MONTHLY OPTIMIZATION OF A NEW HYBRID RENEWABLE ENERGY SYSTEM CONSIDERING ENERGY AND AGRICULTURAL EFFICIENCY

Selmin Ener Rusen; Buket Bezgin Carbas; Abdurrahman Ulker

Journal Name:

International Journal of Energy Applications and Technologies

Publication Year:

2016

Key Words:

Author Name	University of Author
Selmin Ener Rusen
Buket Bezgin Carbas	Karamanoğlu Mehmetbey Üniversitesi
Abdurrahman Ulker	Karamanoğlu Mehmetbey Üniversitesi

Abstract (2. Language):

Clean and cheap energy in agriculture play a key role in improving agricultural productivity, environmental sustainability, and economic performance. This paper presents the result of the monthly optimization analysis for enhancing energy efficiency and conservation in a new hybrid system composed of pumped-storage (PHS) power plant integrated PV platform and wind turbine (WT). The monthly performance of this new hybrid system is analyzed for Karaman which has high solar and wind energy potentials by reason of its climatic and regional factors. Using the data for one year, a preliminary study has been carried out for the selected station which produced important information for an extended work. The monthly optimization analysis results have been determined by using earth observation data of solar and the wind which are registered in this region. According to the wind and solar data, the optimum month was found as July considering energy and agricultural efficiency. Results can be used either to increase the performance of the new hybrid system or to analyze long-term agricultural and energy studies with more efficiently.

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REFERENCES

References:

[1] S. Neil, W. Jayne (2006). Alternative Energy. Thomson Gale.
[2] WHO, the energy access situation in developing countries: a review focusing on the least developed countries and Sub-Saharan Africa. New York and Geneva: World Health Organization (WHO) and United Nations Development.
[3] IEA. World energy outlook. 2nd ed. International Energy Agency Publications (2006).
[4] International Energy Agency (http://www.iea.org/)
[5] M. Goedeckeb, S. Therdthianwong, SH. Gheewala (2007). Life cycle cost analysis of alternative vehicles and fuels in Thailand, Energy Policy 35(6) 3236–46.
[6] Q. Volker, (2005). Understanding Renewable Energy Systems, Earthscan.
[7] S. Ali (2014). Renewable Energy in the Service of Mankind. Springer.
[8] R.P. Mukund (2006). Wind and Solar Power Systems, Taylor & Francis Group, the academic division of T&F Informa plc vol. 2.
[9] S. M. Muyeen (2012). Wind Energy Conversion Systems, Technology and Trends, Springer.
[10] J. F. Manwell, J. G. McGowan (2009). Wind energy explained : theory, design, and application, Wiley.
[11] T.R. Ayodele, A.A. Jimoh, J.L. Munda, J.T. Agee (2014). Wind distribution and capacity factor estimation for wind turbines in the coastal region of South Africa, Energy Convers Manage (64) 614–25.
[12] H. Yang, W. Zhou, C. Lou (2009). Optimal design and techno-economic analysis of a hybrid solar wind power generation system. Applied Energy (86) 163-69.
[13] G. Arnau, R. Jordi-Roger, R. Antoni, P. Rita (2015). Optimal sizing of a hybrid grid-connected photovoltaic and wind power system. Applied Energy (154) 752-62.
[14] I.G. Mason (2015). Comparative impacts of wind and photovoltaic generation on energy storage for small islanded electricity systems. Renewable Energy (80) 793-05.
[15] S.M. Sichilalu, X. Xia (2015). Optimal power dispatch of a grid tied-battery-photovoltaic system supplying heat pump water heaters. Energy Convers Manage (102) 81–91.
[16] http://www.jasolar.com/
[17] H. Yang, W. Zhou, C. Lou (2009). Optimal design and techno-economic analysis of a hybrid solar wind power generation system. Applied Energy (86) 163-69.
[18] Technical specifications & data https://www.vestas.
[19] A. Juan IP-Díaz, M. Chazarra, J. García-G, G. Cavazzini, A. Stoppato (2015). Trends and challenges in the operation of pumped-storage hydropower plants, Renewable and Sustainable Energy Reviews. (44) 767-784
[20] S. Rehman, L. M. Al-H, A. Md. Mahbub (2015). Pumped hydro energy storage system: A technological review. Renewable and Sustainable Energy Reviews. (44) 586–598.
[21] G. Ardizzon, G. Cavazzini, G. Pavesi (2014). A new generation of small hydro and pumped-hydro power plants: Advances and future challenges. Renewable and Sustainable Energy Reviews. (31) 746–761.
[22] S.V. Papaefthymiou, S.A. Papathanassiou (2014). Optimum sizing of wind-pumpedstorage hybrid power stations in island systems. Renew Energy (64) 187–96.
[23] E.M. Nfah, J.M. Ngundam (2009). Feasibility of pico-hydro and photovoltaic hybrid power systems for remote villages in Cameroon. Renewable Energy (34) 1445–50.

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MONTHLY OPTIMIZATION OF A NEW HYBRID RENEWABLE ENERGY SYSTEM CONSIDERING ENERGY AND AGRICULTURAL EFFICIENCY

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