International Journal of Renewable Energy Research-IJRER

This paper first reviews the current state of Photovoltaic (PV) cell technology, and comparatively analyzes the cost of electricity generated from different PV technologies against electricity produced at the main thermal power plant in Northern Cyprus. The comparison has been done with and without externality costs, and thus incorporates sustainability principles. The analysis is extended to investigate suitable solar cell technologies for an on-campus PV farm at Middle East Technical University Northern Cyprus Campus, with and without substantial storage support. The estimated economical break-even points of the PV system with battery storage as opposed to current fossil fuel based energy are approximately 15 and 17 years respectively for mono-crystalline silicon (Si) and multi-crystalline Si technology. Assuming the produced electricity can be stored to the grid through bi-directional power delivery, the economical break-even point can be reduced to 6 to 7 years depending on utilized technology. The electricity generation cost of grid-tied PV system at university with multi-crystalline Si technology has already become competitive against that of the grid electricity in Northern Cyprus. Therefore PV electricity production can be expected to significantly contribute to electricity production in Northern Cyprus in near future based on the analysis in this paper.

E. Al-Ammar and A. Al-Aotabi, “Feasibility Study of Establishing a PV Power Plant to Generate Electricity in Saudi Arabia from Technical, Geographical, and Economical Viewpoints,†presented at the International Conference on Renewable Energies and Power Quality (ICREPQ ’10), Granada (Spain), 2010.

K. S. Myers, S. A. Klein, and D. T. Reindl, Assessment of High Penetration of Photovoltaics on Peak Demand and Annual Energy Use. Madison: University of Wisconsin, 2010.

B. van der Zwaan and A. Rabl, “Prospects for PV: a learning curve analysis,†Sol. Energy, vol. 74, no. 1, pp. 19–31, Jan. 2003.

G. Panayiotou, S. Kalogirou, and S. Tassou, “Design and simulation of a PV and a PV–Wind standalone energy system to power a household application,†Renew. Energy, vol. 37, no. 1, pp. 355–363, Jan. 2012.

O.Phillips Agboola, FauT Eglioglu, and O. Mary Agboola, “The Feasibility Study of household units PV cells for carbon emission reduction in developing countries: A case study of North Cyprus,†presented at the International Conference on Energy Sustainability, Phoenix, Arizona, USA, 2010.

http://solarcellcentral.com/markets_page.html. [Accessed: Feb-2012].

“PV Status Report 2013.†[Online]. Available: http://iet.jrc.ec.europa.eu/remea/pv-status-report-2013. [Accessed: Nov-2013].

http://www.iea.org/. [Accessed: Feb-2012].

http://www.solarbuzz.com/. [Accessed: Feb-2013].

M.Ito,M. Kudo, M. Nagura, and K. Kurokawa, “A comparative study on life cycle analysis of 20 different PV modules installed at the Hokuto mega-solar plant,†Prog. Photovolt. Res. Appl., vol. 19, no. 7, pp. 878–886, 2011.

R. Foster, Solar energy: renewable energy and the environment. Boca Raton: CRC Press, 2010.

http://www.kibtek.com/. [Accessed: Feb-2012].

M. El-Kordy, M. Badr, K.Abed, and S.M.Ibrahim, “Economical evaluation of electricity generation considering externalities,†Renew. Energy, vol. 25, no. 2, pp. 317–328, Feb. 2002.

Teknecik Power Plant Staff .Kyrenia, N. Cyprus., “Personal conversation,†16-Dec-2011.

“Welcome to InflationData.com.†[Online]. Available: http://inflationdata.com/. [Accessed: Feb-2012].

Ali Muhtaroglu, “SEES 502 Fall 2011 Class Notes. Sustainable Environmental and Energy Systems.Middle East Technical University N. Cyprus Campus (METU NCC).†2011.

R. A. Messenger and J. Ventre, Photovoltaic systems engineering. Boca Raton, FL: CRC Press/Taylor & Francis, 2010.

M. Staffhorst, The Way to Competitiveness of PV - An Experience Curve and Break-even Analysis. kassel university press GmbH, 2006.

V. Petrova-Koch, R. Hezel, and A. Goetzberger, High-efficient low-cost photovoltaics recent developments. Berlin: Springer, 2009.