Research Article
BibTex RIS Cite
Year 2022, Volume: 11 Issue: 4, 971 - 982, 31.12.2022
https://doi.org/10.17798/bitlisfen.1129632

Abstract

References

  • P. G. Vasconcelos Sampaio, and M. O. Aguirre Gonzales, “Photovoltaic solar energy: Conceptual framework” Renewable and Sustainable Energy Reviews, vol. 74, pp. 590-601, 2017.
  • A. Kumar, A. Adelodun, and K. H. Kim, “Solar energy: Potential and future prospects,” Renewable and Sustainable Energy Reviews, vol. 82, pp. 894-900, 2018.
  • İ. Çelik, C. Yıldız, and M. Şekkeli, Turkish Journal of Engineering, vol 5, no.2, pp. 89-94, 2021.
  • B. Al-Mhairat and A. Al-Quraan, “Assessment of Wind Energy Resources in Jordan Using Different Optimization Techniques,” Processes, vol. 10, no.1, p. 105, 2022.
  • C. Xiaodong, D. Xilei, and L. Junjie, “Building energy-consumption status worldwide and the state-of-the-art technologies for zero-energy buildings during the past decade,” Energy and Buildings, vol. 128, pp. 198-213, 2016.
  • “Annual energy outlook - U.s. energy Information Administration (EIA),” Eia.gov. [Online]. Available: https://www.eia.gov/outlooks/aeo/. [Accessed: 16-Oct-2022].
  • Commission européenne. Direction générale de la mobilité et des transports, EU energy, transport and GHG emmissions: Trends to 2030 : Reference scenario 2013. Brussels, Belgium: European Commission, 2014.
  • J. Liu, X. Chen, H. Yang, and K. Shan, “Hybrid renewable energy applications in zero-energy buildings and communities integrating battery and hydrogen vehicle storage,” Applied Energy, vol. 290, no. 116733, p. 116733, 2021.
  • A. Sajid and C. M. Jang, "Optimum design of hybrid renewable energy system for sustainable energy supply to a remote island." Sustainability, vol. 12, no. 1280, p. 1280, 2020.
  • J. Liu, Y. Zhou, H. Yang, and H. Wu, “Net-zero energy management and optimization of commercial building sectors with hybrid renewable energy systems integrated with energy storage of pumped hydro and hydrogen taxis,” Applied Energy, vol. 321, no. 119312, p. 119312, 2022.
  • W. Wu and H.M. Skye, "Residential net-zero energy buildings: Review and perspective," Renewable and Sustainable Energy Reviews, vol. 142, no. 110859, p. 110859, 2021.
  • F. Bahramian, A. Akbari, M. Nabavi, S. Esfandi, E. Naeiji, and A. Issakhov, “Design and tri objective optimization of an energy plant integrated with near-zero energy building including energy storage: An application of dynamic simulation,” Sustainable Energy Technologies and Assessments, vol. 47, no. 101419, p.10419, 2021.
  • S. Gorjian, H. Ebadi, G. Najafi, S. S. Chandel, and H. Yildizhan, “Recent advances in net-zero energy greenhouses and adapted thermal energy storage systems,” Sustainable Energy Technologies and Assessments, vol. 43, no. 100940, p. 100940, 2021.
  • J. Liu, H. Yang, and Y. Zhou, “Peer-to-peer energy trading of net-zero energy communities with renewable energy systems integrating hydrogen vehicle storage,” Applied Energy, vol. 298, no. 117206, p. 117206, 2021.
  • N. Sifakis and T. Tsoutsos, “Planning zero-emissions ports through the nearly zero energy port concept,” Journal of Cleaner Production, vol. 286, no. 125448, p. 125448, 2021.
  • A. Arabkoohsar, A. Behzadi, and A.S. Alsagri, “Techno-economic analysis and multi-objective optimization of a novel solar-based building energy system; An effort to reach the true meaning of zero-energy buildings,” Energy Conversion and Management, vol. 232, no. 113858, p. 113858, 2021.
  • S. Arabi-Nowdeh, S. Nasri, P. B. Saftjani, A. Naderipour, Z. Abdul-Malek, H. Kamyab, and A. Jafar-Nowdeh, “Multi-criteria optimal design of hybrid clean energy system with battery storage considering off-and on-grid application,” Journal of Cleaner Production, vol. 290, no. 125808, p. 125808, 2021.
  • K. V. Konneh, H. Masrur, M. L. Othman, N. I. A. Wahab, H. Hizam, H., S. Z. Islam, and T. Senjyu,” Optimal design and performance analysis of a hybrid off-grid renewable power system considering different component scheduling, PV modules, and solar tracking systems,” IEEE Access, vol. 9, pp. 64393-64413, 2021.
  • B. Musa, N. Yimen, S. I. Abba, H. H. Adun, and M. Dagbasi, “Multi-state load demand forecasting using hybridized support vector regression integrated with optimal design of off-grid energy Systems—A metaheuristic approach,” Processes, vol. 9, no. 1166, p. 1166, 2021.
  • H. M. Farh, A. A. Al-Shamma’a, A. M. Al-Shaalan, A. Alkuhayli, A. M. Noman, and T. Kandil, “Technical and economic evaluation for off-grid hybrid renewable energy system using novel bonobo optimizer,” Sustainability, vol. 14, no. 1533, p.1533, 2022.
  • P. Marocco, D. Ferrero, A. Lanzini, and M. Santarelli, “Optimal design of stand-alone solutions based on RES+hydrogen storage feeding off-grid communities. Energy Conversion and Management,” vol. 238, no. 114147, p. 114147, 2021.
  • M. Kharrich, S. Kamel, M. Abdeen, O. H. Mohammed, M. Akherraz, T. Khurshaid, and S. B. Rhee,” Developed approach based on equilibrium optimizer for optimal design of hybrid PV/Wind/Diesel/Battery microgrid in Dakhla, Morocco. IEEE Access, vol. 9, pp. 13655-13670, 2021.
  • F. Wang, J. Xu, L. Liu, G. Yin, J. Wang, and J. Yan, “Optimal design and operation of hybrid renewable energy system for drinking water treatment,” Energy, vol. 219, no. 119673, p. 119673, 2021.
  • Z. Ullah, M. R. Elkadeem, K. M. Kotb, I. B. Taha, and S. Wang, “Multi-criteria decision-making model for optimal planning of on/off-grid hybrid solar, wind, hydro, biomass clean electricity supply,” Renewable Energy, vol. 179, pp. 885-910, 2021.
  • F. Kahwash, A. Maheri, and K. Mahkamov, “Integration and optimisation of high-penetration Hybrid Renewable Energy Systems for fulfilling electrical and thermal demand for off-grid communities,” Energy Conversion and Management, vol. 236, no. 114035, 2021.
  • M. El Zein and G. Gebresenbet, “Investigating off-grid systems for a mobile automated milking facility,” Heliyon, vol. 7, no. 4, p. e06630, 2021.
  • A. Borodinecs, D. Zajecs, K. Lebedeva, and R. Bogdanovics, “Mobile Off-Grid Energy Generation Unit for Temporary Energy Supply”. Applied Sciences, vol. 12(2), no. 673, p. 673, 2022.
  • S. K. A. Shezan, S. Julai, M.A. Kibria, K.R. Ullah, R. Saidur, W.T. Chong, and R.K. Akikur, “Performance analysis of an off-grid wind-PV (photovoltaic)-dieselbattery hybrid energy system feasible for remote areas”, Journal of Cleaner Production vol.125, pp. 121-132, 2016.
  • “Pvsyst”, http://www.pvsyst.com/en/. [Accessed: 15-May-2022].
  • “GEPA”, https://gepa.enerji.gov.tr/MyCalculator/pages/46.aspx. [Accessed: 15-May-2022].

