Research Article
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Year 2022, Volume: 7 Issue: 2, 99 - 111, 29.12.2022
https://doi.org/10.58559/ijes.1160477

Abstract

References

  • [1] Demirkesen S, Variyenli HI. The model of ‘free investment and centralised management’ in renewable energy production projects. International Journal of Energy Studies 2021;6(1):1-18.
  • [2] Yolcan OO, Köse R. Finding optimum tilt angles of photoltaic panels: Kütahya case study. International Journal of Energy Studies 2020;5(2):89-105.
  • [3] Wu H, Deng F, Tan H. Research on parametric design method of solar photovoltaic utilization potential of nearly zero-energy high-rise residential building based on genetic algorithm. Journal of Cleaner Production 2022;368: 133169.
  • [4] Ouria M. (2019). Solar energy potential according to climatic and geometrical parameters of cities and buildings: A case-study from Tabriz City-Iran. Urban Climate 2019; 28:100469.
  • [5] Li Y, Ding D, Liu C, Wang C. A pixel-based approach to estimation of solar energy potential on building roofs. Energy and Buildings 2016; 129: 563-573.
  • [6] Li SY, Han JY. The impact of shadow covering on the rooftop solar photovoltaic system for evaluating self-sufficiency rate in the concept of nearly zero energy building. Sustainable Cities and Society 2022; 80: 103821.
  • [7] Behura AK, Kumar A, Rajak DK, Pruncu CI, Lamberti L. Towards better performances for a novel rooftop solar PV system. Solar Energy 2021; 216: 518-529.
  • [8] Kumar R, Rajoria CS, Sharma A, Suhag S. Design and simulation of standalone solar PV system using PVsyst Software: A case study. Materials Today: Proceedings 2021; 46: 5322-5328.
  • [9] Anang N, Azman SSN, Muda WMW, Dagang AN, Daud MZ. Performance analysis of a grid-connected rooftop solar PV system in Kuala Terengganu, Malaysia. Energy and Buildings, 2021; 248: 111182.
  • [10] van Vuuren DJ, Marnewick A, Pretorius JHC. A proposed simulation-based theoretical preconstruction process: The case of solar photovoltaic technology in South African shopping centres. Renewable and Sustainable Energy Reviews 2019;113: 109295.
  • [11] Ali H, Khan H A. Techno-economic evaluation of two 42 kWp polycrystalline-Si and CIS thin-film based PV rooftop systems in Pakistan. Renewable Energy 2020;152: 347-357.
  • [12] Dehwah AH, Asif M, Rahman MT. Prospects of PV application in unregulated building rooftops in developing countries: A perspective from Saudi Arabia. Energy and Buildings 2018;171: 76-87.
  • [13] Odou ODT, Bhandari R, Adamou R. Hybrid off-grid renewable power system for sustainable rural electrification in Benin. Renewable energy 2020;145: 1266-1279.
  • [14] Dahmoun MEH, Bekkouche B, Sudhakar K, Guezgouz M, Chenafi A, Chaouch A. (2021). Performance evaluation and analysis of grid-tied large scale PV plant in Algeria. Energy for Sustainable Development 2021; 61: 181-195.
  • [15] Redweik P, Catita C, Brito M. Solar energy potential on roofs and facades in an urban landscape. Solar energy 2013; 97: 332-341.
  • [16] Ahmed A, Nadeem TB, Naqvi AA, Siddiqui MA, Khan MH, Zahid MSB, Ammar SM. Investigation of PV utilizability on university buildings: A case study of Karachi, Pakistan. Renewable Energy 2022; 195: 238-251.
  • [17] Nisar H, Janjua AK, Hafeez H, Shahzad N, Waqas A. Thermal and electrical performance of solar floating PV system compared to on-ground PV system-an experimental investigation. Solar Energy 2022; 241: 231-247.
  • [18] Agrawal KK, Jha SK, Mittal RK, Vashishtha S. Assessment of floating solar PV (FSPV) potential and water conservation: case study on Rajghat Dam in Uttar Pradesh, India. Energy for Sustainable Development 2022; 66: 287-295.
  • [19] Kechiche OBHB, Hamza M. Enhancement of a commercial PV module performance under Low Concentrated Photovoltaic (LCPV) conditions: A numerical study. Renewable Energy Focus 2022; 41: 258-267.
  • [20] Belhaouas N, Mehareb F, Assem H, Kouadri-Boudjelthia E, Bensalem S, Hadjrioua F, Aissaoui A, Bakria K. A new approach of PV system structure to enhance performance of PV generator under partial shading effect. Journal of Cleaner Production 2021; 317: 128349.
  • [21] General Directorate of Renewable Energy of Turkey, available at: www.yegm.gov.tr

Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey

Year 2022, Volume: 7 Issue: 2, 99 - 111, 29.12.2022
https://doi.org/10.58559/ijes.1160477

Abstract

Solar energy is considered as one of the clean and sustainable energy sources. As known, big portion of the energy demand in industrial processes are generally met by fossil energy sources. Utilizing renewable and sustainable energy technologies in industrial facilities can decrease negative environmental effects. In this study, applicability of a rooftop solar energy generation system in an industrial building has been analyzed. In the simulation process, PvSOL software has been employed. Considering available areas on the roof of the facility, solar electrical energy generation system with installed power of 573.75 kWp was planned and simulated. Moreover, economic analysis results of the proposed rooftop solar energy system were presented within the scope of this research. According to the economic analysis outcomes, payback period of the proposed rooftop energy system was achieved less than 4 years.

References

  • [1] Demirkesen S, Variyenli HI. The model of ‘free investment and centralised management’ in renewable energy production projects. International Journal of Energy Studies 2021;6(1):1-18.
  • [2] Yolcan OO, Köse R. Finding optimum tilt angles of photoltaic panels: Kütahya case study. International Journal of Energy Studies 2020;5(2):89-105.
  • [3] Wu H, Deng F, Tan H. Research on parametric design method of solar photovoltaic utilization potential of nearly zero-energy high-rise residential building based on genetic algorithm. Journal of Cleaner Production 2022;368: 133169.
  • [4] Ouria M. (2019). Solar energy potential according to climatic and geometrical parameters of cities and buildings: A case-study from Tabriz City-Iran. Urban Climate 2019; 28:100469.
  • [5] Li Y, Ding D, Liu C, Wang C. A pixel-based approach to estimation of solar energy potential on building roofs. Energy and Buildings 2016; 129: 563-573.
  • [6] Li SY, Han JY. The impact of shadow covering on the rooftop solar photovoltaic system for evaluating self-sufficiency rate in the concept of nearly zero energy building. Sustainable Cities and Society 2022; 80: 103821.
  • [7] Behura AK, Kumar A, Rajak DK, Pruncu CI, Lamberti L. Towards better performances for a novel rooftop solar PV system. Solar Energy 2021; 216: 518-529.
  • [8] Kumar R, Rajoria CS, Sharma A, Suhag S. Design and simulation of standalone solar PV system using PVsyst Software: A case study. Materials Today: Proceedings 2021; 46: 5322-5328.
  • [9] Anang N, Azman SSN, Muda WMW, Dagang AN, Daud MZ. Performance analysis of a grid-connected rooftop solar PV system in Kuala Terengganu, Malaysia. Energy and Buildings, 2021; 248: 111182.
  • [10] van Vuuren DJ, Marnewick A, Pretorius JHC. A proposed simulation-based theoretical preconstruction process: The case of solar photovoltaic technology in South African shopping centres. Renewable and Sustainable Energy Reviews 2019;113: 109295.
  • [11] Ali H, Khan H A. Techno-economic evaluation of two 42 kWp polycrystalline-Si and CIS thin-film based PV rooftop systems in Pakistan. Renewable Energy 2020;152: 347-357.
  • [12] Dehwah AH, Asif M, Rahman MT. Prospects of PV application in unregulated building rooftops in developing countries: A perspective from Saudi Arabia. Energy and Buildings 2018;171: 76-87.
  • [13] Odou ODT, Bhandari R, Adamou R. Hybrid off-grid renewable power system for sustainable rural electrification in Benin. Renewable energy 2020;145: 1266-1279.
  • [14] Dahmoun MEH, Bekkouche B, Sudhakar K, Guezgouz M, Chenafi A, Chaouch A. (2021). Performance evaluation and analysis of grid-tied large scale PV plant in Algeria. Energy for Sustainable Development 2021; 61: 181-195.
  • [15] Redweik P, Catita C, Brito M. Solar energy potential on roofs and facades in an urban landscape. Solar energy 2013; 97: 332-341.
  • [16] Ahmed A, Nadeem TB, Naqvi AA, Siddiqui MA, Khan MH, Zahid MSB, Ammar SM. Investigation of PV utilizability on university buildings: A case study of Karachi, Pakistan. Renewable Energy 2022; 195: 238-251.
  • [17] Nisar H, Janjua AK, Hafeez H, Shahzad N, Waqas A. Thermal and electrical performance of solar floating PV system compared to on-ground PV system-an experimental investigation. Solar Energy 2022; 241: 231-247.
  • [18] Agrawal KK, Jha SK, Mittal RK, Vashishtha S. Assessment of floating solar PV (FSPV) potential and water conservation: case study on Rajghat Dam in Uttar Pradesh, India. Energy for Sustainable Development 2022; 66: 287-295.
  • [19] Kechiche OBHB, Hamza M. Enhancement of a commercial PV module performance under Low Concentrated Photovoltaic (LCPV) conditions: A numerical study. Renewable Energy Focus 2022; 41: 258-267.
  • [20] Belhaouas N, Mehareb F, Assem H, Kouadri-Boudjelthia E, Bensalem S, Hadjrioua F, Aissaoui A, Bakria K. A new approach of PV system structure to enhance performance of PV generator under partial shading effect. Journal of Cleaner Production 2021; 317: 128349.
  • [21] General Directorate of Renewable Energy of Turkey, available at: www.yegm.gov.tr
There are 21 citations in total.

