Optimal Sizing of Hybrid Renewable Energy System for off-Grid Electrification: A Case Study of University of Ibadan Abdusalam Abubakar Post Graduate Hall of Residence
Abstract
The main objective of this study is to design a Hybrid Renewable Energy System (HRES) to meet the energy demand of a major Post Graduate Student residential hostel. The specific objectives were to estimate the energy demand, perform economic and technical analysis of various combination of renewable energy technologies that can meet the estimated energy demand and to select the appropriate and optimum hybrid system for the hall of residence. Quantitative analysis was used to determine the energy demand of the hall of residence while the solar resource information was obtained from the NASA Surface Meteorology. The Hybrid Optimization Model for Electric Renewables (HOMER) software was used for analysis. The components of the system considered were solar photovoltaic (PV), diesel generator, batteries and inverter. The optimised hybrid system obtained was also compared to a system in which a diesel generator serves as the sole source of electricity supply. Economic analysis using the total net present cost and levelized cost of enegy was employed to determine the optimized hybrid combination. Environmental considerations were also made based on the amount of Carbon dioxide emitted per year. Results indicates that electricity generation through a hybrid system made up of 1000kW PV, 110 kVA generator, 11791 kWh Surrette S6CS25P battery arranged in parallel strings and a 220 kW Inverter had the lowest total net present cost, lowest cost of energy with a low emission. Hence, Hybrid Renewable Energy Systems (HRES) should be employed in the production of electricity in due to its ability to reduce environmental degradation while ensuring a low total net present cost and a low cost of energy.
Keywords
Full Text:
PDFReferences
Babatunde, O., Emezirinwune, M., & Denwigwel , H. (2017). Hybrid Power System for Off-grid Communities:Techno-Economic and Energy Mix Analysis. IEEE.
Bakos, G. (2002). Feasibility Study of a Hybrid Wind/Hydro Power System for Low-Cost Electricity Production. Applied Energy, 72, 599-608.
Bekele, G., & Tadesse, G. (2012). Feasibility Study of Small Hydro/PV/Wind Hybrid System for Off-Grid Rural Electrification in Ethiopia. Applied Energy, 97, 5-15.
Bhandari, B., Poudel, S., Lee, K. T., & Ahn, S. H. (2014). Mathematical Modeling of Hybrid Renewable Energy System: A Review on Small Hydro-Solar-Wind Power Generation. International Journal of Precision Engineering and Manufacturing- Green Technology, 1, 157-173.
Bhattacharyya, S. C. (2011). Energy Economics: Concepts, Issues, Markets and Governance. London: Springer. doi:10.1007/978-0-85729-268-1
Dali, M., Belhadj, J., & Roboam, X. (2010). Hybrid solar–Wind System with Battery Storage Operating in Grid-Connected and Standalone Mode: Control and Energy Management – Experimental Investigation. Energy, 35, 2587-2595.
EIA. (2018, August 8). Nonenewable Energy Explained. Retrieved August 2018, from US Energy Information Administration: https://www.eia.gov/energyexplained/?page=nonrenewable_home
Fazelpour, F., Farahi, S., & Soltani, N. (2016). Techno-Economic Analysis of a Hybrid Power System for a Residential Building in Zabol, Iran. IEEE.
Hashimoto, S., Yachi, T., & Tani, T. (2005). New Stand-Alone Hybrid Power System with Wind Turbine Generator and Photovoltaic Modules for a Small-Scale Radio Base Station. IEEJ Transactions on Power and Energy, 11, 1014-1046.
Hassan, M. (2014). Power Generation Methods, Tehniques and Economical Strategy. International Technical Sciences Journal, 43-61.
InfoGuide Nigeria. (2017). 38 power stations in Nigeria, Locations and their Capacities. Retrieved October 3, 2018, from https://infoguidenigeria.com/power-stations-nigeria/
Kane, M. (2003). Small Hybrid Solar Power System. Energy, 28, 1427-1443.
Lao, C., & Chungpaibulpatana, S. (2017). Techno-Economic Analysis of Hybrid Systemfor Rural Electrification in Cambodia. Energy Procedia, 524-529.
NAOC. (2018). Access to Energy Initiatives. Retrieved October 3, 2018, from https://www.eni.com/en_NG/sustainability/community/social-investments/access-to-energy/access-to-energy.shtml
Nurunnabi, M., & Roy, N. (2015). Grid Connected Hybrid Power System Deign Using HOMER. IEEE.
Olatomiwa, L., Mekhilef, S., Huda, A. S., & Sanusi, K. (2015). Techno-economic analysis of hybrid PV–diesel–battery and PV–wind–diesel–battery power systems for mobile BTS: the way forward for rural development. Energy Science and Engineering, 271-285.
Ram Prabhakar, J., & Ragavan, K. (2013). Power Management Based Current Control Technique for Photovoltaic-Battery Assisted Wind Hydro Hybrid System. International Journal of Emerging Electric Power Systems, 14, 351-362.
Saheb-Koussa, D., Haddadi, M., & Belhamel, M. (2009). Economic and Technical Study of a Hybrid System (wind-photovoltaic-diesel) for Rural Electrification in Algeria. Applied Energy, 86, 1024-1030.
Sharaf, A. M., & El-Sayed, M. (2009). A Novel Hybrid Integrated Wind-PV Micro Co-Generation Energy Scheme for Village Electricity. Proc. of IEEE International Electric Machines and Drives Conference (IEMDC '09),.
Timmons, D., Harris, J. M., & Roach, B. (2014). The Econoics of Renewable Energy. Medford, Massachusetts: Global Development And Environment Institute.
TREIA. (2015). Definition of Renewable Energy. Retrieved from efine Renewable Energy: http://www.treia.org/renewable-energy-defined.
DOI (PDF): https://doi.org/10.20508/ijsmartgrid.v4i4.135.g110
Refbacks
- There are currently no refbacks.
www.ijsmartgrid.com; www.ijsmartgrid.org
ilhcol@gmail.com; ijsmartgrid@nisantasi.edu.tr
Online ISSN: 2602-439X
Publisher: ilhami COLAK (istanbul Nisantasi Univ)
Cited in Google Scholar and CrossRef