Design and simulation of a hybrid system based on renewable energy for hydrogen production
Abstract
Transitioning to renewable energy is part of the answer to, on the one hand, growing industrial development and the rising demand for energy and, on the other, environmental concerns and the need to preserve fossil fuel resources for future generations. This research focuses on the potential for integrating hydrogen storage into a highly reliable renewable energy system. The purpose of this study is to determine the potential of renewable energy in an Iranian location, in a project that looks at a power grid in various connected and disconnected scenarios involving hydrogen storage. The energy potential is identified: annual production capacity is 2218818 kW, requiring a total investment outlay of US$697,624.References
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[15] Sema Z. Baykara. Hydrogen: A brief overview on its sources production and environmental impact. International Journal of Hydrogen Energy, 43(23):10605–10614, jun 2018.
[16] Z. Abdin and W. M´erida. Hybrid energy systems for off-grid power supply and hydrogen production based on renewable energy: A technoeconomic analysis. Energy Conversion and Management, 196:1068–1079, sep 2019.
[17] Tanay Sıdkı Uyar and Dog˘ancan Be¸sikci. Integration of hydrogen energy systems into renewable energy systems for better design of 100% renewable energy communities. International Journal of Hydrogen Energy, 42(4):2453–2456, jan 2017.
[18] Mohammad Amin Vaziri Rad, Roghaye Ghasempour, Parisa Rahdan, Soroush Mousavi, and Mehrdad Arastounia. Techno-economic analysis of a hybrid power system based on the costeffective hydrogen production method for rural electrification a case study in Iran. Energy, 190:116421, jan 2020.
[19] Hoarca Cristian, Nicu Bizon, and Badita Alexandru. Design of hybrid power systems using HOMER simulator for different renewable energy sources. In 2017 9th International Conference on Electronics Computers and Artificial Intelligence (ECAI). IEEE, jun 2017.
[20] Annamaria Buonomano, Francesco Calise, Massimo Dentice d'Accadia, and Maria Vicidomini. A hybrid renewable system based on wind and solar energy coupled with an electrical storage: Dynamic simulation and economic assessment. Energy, 155:174–189, jul 2018.
[21] Weiping Zhang, Akbar Maleki, Marc A. Rosen, and Jingqing Liu. Optimization with a simulated annealing algorithm of a hybrid system for renewable energy including battery and hydrogen storage. Energy, 163:191–207, nov 2018.
[22] Yag˘mur Budak and Yılser Devrim. Comparative study of PV/PEM fuel cell hybrid energy system based on methanol and water electrolysis. Energy Conversion and Management, 179:46–57, jan 2019.
[23] O. H. Mohammed, Y. Amirat, M. E. H. Benbouzid, and G. Feld. Optimal Design and Energy Management of a Hybrid Power Generation System Based on Wind/Tidal/PV Sources: Case Study for the Ouessant French Island. In Smart Energy Grid Design for Island Countries, pages 381–413. Springer International Publishing, 2017.
[24] Reza Alayi, Alibakhsh Kasaeian, Atabak Najafi, and Eskandar Jamali. Optimization and evaluation of a wind solar and fuel cell hybrid system in supplying electricity to a remote district in national grid. International Journal of Energy Sector Management, 14(2):408–418, oct 2019.
[25] Murat Go¨kc¸ek and Cihangir Kale. Technoeconomical evaluation of a hydrogen refuelling station powered by Wind-PV hybrid power system: A case study for ˙Izmir-C¸e¸sme. International Journal of Hydrogen Energy, 43(23):10615– 10625, jun 2018.
[26] Kamal Anoune, Mohsine Bouya, Abdelali Astito, and Abdellatif Ben Abdellah. Sizing methods and optimization techniques for PV-wind based hybrid renewable energy system: A review. Renewable and Sustainable Energy Reviews, 93:652– 673, oct 2018.
[27] Sarangthem Sanajaoba Singh and Eugene Fernandez. Modeling size optimization and sensitivity analysis of a remote hybrid renewable energy system. Energy, 143:719–731, jan 2018.
[28] A. Can Duman and Onder Gu¨ler.¨ Technoeconomic analysis of off-grid PV/wind/fuel cell hybrid system combinations with a comparison of regularly and seasonally occupied households. Sustainable Cities and Society, 42:107–126, oct 2018.
[29] Zehra Ural Bayrak, Go¨kay Bayrak, Mahmut Temel Ozdemir, Muhsin Tunay Gencoglu, and Mehmet Cebeci. A low-cost power management system design for residential hydrogen & solar energy based power plants. International Journal of Hydrogen Energy, 41(29):12569– 12581, aug 2016.
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[35] Remy Rigo-Mariani, Chuan Zhang, Alessandro Romagnoli, Markus Kraft, K. V. Ling, and Jan M. Maciejowski. A Combined Cycle Gas Turbine Model for Heat and Power Dispatch Subject to Grid Constraints. IEEE Transactions on Sustainable Energy, pages 1–1, 2019.
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[38] Ahmed Abdelhafez, Sherif S. Rashwan, Medhat A. Nemitallah, and Mohamed A. Habib. Stability map and shape of premixed CH4/O2/CO2 flames in a model gas-turbine combustor. Applied Energy, 215:63–74, 2018.
[39] Serhiy I. Serbin, Igor B. Matveev, and Ganna B.
Mostipanenko. Investigations of the Working Process in a “Lean-Burn” Gas Turbine Combustor With Plasma Assistance. IEEE Transactions on Plasma Science, 39(12):3331–3335, dec 2011.
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Published
2020-12-26
How to Cite
ALAYI, reza et al.
Design and simulation of a hybrid system based on renewable energy for hydrogen production.
Journal of Power Technologies, [S.l.], v. 100, n. 4, p. 331–340, dec. 2020.
ISSN 2083-4195.
Available at: <https://papers.itc.pw.edu.pl/index.php/JPT/article/view/1710>. Date accessed: 26 apr. 2024.
Issue
Section
Electrical Engineering
Keywords
fossil fuel resources, renewable energy, investment cost, hydrogen storage.
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