Details

Primary Language English
Subjects Energy Systems Engineering (Other)
Journal Section Research Article
Authors

Berk Sürücü 0000-0003-2211-7077

Murat Öztürk 0000-0002-0668-8075

Erdem Çiftçi 0000-0003-2493-5962

Azim Doğuş Tuncer 0000-0002-8098-6417

Publication Date December 29, 2022
Submission Date August 10, 2022
Acceptance Date August 25, 2022
Published in Issue Year 2022 Volume: 7 Issue: 2

Cite

APA Sürücü, B., Öztürk, M., Çiftçi, E., Tuncer, A. D. (2022). Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey. International Journal of Energy Studies, 7(2), 99-111. https://doi.org/10.58559/ijes.1160477
AMA Sürücü B, Öztürk M, Çiftçi E, Tuncer AD. Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey. Int J Energy Studies. December 2022;7(2):99-111. doi:10.58559/ijes.1160477
Chicago Sürücü, Berk, Murat Öztürk, Erdem Çiftçi, and Azim Doğuş Tuncer. “Software-Based Solar Energy Potential Assessment for an Industrial Facility: A Case Study from Aegean Region of Turkey”. International Journal of Energy Studies 7, no. 2 (December 2022): 99-111. https://doi.org/10.58559/ijes.1160477.
EndNote Sürücü B, Öztürk M, Çiftçi E, Tuncer AD (December 1, 2022) Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey. International Journal of Energy Studies 7 2 99–111.
IEEE B. Sürücü, M. Öztürk, E. Çiftçi, and A. D. Tuncer, “Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey”, Int J Energy Studies, vol. 7, no. 2, pp. 99–111, 2022, doi: 10.58559/ijes.1160477.
ISNAD Sürücü, Berk et al. “Software-Based Solar Energy Potential Assessment for an Industrial Facility: A Case Study from Aegean Region of Turkey”. International Journal of Energy Studies 7/2 (December 2022), 99-111. https://doi.org/10.58559/ijes.1160477.
JAMA Sürücü B, Öztürk M, Çiftçi E, Tuncer AD. Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey. Int J Energy Studies. 2022;7:99–111.
MLA Sürücü, Berk et al. “Software-Based Solar Energy Potential Assessment for an Industrial Facility: A Case Study from Aegean Region of Turkey”. International Journal of Energy Studies, vol. 7, no. 2, 2022, pp. 99-111, doi:10.58559/ijes.1160477.
Vancouver Sürücü B, Öztürk M, Çiftçi E, Tuncer AD. Software-based solar energy potential assessment for an industrial facility: a case study from Aegean Region of Turkey. Int J Energy Studies. 2022;7(2):99-111.