Usage and efficiency analysis of electricity generated by PV power plant in a marina or industrial facility

Yıl 2022, Cilt: 6 Sayı: 3, 357 - 368, 30.09.2022

Ali Riza Dal

https://doi.org/10.30521/jes.1054133

Öz

In this study, the analysis of the usage efficiency and the time allocation to cover the initial investment cost of a PV power plant to be installed in an industrial facility having constant electricity consumption monthly and a yacht marina having fluctuating electricity consumption in a year (equal yearly electricity in each in total) within the installation assumption of same conditions of PV plant has been done. The PV power plant data with 680 kWp power and located at the same latitude as the yacht marina in the center of Mediterranean were used. For this purpose, it has been calculated that the PV power plant installed power required for the annual electricity need of the yacht marina will be 1357 kWp. With this power, 2,141,117 kWh of electricity has been produced annually and the yacht marina/industrial facility need has been supplied. In addition, the Net Present Value (NPV) was used to calculate the coverage period for the initial investment cost of the PV plant. In the calculations, it has been determined that the time to cover the initial investment cost is 4.31 years in the yacht marina and 4.37 years in the industrial facility. This result showed that installing PV power plants in marinas would be 1.5% more advantageous than other industrial facilities.

Anahtar Kelimeler

Energy efficiency, PV plant, Solar energy, Yacht marina

Kaynakça

• [1] Official Gazette Numbered 31760. Decision of the President on Decision to Amend the Decision on State Aids in Investments. February 24, 2022.
• [2] Official Gazette Numbered 30772. Regulation on Unlicensed Electricity Generation in the Electricity Market. May 12, 2019.
• [3] Sarı, V, Özyiğit, FY. Design and analysis of grid connected solar power plants in different districts of Sivas province. European Journal of Science and Technology 2020; 20: 425 – 437.
• [4] Güven, ŞY. Şenol, RA sample application of solar cells-based garden lightingard irrigation systems, Engineer and Machinery 2020; 46 (548):13-20.
• [5] Baghdadi, I, Yaakoubi, A, Attari, K, Leemrani, Z, Asselman, A. Performance investigation of a PV system connected to the grid. Procedia Manufacturing 2018; 22: 667-674.
• [6] Chang, TP. Output energy of a photovoltaic module mounted on a single-axis tracking system. Applied Energy 2009; 86 (10): 2071–2078. DOI:10.1016/j.apenergy.2009.02.006.
• [7] Dondariya, C, Porwal, D, Awasthi, A, Shukla, AK, Sudhakar, K, Monahar, SRM, Bhimte, A. Performance simulation of grid-connected rooftop solar PV system for small households: a case study of Ujjain, India. Energy Reports 2018; 4: 546-553.
• [8] Kandasamy, CP, Prabuand, P, Niruba, K. Solar potential assessment using PVSYST software. In: ICGCE 2013 International Conference on Green Computing, Communication and Conservation of Energy; 27-29 June 2013: IEEE, pp. 667-672.
• [9] Sharma, V, Chandel, SS. Performance analysis of a 190 kWp Grid interactive solar photovoltaic power plant in India. Energy 2013; 55: 476-485.
• [10] Ramoliya, JV. Performance Evaluation of Grid connected Solar Photovoltaic Plant Using PVSYST Software. Journal of Emerging Technologies and Innovative Research (JETIR) 2015; 2(2): 372-378.
• [11] Charfi W, Chaabane, M, Mhiri, H, Bournot, P. Performance evaluation of a solar photovoltaic system. Energy Reports 2018; 4: 400-406.
• [12] Boboker, H. Feasibility Analysis for a Solar Power Plant in Libya, A Master’s Thesis, Atılım University the Graduate School of Natural and Applied Sciences, İstanbul, Turkey, 2017.
• [13] Dal, AR, Yılmaz, F. An investigation on supplying electricity demand of a commercial marina via photovoltaic (PV) technology. Uludağ University Journal of The Faculty of Engineering, 2020; 25 (3): 1189-1204.
• [14] Shimy, M. Viability analysis of PV power plants in Egypt, Renewable Energy 2009; 34(10): 2187-2196.
• [15] Sulukan, E. Techno-economic and environmental analysis of a photovoltaic system in İstanbul. Pamukkale University Journal of Engineering Sciences 2020; 26(1): 127-132.
• [16] Emeksiz, C, Fındık, MM. Evaluation of renewable energy resources for sustainable development in Turkey. European Journal of Science and Technology, 2021; 26: 155-164.
• [17] Demircan, C, Eke, R. The performance analysis of the 40 kWp BIPV system after 6 months operating duration. SDU Journal of Science 2014; 9(2): 122-131.
• [18] Roberts S. and Guariento N. Building Integrated Photovoltaics A Handbook. Berlin: Birkhauser Press, Germany, 2009.
• [19] Yıldırım, E., Aktacir, MA. Investigation of azimuth and tilt angle effects on building integrated photovoltaic systems. Journal of the Faculty of Engineering and Architecture of Gazi University 2019; 34(2): 609-619.
• [20] Boztepe, M. Fotovoltaik Güç Sistemlerinde Verimliliği Etkileyen Parametreler [Parameters Affecting Efficiency in Photovoltaic Power Systems]. In: IV. İzmir Enerji Verimliliği Günleri; 19-20 January 2017: The Chamber of Electrical Engineers, pp. 19-20.
• [21] Hair, JF., Anderson, RE., Tatham, RL. Black, WC. Multivariate Data Analysis with Readings. Englewood Cliff: Prentice-Hall International Inc., New Jersey, 1995.
• [22] Official Gazette Numbered 31796. Board Decision of the Energy Market Regulatory Authority. April 1, 2022.
• [23] Eski, H, Armaneri, Ö. Engineering Economics. Ankara, Türkiye: Gazi Kitapevi, 2006.
• [24] Turkish Statistical Institute (TÜİK). Statistics on Inflation and Prices. April 20, 2021.