Abstract
This research examines the current problems systematic approach of energy generation for Russia’s decentralized energy supply areas and looks at potential optimization by implementing a sustainable approach. We evaluate the solutions that could improve both the economic and social development in the Russian Energy sector. Renewable energy sources (RES) can be combined with a hybrid energy system that runs in parallel with different types of energy storage units, taking into account the resource, technical and technological features of their functioning in decentralized power supply systems. Based on our research, we have developed a 3D model of a energy system, which allows one to study its operating modes under real operating conditions. The proposed methods can be used in solving design problems to establish the parameters of decentralized power supply systems for consumers in isolated and decentralized energy supply regions.
REFERENCES
Fortov, V.E. and Popel, O.S., Energetika v sovremennom mire: Nauchnoye izdaniye (Energy in the modern world: Scientific publication), Dolgoprudny: Intellekt, 2011.
Elistratov, V.V., Vozobnovlyayemaya energetika (Renewable Energy), St. Petersburg: Nauka, 2013.
Tyagunov, M.G., Digitalization and management in distributed energy systems with renewable energy sources, Tsifrovaya energetika: novaya paradigma funktsionirovaniya i razvitiya (Digital Energy: A New Paradigm of Functioning and Development), Rogalev, N.D., Ed., Moscow: Mosk. Energ. Inst., 2019, pp. 187–203.
Analytical Center for the Government of the Russian Federation, 2020. https://ac.gov.ru. Accessed March 24, 2020.
Makarov, A.A., Grigoriev, L.M., and Mitrova, T.A., Prognoz razvitiya energetiki mira i Rossii 2016 (Forecast of Energy Development in the World and in Russia 2016), Moscow: Inst. Energ. Issled. Ross. Akad. Sci., 2016.
Moody’s Investors Service, International rating Agency, 2020. https://www.moodys.com. Accessed February 5, 2021.
Elistratov, V.V., Technological and technical and economic features of energy complexes based on renewable energy sources for difficult natural and climatic conditions, 5th International Conference Renewable Energy: Problems and Prospects, 2017, vol. 1, pp. 42–47.
Savin, V. and Rozhenko, S., Cross-subsidization in the Russian electric power industry, International Benchmarking, 2021, p. 64. https://assets.kpmg/content/dam/kpmg/ru/pdf/2020/07/ru-ru-cross-subsidies-in-the-russian-power-industry.pdf.
Tyagunov, M.G., Distributed energy system’s is future of the world’s power industry, 2nd International Conference Information Technology to Renewable Energy Processes and Systems, 2017, pp. 113–117.
Shivarama, K.K. and Sathish, K.K., A review on hybrid renewable energy systems, Renewable Sustainable Energy Rev., 2015, vol. 52, pp. 907–916.
Chauhan, A. and Saini, R.P., A review on Integrated Renewable Energy System based power generation for stand-alone applications: Configurations, storage options, sizing methodologies and control, Renewable Sustainable Energy Rev., 2014, vol. 38, pp. 99–120.
Tyagunov, M.G. and Vikulov, A.N., Renewable energy in distributed power systems, Santekhnika, Otopleniye, Konditsionirovaniye, 2018, no. 7, pp. 76–77.
Obukhov, S.G., Plotnikov, I.A., and Masolov, V.G., Analysis of the operating modes of energy storage units in autonomous hybrid power plants with renewable energy sources, Al’tern. Energ. Ekol., 2018, nos. 13–15, pp. 55–67.
Barton, J.P. and Infield, D.G., Energy storage and its use with intermittent renewable energy, Trans. Energy Convers., 2004, vol. 19, pp. 441–448.
Gan, L.K., Shek, J.K.H., and Mueller, M.A., Hybrid wind-photovoltaic-diesel-battery system sizing tool development using empirical approach, life-cycle cost and performance analysis: A case study in Scotland, Energy Convers. Manage., vol. 106, pp. 479–494, 2015.
Bianchini, A., Optimization of a PV-wind-diesel hybrid system for a remote stand-alone application, Energy Procedia, 2015, vol. 81, pp. 133–144.
Ani, V., Design of a reliable hybrid (PV/diesel) power system with energy storage in batteries for remote residential home, 2019. https://doi.org/10.1155/2016/6278138
Elbaset Mohamed, A.A., Abdelwahab, S.A.M., and Ibrahim, H.A., Performance Analysis of Photovoltaic Systems with Energy Storage Systems, Cham: Springer Nature, 2019.
Tyagunov, M.G. and Sheverdiev, R.P., Features of the modes of hybrid energy complexes based on renewable energy sources for determining the type of energy storage batteries, Vestn. Mosk. Energ. Inst., 2020, no. 4, pp. 62–70.
Abd Ali, L.M., Al-Rufai, F.M., Kuvshinov, V.V., Crete, B.L., Al-Antaki, A.M., and Morozova, N.V., Study of the hybrid wind-solar systems for the Iraqi energy complex, Appl. Sol. Energy, 2020, no. 3, pp. 285–296.
Kuvshinov, V.V., Kolomiychenko, V.P., Kakushina, E.G., Abdali, L.M., and Kuvshinova, V.V., System storage for solar plants, Appl. Sol. Energy, 2019, no. 2, pp. 111–122.
Chemezov, A.V., Strakhov, A.G., and Bakshaeva, N.M., Algorithm of optimization of multi-agent isolated energy systems, Appl. Sol. Energy, 2018, no. 6, pp. 56–61.
Sheverdiev, R.P., Hybrid energy complex of guaranteed energy supply with energy storage, 10th International School-Seminar for Young Scientists and Specialists: Energy Saving. Theory and Practice, 2020, pp. 351–356.
Obukhov, S.G. and Plotnikov, I.A., A simulation model of the operating modes of an autonomous photovoltaic power plant, taking into account real operating conditions, Vestn. Tomsk Politekh. Univ. Inzh. Geores., 2017, no. 6, pp. 38–51.
Vissarionov, V.I., Deryugina, G.V., and Kuznetsova, V.A., Solnechnaya energetika (Solar Energy), Moscow: Mosk. Energ. Inst., 2008.
Beckman, W., Klein, S., and Duffie, J., Solar Heating Design, New York: Wiley, 1977.
NASA database, 2021. https://power.larc.nasa.gov/data-access-viewer.
RP5–Weather Schedule, 2021. https://rp5.ru.
Hevel Group, 2021. https://www.hevelsolar.com.
Vaskov, A.G., Deryugina, G.V., Karpov, N.D., and Chernov, D.A., Tekhniko-ekonomicheskoe obosnovanie vetrovoi elektrostantsii v sostave vetrodizel’nogo kompleksa (Feasibility Study of a Wind Farm as Part of a Wind-Diesel Complex), Moscow: Mosk. Energ. Inst., 2018.
Funding
This work was supported by an internal grant from the NRU “MPEI” in the framework of the implementation of priority scientific and technical projects from the program of scientific research “Energy” (1st stage) (Order dated July 26, 2019 no. 459).
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Tyagunov, M.G., Sheverdiev, R.P. Hybrid Energy System of Guaranteed Power Supply to Isolated and Remote Consumers. Appl. Sol. Energy 58, 583–593 (2022). https://doi.org/10.3103/S0003701X22040168
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DOI: https://doi.org/10.3103/S0003701X22040168