An investigation of optimal power system designs for a net zero energy house: A case study of Kahramanmaras

Year 2022, Volume: 11 Issue: 4, 971 - 982, 31.12.2022
https://doi.org/10.17798/bitlisfen.1129632

Abstract

This paper aims to optimize the power system design of a vineyard house in Pazarcık, Kahramanmaras. In this process, the electrical energy demand is met by the hybrid Photovoltaic-Wind-Diesel-Battery system because the vineyard house is remote from the electric network. The vineyard house is located in Karagol, southern of Pazarcık. During the summer in Karagol, many people stay in and visit the vineyard houses. However, the vineyard houses are generally unoccupied in winter. Therefore, an economical energy source is required in this process without compromising life quality. Capital costs are high and the running costs are low for stand-alone renewable sources. On the other hand, it is the opposite for stand-alone diesel power generators. This study is designed to take these circumstances into consideration. The optimal design is investigated for a hybrid system of renewable energy sources and a diesel power generator. The Homer software is used during this process. The realized design is evaluated in terms of its technical and environmental aspects. As a result of the study, 6 kW photovoltaic panels, a 1 kW wind turbine, a 1 kW diesel generator, a 2 kW converter, and an optimally sized 8-unit battery system are used to meet the electricity needs of the vineyard house. The renewable energy factor is 99.8% for a vineyard house. This value is an acceptable rate for a net zero energy house. This study shows that the hybrid system meets the house's electric energy demands and has a positive impact on the environment by reducing greenhouse gas emissions.

