Authors: Mahdiyeh Zafaranchi, Ethan S. Cantor, William T. Riddell, Jess W. Everett

Abstract:

The New Jersey Department of Military and Veteran’s Affairs (NJ DMAVA) operates over 50 facilities throughout the state of New Jersey, US. NJ DMAVA is under a mandate to move toward decarbonization, which will eventually include eliminating the use of natural gas and other fossil fuels for heating. At the same time, the organization requires increased resiliency regarding electric grid disruption. These competing goals necessitate adopting the use of on-site renewables such as photovoltaic and geothermal power, as well as implementing power control strategies through microgrids. Planning for these changes requires a detailed understanding of current and future electricity use on yearly, monthly, and shorter time scales, as well as a breakdown of consumption by heating, ventilation, and air conditioning (HVAC) equipment. This paper discusses case studies of two buildings that were simulated using the QUick Energy Simulation Tool (eQUEST). Both buildings use electricity from the grid and photovoltaics. One building also uses natural gas. While electricity use data are available in hourly intervals and natural gas data are available in monthly intervals, the simulations were developed using monthly and yearly totals. This approach was chosen to reflect the information available for most NJ DMAVA facilities. Once completed, simulation results are compared to metrics recommended by several organizations to validate energy use simulations. In addition to yearly and monthly totals, the simulated peak demands are compared to actual monthly peak demand values. The simulations resulted in monthly peak demand values that were within 30% of the measured values. These benchmarks will help to assess future energy planning efforts for NJ DMAVA.

Keywords: Building Energy Modeling, eQUEST, peak demand, smart meters.

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References:

