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[1] Arriaga, M., Canizares, C.A. & Kazerani, M., Northern lights: Access to electricity in Canada’s Northern and remote communities. IEEE Power and Energy Magazine, 12(4), pp. 50–59, July 2014.
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[4] Number, S., Chadwick, B. & Mullins, J., Sustainable forward operating bases. Strategic Environmental Research and Development Program (SERDP). Noblis, 2015.
[5] Eady, D.S., Siegel, S.B., Bell, R.S. & Dicke, S.h., Sustain the Mission Project: Casualty Factors for Fuel and Water Resupply Convoys. Army Environmental Policy Institute (AEPI), Arlington, vA, 2009.
[6] Saheb-Koussa, D., haddadi, M. & Belhamel, M., Economic and technical study of a hybrid system (wind-photovoltaic-diesel) for rural electrification in Algeria. Applied Energy, 86(7–8), pp. 1024–1030, 2009.
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[10] Perera, A.T.D., Attalage, R.A., Perera, K. & Dassanayake, v., Designing standalone hybrid energy systems minimizing initial investment, life cycle cost and pollutant emission. Energy, 54, pp. 220–230, 2013.
[11] International Energy Agency, Renewables 2017: A New Era for Solar Power, 2017.
[12] Chester, D.J., Wagner, T.J. & Dudis, D., 36% reduction in FOB generator fuel use with optimized energy storage. Marine Corps Gazette, 103(3), 2019.
[13] Wagner, T., Lang, E., Assink, W. & Dudis, D., Photovoltaic system optimization for an austere location using time-series data. Proceedings of the IEEE 45th Photovoltaic Specialists Conference, pp. 0–4, 2018.
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[16] Keith, M.v., Moheisen, R.M., Shaaban, A.h. & Salavani, R., Photovoltaic (PV) Integrated Power Shelter Systems for Basic Expeditionary Airfield Resources (BEAR), 2012.
[17] USAF, 635th Materiel Maintenance Group. Definitive Guide to BEAR Base Assets, 2017.
[18] USAF, Air Force Tactics, Techniques, and Procedures AFTTP3-32.34V5 - Contingency Electrical Power Production and Distribution Systems, 2017.
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Open Access
Research article

A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement

Nathan Thomsen,
Torrey Wagner,
Andrew Hoisington,
Steven Schuldt
Department of Systems Engineering and Management, Air Force Institute of Technology, Wright-Patterson Air Force Base, USA.
International Journal of Energy Production and Management
|
Volume 4, Issue 1, 2019
|
Pages 28-39
Received: N/A,
Revised: N/A,
Accepted: N/A,
Available online: N/A
View Full Article|Download PDF

Abstract:

Remote locations such as disaster relief camps, isolated arctic communities, and military forward operating bases are disconnected from traditional power grids forcing them to rely on diesel generators with a total installed capacity of 10,000 MW worldwide. The generators require a constant resupply of fuel, resulting in increased operating costs, negative environmental impacts, and challenging fuel logistics. To enhance remote site sustainability, planners can develop stand-alone photovoltaic-battery systems to replace existing prime power generators. This paper presents the development of a novel cost-performance model capable of optimizing solar array and Li-ion battery storage size by generating tradeoffs between minimizing initial system cost and maximizing power reliability. A case study for the replacement of an 800 kW generator, the US Air Force’s standard for prime power at deployed locations, was analyzed to demonstrate the model and its capabilities. A MATLAB model, simulating one year of solar data, was used to generate an optimized solution to minimize initial cost while providing over 99% reliability. Replacing a single diesel generator would result in a savings of 1.9 million liters of fuel, eliminating 100 fuel tanker truck deliveries annually. The distinctive capabilities of this model enable designers to enhance environmental, economic, and operational sustainability of remote locations by creating energy self-sufficient sites, which can operate indefinitely without the need for resupply.

Keywords: battery, diesel generator, energy storage, isolated sites, optimization, photovoltaic, renewable energy, solar array, stand-alone
Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