References

  • P. G. Vasconcelos Sampaio, and M. O. Aguirre Gonzales, “Photovoltaic solar energy: Conceptual framework” Renewable and Sustainable Energy Reviews, vol. 74, pp. 590-601, 2017.
  • A. Kumar, A. Adelodun, and K. H. Kim, “Solar energy: Potential and future prospects,” Renewable and Sustainable Energy Reviews, vol. 82, pp. 894-900, 2018.
  • İ. Çelik, C. Yıldız, and M. Şekkeli, Turkish Journal of Engineering, vol 5, no.2, pp. 89-94, 2021.
  • B. Al-Mhairat and A. Al-Quraan, “Assessment of Wind Energy Resources in Jordan Using Different Optimization Techniques,” Processes, vol. 10, no.1, p. 105, 2022.
  • C. Xiaodong, D. Xilei, and L. Junjie, “Building energy-consumption status worldwide and the state-of-the-art technologies for zero-energy buildings during the past decade,” Energy and Buildings, vol. 128, pp. 198-213, 2016.
  • “Annual energy outlook - U.s. energy Information Administration (EIA),” Eia.gov. [Online]. Available: https://www.eia.gov/outlooks/aeo/. [Accessed: 16-Oct-2022].
  • Commission européenne. Direction générale de la mobilité et des transports, EU energy, transport and GHG emmissions: Trends to 2030 : Reference scenario 2013. Brussels, Belgium: European Commission, 2014.
  • J. Liu, X. Chen, H. Yang, and K. Shan, “Hybrid renewable energy applications in zero-energy buildings and communities integrating battery and hydrogen vehicle storage,” Applied Energy, vol. 290, no. 116733, p. 116733, 2021.
  • A. Sajid and C. M. Jang, "Optimum design of hybrid renewable energy system for sustainable energy supply to a remote island." Sustainability, vol. 12, no. 1280, p. 1280, 2020.
  • J. Liu, Y. Zhou, H. Yang, and H. Wu, “Net-zero energy management and optimization of commercial building sectors with hybrid renewable energy systems integrated with energy storage of pumped hydro and hydrogen taxis,” Applied Energy, vol. 321, no. 119312, p. 119312, 2022.
  • W. Wu and H.M. Skye, "Residential net-zero energy buildings: Review and perspective," Renewable and Sustainable Energy Reviews, vol. 142, no. 110859, p. 110859, 2021.
  • F. Bahramian, A. Akbari, M. Nabavi, S. Esfandi, E. Naeiji, and A. Issakhov, “Design and tri objective optimization of an energy plant integrated with near-zero energy building including energy storage: An application of dynamic simulation,” Sustainable Energy Technologies and Assessments, vol. 47, no. 101419, p.10419, 2021.
  • S. Gorjian, H. Ebadi, G. Najafi, S. S. Chandel, and H. Yildizhan, “Recent advances in net-zero energy greenhouses and adapted thermal energy storage systems,” Sustainable Energy Technologies and Assessments, vol. 43, no. 100940, p. 100940, 2021.
  • J. Liu, H. Yang, and Y. Zhou, “Peer-to-peer energy trading of net-zero energy communities with renewable energy systems integrating hydrogen vehicle storage,” Applied Energy, vol. 298, no. 117206, p. 117206, 2021.
  • N. Sifakis and T. Tsoutsos, “Planning zero-emissions ports through the nearly zero energy port concept,” Journal of Cleaner Production, vol. 286, no. 125448, p. 125448, 2021.
  • A. Arabkoohsar, A. Behzadi, and A.S. Alsagri, “Techno-economic analysis and multi-objective optimization of a novel solar-based building energy system; An effort to reach the true meaning of zero-energy buildings,” Energy Conversion and Management, vol. 232, no. 113858, p. 113858, 2021.
  • S. Arabi-Nowdeh, S. Nasri, P. B. Saftjani, A. Naderipour, Z. Abdul-Malek, H. Kamyab, and A. Jafar-Nowdeh, “Multi-criteria optimal design of hybrid clean energy system with battery storage considering off-and on-grid application,” Journal of Cleaner Production, vol. 290, no. 125808, p. 125808, 2021.
