International Journal of Renewable Energy Research-IJRER

Abstract- For remote houses with no connection to the grid, if the site is suitable for wind energy, an off-grid wind turbine-battery power system is a good alternative for supplying the energy need of the house. If the reliability of the power supply is crucial then sizing of the components, wind turbine and the battery bank, is very important. In the market there are many wind turbines with different ratings and power curves. For an off-grid turbine-battery power system, for every different chosen wind turbine the minimum required number of batteries in the battery bank would be different for reliable and continuous power supply to the house. It is the usual case in practice that either the battery bank is chosen as undersized such that the consumer suffers from no power from time to time or the battery bank is chosen as oversized without any calculation and this results in high initial costs for the consumer. In this study, for a remote house in Catalca Turkey, a stand-alone wind turbine-battery system will be sized using wind data of the site and consumption data of the house. Our results show that the minimum number of batteries needed in the battery bank for an uninterrupted electrical energy supply changes very much according to the chosen wind turbine and the minimum required number of batteries depends on the power curve of the chosen wind turbine rather than the rated power of the wind turbine.

Wind turbine-battery system; stand-alone off-grid system; optimum sizing of battery bank; wind energy; reliability

References

Kaldellis JK. 2010. “Stand-Alone and Hybrid Wind Energy Systemsâ€. Woodhead Publishing, ISBN:978-1-84569-527-9

https://www.sciencedirect.com/science/book/9781845695279

Ramgolam YK, Thumiah R. 2018. “Stand-Alone Wind or Photovoltaic Power System: A Holistic Approach for System Design and Selection. The Nexus: Energy, Environment and Climate Changeâ€. Green Energy and Technology. Springer International Publishing, ISBN:978-3-319-63612-2

http://www.springer.com/gp/book/9783319636115

Rathish RJ, Mahadevan K. 2018. “Multi-Objective Optimization of Stand-alone Renewable Energy Hybrid Systemâ€. Intelligent and Efficient Electrical Systems. Lecture Notes in Electrical Engineering, vol 446. Springer International Publishing, ISBN:978-981-10-4852-4

http://www.springer.com/gp/book/9789811048517

Gavanidou E, Bakirtzis A. 1992. “Design of a stand alone system with renewable energy sources using trade-off methodsâ€, IEEE Transactions on Energy Conversion 7:42-48.

http://dx.doi.org/10.1109/60.124540

Chedid R, Rahman S. 1997. “Unit sizing and control of hybrid wind–solar power systemsâ€, IEEE Transactions on Energy Conversion 12:79-85.

http://dx.doi.org/10.1109/60.577284

Kellogg WD, Nehrir MH, Venkataramanan G, Gerez V. 1998. “Generation unit sizing and cost analysis for stand-alone wind, photovoltaic and hybrid wind/PV systemsâ€, IEEE Transactions on Energy Conversion 13:70-75.

http://dx.doi.org/10.1109/60.658206

Bernal-Agust'in JL, Dufo-L'opez R, Rivas-Ascaso DM. 2006. “Design of isolated hybrid systems minimizing costs and pollutant emissionsâ€, Renewable Energy 31:2227-2244.

http://dx.doi.org/10.1016/j.renene.2005.11.002

Senjyu T, Hayashi D, Yona A, Urasaki N, Funabashi T. 2007. “Optimal configuration of power generating systems in isolated island with renewable energyâ€, Renewable Energy 32:1917-1933.

http://dx.doi.org/10.1016/j.renene.2006.09.003

Patel AM, Singal SK. 2018. “Economic Analysis of Integrated Renewable Energy System for Electrification of Remote Rural Area having Scattered Populationâ€, International Journal of Renewable Energy Research 8:523-539

http://www.ijrer.org/ijrer/index.php/ijrer/article/view/6820/pdf

Okinda VO, Odero NA. 2016. “Modelling, Simulation and Optimal Sizing of a Hybrid Wind, Solar PV Power System in Northern Kenyaâ€, International Journal of Renewable Energy Research 6:1199-1211

http://www.ijrer.org/ijrer/index.php/ijrer/article/view/4323/pdf

Suhane P, Rangnekar S. 2014. “Optimal Sizing of Hybrid Energy System using Ant Colony Optimizationâ€, International Journal of Renewable Energy Research 4:936-942

http://www.ijrer.org/ijrer/index.php/ijrer/article/view/1676/6430

Yang H, Lu L, Zhou W. 2007. “A novel optimization sizing model for hybrid solar-wind power generation systemâ€, Solar Energy 81:76-84