[1] Hassan, J., et al., Building energy consumption in Malaysia: An overview. Jurnal Teknologi, 2014. 70(7).
[2] Change, I.P.O.C., Climate change 2014: synthesis report. Contribution of working groups I. II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (Core Writing Team, RK Pachauri and LA Meyer (eds.)). IPCC, Geneva, Switzerland, 2014. 151.
[3] Liu, J., et al., Quantitative evaluation of the building energy performance based on short-term energy predictions. Energy, 2021. 223: p. 120065.
[4] Fan, J.-L., Y.-J. Zhang, and B. Wang, The impact of urbanization on residential energy consumption in China: An aggregated and disaggregated analysis. Renewable and Sustainable Energy Reviews, 2017. 75: p. 220-233.
[5] Kathirgamanathan, A., et al., Data-driven predictive control for unlocking building energy flexibility: A review. Renewable and Sustainable Energy Reviews, 2021. 135: p. 110120.
[6] Zafaranchi, M. and H. Sözer, Comparing energy profiles of different building types by determining their sensitivities. Architectural Engineering and Design Management, 2023: p. 1-22.
[7] Zaferanchi, M. and H. Sozer, Effectiveness of interventions to convert the energy consumption of an educational building to zero energy. International Journal of Building Pathology and Adaptation, 2022.
[8] Zafaranchi, M., Simulation and Analysis of Passive Parameters of Building in eQuest: A Case Study in Istanbul, Turkey. International Journal of Energy and Environmental Engineering, 2020. 14(10): p. 253-259.
[9] Gassar, A.A.A. and S.H. Cha, Energy prediction techniques for large-scale buildings towards a sustainable built environment: A review. Energy and Buildings, 2020. 224: p. 110238.
[10] Li, X. and J. Wen, Review of building energy modeling for control and operation. Renewable and Sustainable Energy Reviews, 2014. 37: p. 517-537.
[11] Amara, F., et al., Comparison and simulation of building thermal models for effective energy management. Smart Grid and renewable energy, 2015. 6(04): p. 95.
[12] Cuerda, E., et al., Understanding the performance gap in energy retrofitting: Measured input data for adjusting building simulation models. Energy and Buildings, 2020. 209: p. 109688.
[13] Chong, A., Y. Gu, and H. Jia, Calibrating building energy simulation models: A review of the basics to guide future work. Energy and Buildings, 2021. 253: p. 111533.
[14] Henze, G.P., et al., An energy signal tool for decision support in building energy systems. Applied energy, 2015. 138: p. 51-70.
[15] Kim, D.-W. and C.-S. Park, Difficulties and limitations in performance simulation of a double skin façade with EnergyPlus. Energy and Buildings, 2011. 43(12): p. 3635-3645.
[16] Baig, A.A. and A.S. Fung, A case study in energy modeling of an energy efficient building with gas driven absorption heat pump system in eQUEST. Ryerson University Toronto, Ontario. Department of Mechanical and Industrial Engineering, 2015.
[17] Lamichhane, S., An eQUEST Based Building Energy Modeling Analysis for Energy Efficiency of Buildings. 2021: West Virginia University.
[18] Lamagna, M., et al. Hourly energy profile determination technique from monthly energy bills. in Building Simulation. 2020. Springer.
[19] Ke, M.-T., C.-H. Yeh, and J.-T. Jian, Analysis of building energy consumption parameters and energy savings measurement and verification by applying eQUEST software. Energy and Buildings, 2013. 61: p. 100-107.
[20] Mostafavi, N., M. Farzinmoghadam, and S. Hoque, Envelope retrofit analysis using eQUEST, IESVE Revit Plug-in and Green Building Studio: a university dormitory case study. International Journal of Sustainable Energy, 2015. 34(9): p. 594-613.
[21] Ramos Ruiz, G. and C. Fernandez Bandera, Validation of calibrated energy models: Common errors. Energies, 2017. 10(10): p. 1587.
[22] Warty, A. and S. Mehendale, Energy Modeling and Energy Efficiency Opportunities for a Public Library Building in the Upper Peninsula of Michigan. 2021.
[23] Xing, J., P. Ren, and J. Ling, Analysis of energy efficiency retrofit scheme for hotel buildings using eQuest software: A case study from Tianjin, China. Energy and Buildings, 2015. 87: p. 14-24.
[24] Kavanaugh, S.P. and K.D. Rafferty, Geothermal heating and cooling: design of ground-source heat pump systems. EBSCO eBooks, 2014.
[25] (DOE2), D.O.E. the QUick Energy Simulation Tool. https://doe2.com/equest/ Online available on 12.27.2022.
[26] EnergyPlus is developed in collaboration with NREL, various DOE National Laboratories, academic institutions, and private firms. online available on 12.27.2022.
[27] Rallapalli, H.S., A comparison of EnergyPlus and eQUEST whole building energy simulation results for a medium sized office building. 2010, Arizona State University.
[28] Zerroug, A. and E. Dzelzitis. Analysis of results of energy consumption simulation with eQUEST and energy plus. in International Conference Civil Engineering. 2015.
[29] Zhu, D., et al. A detailed loads comparison of three building energy modeling programs: EnergyPlus, DeST and DOE-2.1 E. in Building Simulation. 2013. Springer.
[30] Hirsch, J.J., Overview of DOE-2.2, Simulation Research Group Lawrence Berkeley National Laboratory University of California. 1998.
[31] Autodesk. Building Performance Analysis Raised to the Power of the Cloud. 2022 (cited 2022 November).
[32] Hirsch, J., et al., Building Energy Simulation Group. Energy & Environment Division. Annual Report 1981, 1982.
[33] Autodesk, G.B.S.-. Building Performance Analysis Raised to the Power of the Cloud. online available on november of 2022.
[34] Climate and monthly weather forecast Lawrenceville, NJ. 12.12.2022].
[35] Program, N.I.S., New Jersey Department of Military and Veterans Affairs. 2006. accessed on 24 April 2023.
[36] Coakley, D., P. Raftery, and M. Keane, A review of methods to match building energy simulation models to measured data. Renewable and sustainable energy reviews, 2014. 37: p. 123-141.
[37] Zirnhelt, H., Using calibrated simulation to quantify the energy savings from residential passive solar design in Canada. Toronto, Canada, 2013.
[38] Schranzhofer, H., et al. Validation of a TRNSYS simulation model for PCM energy storages and PCM wall construction elements. in Ecostock conference. 2006.
[39] Pal, S., B. Roy, and S. Neogi, Heat transfer modelling on windows and glazing under the exposure of solar radiation. Energy and Buildings, 2009. 41(6): p. 654-661.
[40] Reddy, T.A., Applied data analysis and modeling for energy engineers and scientists. 2011: Springer Science & Business Media.
[41] Bou-Saada, T.E. and J.S. Haberl, An Improved Procedure for Developing CALD3RATED Hourly Simulation Models. 1995.
[42] ASHRAE, Measurement of energy, demand, and water savings. ASHRAE guidel, 2014. 4: p. 1-150.
[43] Guideline, A., Guideline 14-2002, measurement of energy and demand savings. American Society of Heating, Ventilating, and Air Conditioning Engineers, Atlanta, Georgia, 2002.
[44] DOE, U., M&V guidelines: measurement and verification for federal energy projects version 3.0. US Department of Energy, 2008.
[45] Cowan, J., International performance measurement and verification protocol: Concepts and Options for Determining Energy and Water Savings-Vol. I. International Performance Measurement & Verification Protocol, 2002. 1.
[46] Reddy, T.A., I. Maor, and C. Panjapornpon, Calibrating detailed building energy simulation programs with measured data—part II: application to three case study office buildings (RP-1051). Hvac&r Research, 2007. 13(2): p. 243-265.
[47] Fabrizio, E. and V. Monetti, Methodologies and advancements in the calibration of building energy models. Energies, 2015. 8(4): p. 2548-2574.
[48] Subcommittee, E.I.N.C., International Performance Measurement & Verification Protocol: Concepts and Option for Determining Energy Savings in New Construction. Efficiency Valuation Organization (EVO): Washington, DC, USA, 2003. 3.
[49] FEMP, M., Guidelines: Measurement and Verification for Federal Energy Projects, Version 3.0. Energy Efficiency and Renewable Energy, 2008.
[50] Haberl, J.S., D.E. Claridge, and C. Culp, ASHRAE's Guideline 14-2002 for Measurement of Energy and Demand Savings: How to Determine what was really saved by the retrofit. 2005.