References
[1] Arriaga, M., Canizares, C.A. & Kazerani, M., Northern lights: Access to electricity in Canada’s Northern and remote communities. IEEE Power and Energy Magazine, 12(4), pp. 50–59, July 2014.
[2] Schill, D., Improving energy security for air force installations. RAND Corp Santa Monica, CA, 2015.
[3] United States Government Accountability Office (US GAO), GAO-09-300 Defense Management: DOD Needs to Increase Attention on Fuel Demand Management at Forward-Deployed Locations. 2009.
[4] Number, S., Chadwick, B. & Mullins, J., Sustainable forward operating bases. Strategic Environmental Research and Development Program (SERDP). Noblis, 2015.
[5] Eady, D.S., Siegel, S.B., Bell, R.S. & Dicke, S.h., Sustain the Mission Project: Casualty Factors for Fuel and Water Resupply Convoys. Army Environmental Policy Institute (AEPI), Arlington, vA, 2009.
[6] Saheb-Koussa, D., haddadi, M. & Belhamel, M., Economic and technical study of a hybrid system (wind-photovoltaic-diesel) for rural electrification in Algeria. Applied Energy, 86(7–8), pp. 1024–1030, 2009.
[7] Askarzadeh, A., Distribution generation by photovoltaic and diesel generator sys- tems: Energy management and size optimization by a new approach for a stand-alone application. Energy, 122(1), pp. 542–551, March 2017.
[8] Akinyele, D., Analysis of photovoltaic mini-grid systems for remote locations: A techno- economic approach. International Journal of Energy Research, 42(3), pp. 1363–1380, March 2018.
[9] Yilmaz, S., Ozcalik, h.R., Kesler, S., Dincer, F. & Yelmen, B., The analysis of different Pv power systems for the determination of optimal Pv panels and system installation- A case study in Kahramanmaras, Turkey. Renewable and Sustainable Energy Reviews, 52, pp. 1015–1024, December 2015.
[10] Perera, A.T.D., Attalage, R.A., Perera, K. & Dassanayake, v., Designing standalone hybrid energy systems minimizing initial investment, life cycle cost and pollutant emission. Energy, 54, pp. 220–230, 2013.
[11] International Energy Agency, Renewables 2017: A New Era for Solar Power, 2017.
[12] Chester, D.J., Wagner, T.J. & Dudis, D., 36% reduction in FOB generator fuel use with optimized energy storage. Marine Corps Gazette, 103(3), 2019.
[13] Wagner, T., Lang, E., Assink, W. & Dudis, D., Photovoltaic system optimization for an austere location using time-series data. Proceedings of the IEEE 45th Photovoltaic Specialists Conference, pp. 0–4, 2018.
[14] McCaskey, N.C., Renewable Energy Systems for Forward Operating Bases: A Simulations-Based Optimization Approach, Colorado State University, 2010.
[15] Kosowatz, J., Military Looks to Renewables in Battle Zones. ASME Online. https:// asme.org/engineering-topics/articles/energy/military-looks-renewables-battle-zones (accessed 14 October 2018).
[16] Keith, M.v., Moheisen, R.M., Shaaban, A.h. & Salavani, R., Photovoltaic (PV) Integrated Power Shelter Systems for Basic Expeditionary Airfield Resources (BEAR), 2012.
[17] USAF, 635th Materiel Maintenance Group. Definitive Guide to BEAR Base Assets, 2017.
[18] USAF, Air Force Tactics, Techniques, and Procedures AFTTP3-32.34V5 - Contingency Electrical Power Production and Distribution Systems, 2017.
[19] U.S. Bureau of Labor Statistics, “CPI (Consumer Price Index).” Online https://bls.gov/ cpi/home.htm (accessed 18 November 2018).
[20] Diorio, N., Dobos, A. & Janzou, S., Economic Analysis Case Studies of Battery Energy Storage with SAM. National Renewable Energy Laboratory, 2015.
Cite this:
APA Style
IEEE Style
BibTex Style
MLA Style
Chicago Style
GB-T-7714-2015
Thomsen, N., Wagner, T., Hoisington, A., & Schuldt, S. (2019). A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement. Int. J. Energy Prod. Manag., 4(1), 28-39. https://doi.org/10.2495/EQ-V4-N1-28-39
N. Thomsen, T. Wagner, A. Hoisington, and S. Schuldt, "A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement," Int. J. Energy Prod. Manag., vol. 4, no. 1, pp. 28-39, 2019. https://doi.org/10.2495/EQ-V4-N1-28-39
@research-article{Thomsen2019ASP,
title={A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement},
author={Nathan Thomsen and Torrey Wagner and Andrew Hoisington and Steven Schuldt},
journal={International Journal of Energy Production and Management},
year={2019},
page={28-39},
doi={https://doi.org/10.2495/EQ-V4-N1-28-39}
}
Nathan Thomsen, et al. "A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement." International Journal of Energy Production and Management, v 4, pp 28-39. doi: https://doi.org/10.2495/EQ-V4-N1-28-39
Nathan Thomsen, Torrey Wagner, Andrew Hoisington and Steven Schuldt. "A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement." International Journal of Energy Production and Management, 4, (2019): 28-39. doi: https://doi.org/10.2495/EQ-V4-N1-28-39
THOMSEN N, WAGNER T, HOISINGTON A, et al. A Sustainable Prototype for Renewable Energy: Optimized Prime-Power Generator Solar Array Replacement[J]. International Journal of Energy Production and Management, 2019, 4(1): 28-39. https://doi.org/10.2495/EQ-V4-N1-28-39