  • K. V. Konneh, H. Masrur, M. L. Othman, N. I. A. Wahab, H. Hizam, H., S. Z. Islam, and T. Senjyu,” Optimal design and performance analysis of a hybrid off-grid renewable power system considering different component scheduling, PV modules, and solar tracking systems,” IEEE Access, vol. 9, pp. 64393-64413, 2021.
  • B. Musa, N. Yimen, S. I. Abba, H. H. Adun, and M. Dagbasi, “Multi-state load demand forecasting using hybridized support vector regression integrated with optimal design of off-grid energy Systems—A metaheuristic approach,” Processes, vol. 9, no. 1166, p. 1166, 2021.
  • H. M. Farh, A. A. Al-Shamma’a, A. M. Al-Shaalan, A. Alkuhayli, A. M. Noman, and T. Kandil, “Technical and economic evaluation for off-grid hybrid renewable energy system using novel bonobo optimizer,” Sustainability, vol. 14, no. 1533, p.1533, 2022.
  • P. Marocco, D. Ferrero, A. Lanzini, and M. Santarelli, “Optimal design of stand-alone solutions based on RES+hydrogen storage feeding off-grid communities. Energy Conversion and Management,” vol. 238, no. 114147, p. 114147, 2021.
  • M. Kharrich, S. Kamel, M. Abdeen, O. H. Mohammed, M. Akherraz, T. Khurshaid, and S. B. Rhee,” Developed approach based on equilibrium optimizer for optimal design of hybrid PV/Wind/Diesel/Battery microgrid in Dakhla, Morocco. IEEE Access, vol. 9, pp. 13655-13670, 2021.
  • F. Wang, J. Xu, L. Liu, G. Yin, J. Wang, and J. Yan, “Optimal design and operation of hybrid renewable energy system for drinking water treatment,” Energy, vol. 219, no. 119673, p. 119673, 2021.
  • Z. Ullah, M. R. Elkadeem, K. M. Kotb, I. B. Taha, and S. Wang, “Multi-criteria decision-making model for optimal planning of on/off-grid hybrid solar, wind, hydro, biomass clean electricity supply,” Renewable Energy, vol. 179, pp. 885-910, 2021.
  • F. Kahwash, A. Maheri, and K. Mahkamov, “Integration and optimisation of high-penetration Hybrid Renewable Energy Systems for fulfilling electrical and thermal demand for off-grid communities,” Energy Conversion and Management, vol. 236, no. 114035, 2021.
  • M. El Zein and G. Gebresenbet, “Investigating off-grid systems for a mobile automated milking facility,” Heliyon, vol. 7, no. 4, p. e06630, 2021.
  • A. Borodinecs, D. Zajecs, K. Lebedeva, and R. Bogdanovics, “Mobile Off-Grid Energy Generation Unit for Temporary Energy Supply”. Applied Sciences, vol. 12(2), no. 673, p. 673, 2022.
  • S. K. A. Shezan, S. Julai, M.A. Kibria, K.R. Ullah, R. Saidur, W.T. Chong, and R.K. Akikur, “Performance analysis of an off-grid wind-PV (photovoltaic)-dieselbattery hybrid energy system feasible for remote areas”, Journal of Cleaner Production vol.125, pp. 121-132, 2016.
  • “Pvsyst”, http://www.pvsyst.com/en/. [Accessed: 15-May-2022].
  • “GEPA”, https://gepa.enerji.gov.tr/MyCalculator/pages/46.aspx. [Accessed: 15-May-2022].
There are 30 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Araştırma Makalesi
Authors

Mustafa Eken 0000-0002-7559-876X

İbrahim Çelik 0000-0001-5923-554X

Early Pub Date December 31, 1899
Publication Date December 31, 2022
Submission Date June 12, 2022
Acceptance Date October 17, 2022
Published in Issue Year 2022 Volume: 11 Issue: 4

Cite

IEEE M. Eken and İ. Çelik, “An investigation of optimal power system designs for a net zero energy house: A case study of Kahramanmaras”, Bitlis Eren Üniversitesi Fen Bilimleri Dergisi, vol. 11, no. 4, pp. 971–982, 2022, doi: 10.17798/bitlisfen.1129632.

Bitlis Eren University
Journal of Science Editor
Bitlis Eren University Graduate Institute
Bes Minare Mah. Ahmet Eren Bulvari, Merkez Kampus, 13000 BITLIS