https://doi.org/10.1016/j.solener.2006.06.010

Li J, Wei W, Xiang J. 2012. “A Simple Sizing Algorithm for Stand-Alone PV/Wind/Battery Hybrid Microgridsâ€, Energies 5:5307-5323

https://doi.org/10.3390/en5125307

Al-falahi MDA, Jayasinghe SDG, Enshaei H. 2017. “A review on recent size optimization methodologies for standalone solar and wind hybrid renewable energy systemâ€, Energy Conversion and Management 143:252-274

http://doi.org/10.1016/j.enconman.2017.04.019

Belouda M, Jaafar A, Sareni B, Roboam X, Belhadj J. 2016. “Design methodologies for sizing a battery bank devoted to a stand-alone and electronically passive wind turbine systemâ€, Renewable and Sustainable Energy Reviews 60:144-154

http://doi.org/10.1016/j.rser.2016.01.111

Bakirtzis AG. 1992. “A probabilistic method for the evaluation of the reliability of stand alone wind energy systemsâ€, IEEE Transactions on Energy Conversion 7:99-107

http://doi.org/10.1109/60.124548

Abouzahr I, Ramakumar R. 1990. “Loss of power supply probability of stand-alone wind electric conversion systems: a closed form solution approachâ€, IEEE Transactions on Energy Conversion 5:445-452

http://doi.org/10.1109/60.105267

Karkani SB. 2017. “Designing an off-grid wind system for a household in Catalca, Istanbulâ€, Master’s Thesis, Bahcesehir University, Istanbul Turkey

UK Household Electricity Survey web page [accessed July 2018]

https://www.gov.uk/government/collections/household-electricity-survey

Small Wind Certification Council web page [accessed July 2018]

http://smallwindcertification.org/

Microgeneration Certificate Scheme web page [accessed July 2018]

http://www.microgenerationcertification.org

Intertek web page [accessed July 2018]

http://www.intertek.com/

National Renewable Energy Laboratory (NREL) web page [accessed July 2018]

https://www.nrel.gov/wind/

Swift Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

https://www.nrel.gov/docs/fy13osti/56499.pdf

Sumec PWB01.2.1 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/WorkArea/DownloadAsset.aspx?id=41623

Pika T701 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2017/01/Summary-Report-13-03-2017-1.pdf

Sumec PWB02.2.1 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/WorkArea/DownloadAsset.aspx?id=41624

Skystream 3.7 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2018/01/Summary-Report-10-20-2017.pdf

Kestrel e400nb Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2017/08/Summary-Report-10-16-2017.pdf

Sumec PWA03.2.1 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/WorkArea/DownloadAsset.aspx?id=36586

Windera S Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.ennera.com/upload/descargas/WinderaS_GLCertification_GL.pdf

Fortis Montana Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/uploadedFiles/Intertek/Divisions/Commercial_and_Electrical/Media/PDF/Energy/Wind/Fortis%20Power%20Performance%20Report.pdf

Windspot 3.5 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/uploadedFiles/Intertek/Divisions/Commercial_and_Electrical/Media/PDF/Energy/Wind/SonkyoReport11053879LHD-001-1-11-13.pdf

Sumec PWA05.2.1 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/uploadedFiles/Intertek/Divisions/Commercial_and_Electrical/Media/PDF/Energy/Wind/12100246SHA-004_AWEASummaryReport_SUMEC_PWA05-50-280.pdf

Kingspan KW6 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2017/09/Summary-Report-11-04-2017-1.pdf

Bergey Excel 6 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://bergey.com/documents/2017/02/excel-6-swcc-summary-report-2016.pdf

Virdy CS8 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

https://www.nrel.gov/docs/fy13osti/56500.pdf

Bergey Excel 10 Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2018/01/Summary-Report-10-12-2017.pdf

Lely Aircon LA10 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2018/02/Summary-Report-16-01-2018.pdf

CF10 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/uploadedFiles/Intertek/Divisions/Commercial_and_Electrical/Media/PDF/Energy/Wind/101510200LHD-001b_BWEA%20Summary%20Report_CF10%20(phase%20A).pdf

Osiris 10 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.intertek.com/uploadedFiles/Intertek/Divisions/Commercial_and_Electrical/Media/PDF/Energy/Wind/130500333SHA-001_AWEASummaryReport_Osiris10.pdf

Xzeres 442SR Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://smallwindcertification.org/wp-content/uploads/2018/02/Summary-Report-10-10-2018.pdf

Gaia GW 133-11 Wind Turbine Power Performance Test Report, Available from: [accessed July 2018]

http://www.gaia-wind.com/files/3413/7967/7488/GWTD0018_Gaia-Wind_GW133-11_kW_Summary_Report_UK_MCS_-_V1_1.pdf