 2400 648 3 T 59 R LED RTLED38 38 0.1 NONE 2,400 274 374 0.2 68.01$ 708.75$ -$ 10.4 10.4


35LED Computer Room 125 11 T 32 R F 3 (ELE) F43ILL/2 90 1.0 SW 2400 2,376 11 T 59 R LED RTLED38 38 0.4 NONE 2,400 1,003 1,373 0.6 249.37$ 2,598.75$ -$ 10.4 10.4

35LED Computer Room 125 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 2400 1,296 6 T 59 R LED RTLED38 38 0.2 NONE 2,400 547 749 0.3 136.02$ 1,417.50$ -$ 10.4 10.4






35LED Computer Room 114 11 T 32 R F 3 (ELE) F43ILL/2 90 1.0 SW 2400 2,376 11 T 59 R LED RTLED38 38 0.4 NONE 2,400 1,003 1,373 0.6 249.37$ 2,598.75$ -$ 10.4 10.4



35LED Room 200 2 T 32 R F 3 (ELE) F43ILL/2 90 0.2 SW 4368 786 2 T 59 R LED RTLED38 38 0.1 C-OCC 3,494 266 521 0.1 78.41$ 742.50$ 35$ 9.5 9.0














32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 C-OCC 4,368 262 262 0.1 40.56$ 737.40$ 105$ 18.2 15.6

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 C-OCC 4,368 262 262 0.1 40.56$ 737.40$ 105$ 18.2 15.6














35LED Room 240/242 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 SW 4368 1,572 4 T 59 R LED RTLED38 38 0.2 C-OCC 3,494 531 1,041 0.2 156.82$ 1,215.00$ 35$ 7.7 7.5




















32LED Men's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 C-OCC 4,368 262 262 0.1 40.56$ 737.40$ 105$ 18.2 15.6

32LED Women's Room 2 1T 32 R F 2 (ELE) F42LL 60 0.1 SW 4368 524 2 4 ft LED Tube 200732x2 30 0.1 NONE 4,368 262 262 0.1 40.56$ 467.40$ 70$ 11.5 9.8



35LED Room 267/269 4 T 32 R F 3 (ELE) F43ILL/2 90 0.4 OCC 4368 1,572 4 T 59 R LED RTLED38 38 0.2 NONE 4,368 664 909 0.2 140.62$ 945.00$ -$ 6.7 6.7





71 Room 258 12 I 60 I60/1 60 0.7 SW 8760 6,307 12 CF 26 CFQ26/1-L 27 0.3 C-OCC 8,760 2,838 3,469 0.4 479.90$ 351.00$ 35$ 0.7 0.7

35LED Room 260 8 T 32 R F 3 (ELE) F43ILL/2 90 0.7 SW 4368 3,145 8 T 59 R LED RTLED38 38 0.3 C-OCC 3,494 1,062 2,083 0.4 313.64$ 2,160.00$ 35$ 6.9 6.8

71 Room 262 6 I 60 I60/1 60 0.4 SW 4368 1,572 6 CF 26 CFQ26/1-L 27 0.2 C-OCC 3,494 566 1,006 0.2 151.12$ 310.50$ 35$ 2.1 1.8

35LED Room 262 6 T 32 R F 3 (ELE) F43ILL/2 90 0.5 SW 4368 2,359 6 T 59 R LED RTLED38 38 0.2 C-OCC 3,494 797 1,562 0.3 235.23$ 1,687.50$ 35$ 7.2 7.0

300 Outside 2 ID85 ID85 85 0.2 SW 4368 743 2 ID85 ID85 85 0.2 C-OCC 4,368 743 - 0.0 -$ 270.00$ 35$

231LED Outside 5 WP400MH1 MH400/1 458 2.3 SW 4368 10,003 5 WPLED2T78 WPLED2T78 91 0.5 C-OCC 4,368 1,987 8,015 1.8 1,240.56$ 5,390.96$ 535$ 4.3 3.9

#N/A #VALUE!

#N/A #VALUE!

#N/A #VALUE!

#N/A #VALUE!

#N/A #VALUE!

S Total 0 33.0 125,227 424 15.1 53,937 17.8 11,246 93,597 $4,060

S 17.8 $2,549

S 71,290 $8,697

S $11,246 8.3 8.0

Demand Savings

kWh Savings

Total Savings

EXISTING CONDITIONS RETROFIT CONDITIONS COST & SAVINGS ANALYSIS

7/25/2014 Page 7, ECM-L3

APPENDIX F

Photos

ECM-1 Install Door Seals

Existing Side Doors

ECM-2 Install Destratification Fans

Existing Atrium

ECM-3 Replace the Two Old RTUs with New RTUs

Existing RTU

ECM-4 Re-Activate the Dual Temp Pump Motor VFDs

Existing VFDs

ECM-5 Install a VFD on the Auditorium Air Handling Unit

Existing AHU for Auditorium

ECM-6 Install Occupancy Sensors to Control Individual Fan Coil Units

Existing Fan Coil Unit

ECM-7 Install Vending Misers

Existing Vending Machines

ECM-8 Replace High Flow Plumbing Fixtures with Low Flow Plumbing Fixtures

Existing Plumbing Fixtures

ECM-L1 Lighting Replacement / Upgrades

Existing Lights

ECM-L2 Install Lighting Controls (Occupancy Sensors)

No Pictures Available

ECM-L3 Lighting Replacements with Controls (Occupancy Sensors)

See ECM L-1 and L-2

APPENDIX G

EPA Benchmarking Report

ENERGY STAR® Statement of EnergyPerformance

N/AENERGY STAR®

Score1

Atrium

Primary Property Function: College/UniversityGross Floor Area (ft²): 42,000Built: 1996

For Year Ending: January 31, 2014Date Generated: July 18, 2014

1. The ENERGY STAR score is a 1-100 assessment of a building’s energy efficiency as compared with similar buildings nationwide, adjusting forclimate and business activity.

Property & Contact Information

Property AddressAtrium300 Pompton RoadWayne, New Jersey 07470

Property Owner__________________,(____)____-______

Primary Contact____ ________,(____)____-________________________

Property ID: 4113140

Energy Consumption and Energy Use Intensity (EUI)

Site EUI100.1 kBtu/ft²

Annual Energy by FuelElectric - Grid (kBtu) 2,860,621 (68%)Natural Gas (kBtu) 1,345,502 (32%)

National Median ComparisonNational Median Site EUI (kBtu/ft²) 106.3National Median Source EUI (kBtu/ft²) 262.6% Diff from National Median Source EUI -6%

Source EUI247.5 kBtu/ft²

Annual EmissionsGreenhouse Gas Emissions (Metric TonsCO2e/year)

434

Signature & Stamp of Verifying Professional

I ___________________ (Name) verify that the above information is true and correct to the best of my knowledge.

Signature: _______________________Date: ___________

Licensed Professional

____ ________,(____)____-________________________

Professional Engineer Stamp(if applicable)

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