Imitational Modeling of SPP Electrical Equipment in Various Climatic Conditions

  • Дмитрий [Dmitriy] Андреевич [A.] Харитонов [Kharitonov]
  • Алексей [Aleksey] Геннадьевич [G.] Васьков [Vasykov]
  • Инора [Inora] Назмуллоевна [N.] Айнуллоева [Ainulloyeva]
DOI: https://doi.org/10.24160/1993-6982-2024-4-80-89
Keywords: solar energy, simulation model of solar power plant, modeling, testing, electrical equipment

Abstract

Before starting practical operation of solar power plants, it is required to conduct simulation tests of their electrical equipment under conditions close to real conditions. This paper describes the method of simulation of solar power plants and presents the results of the study of the PV power plant operating under different operating conditions. Using the functionality of the mathematical model of the solar power plant based on the PVLIB library, the verification of the physical and mathematical model of the photovoltaic power plant in a wide range of environmental parameters has been carried out. The principal applicability of the physical and mathematical model available at the National Research University "Moscow Power Engineering Institute" for conducting simulation tests of solar power plants operation under conditions close to real ones is shown.

Information about authors

Дмитрий [Dmitriy] Андреевич [A.] Харитонов [Kharitonov]

Research Engineer of the Laboratory «Control Systems for Solar-diesel Complexes» of Hydro Power Engineering and Renewable Energy Sources Dept., NRU MPEI, e-mail: dimax41@gmail.com

Алексей [Aleksey] Геннадьевич [G.] Васьков [Vasykov]

Ph.D. (Techn.), Head of the Laboratory «Control Systems for Solar-diesel Complexes» of Hydro Power Engineering and Renewable Energy Sources Dept., NRU MPEI, e-mail: VaskovAG@mpei.ru

Инора [Inora] Назмуллоевна [N.] Айнуллоева [Ainulloyeva]

Research Engineer of the Laboratory «Control Systems for Solar-diesel Complexes» of Hydro Power Engineering and Renewable Energy Sources Dept., NRU MPEI, e-mail: AinulloyevaIN@mpei.ru

References

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Для цитирования: Харитонов Д.А., Васьков А.Г., Айнуллоева И.Н. Имитационное моделирование электротехнического оборудования солнечной электростанции в различных климатических условиях // Вестник МЭИ. 2024. № 4. С. 80—89. DOI: 10.24160/1993-6982-2024-4-80-89
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Исследование выполнено в рамках проекта «Системы управления солнечно-дизельными комплексами» при поддержке Министерства науки и высшего образования Российской Федерации (грант № FSWF-2022-0006)
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Конфликт интересов: авторы заявляют об отсутствии конфликта интересов
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1. Holmgren W.F., Hansen C.W., Mikofski M.A. Pvlib Python: a Python Package for Modeling Solar Energy Systems. J. Open Source Software. 2018;3(29):884.
2. Zhang J. Hardware-in-the-loop Simulation of EV Smart Charging in a Distribution Grid [Elektron. Resurs] https://repository.tudelft.nl/file/File_da354330-e319-4697-b44f-9bf117d80f07?preview=1 (Data Obrashcheniya 14.12.2023).
3. Dolara A., Leva S., Manzolini G. Comparison of Different Physical Models for PV Power Output Prediction. Solar Energy. 2015;119:83—99.
4. Operating and Information Manual for PV-Simulator [Elektron. Resurs] https://www.idm-instrumentos.es/files/fuentes/BajaMedia%20potencia/PV-Sim_B_E%20manual.pdf (Data Obrashcheniya 14.12.2023).
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6. Shkuratov A.V. Formirovatel' Analogovykh Vol't-ampernykh Kharakteristik dlya Imitatora Solnechnoy Batarei. Doklady TUSUR. 2018;21;3:93—97. (in Russian).
7. Abd Alrahim Shannan N.M., Yahaya N.Z., Singh B. Single-diode Model and Two-diode Model of PV Modules: a Comparison. Proc. IEEE Control System, Computing and Engineering Intern. Conf. 2013:210—214.
8. Double Diode Model [Elektron. Resurs] https://www.pveducation.org/pvcdrom/characterisation/double-diode-model (Data Obrashcheniya 15.12.2023)
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For citation: Kharitonov D.A., Vasykov A.G., Ainulloyeva I.N. Imitational Modeling of SPP Electrical Equipment in Various Climatic Conditions. Bulletin of MPEI. 2024;4:80—89. (in Russian). DOI: 10.24160/1993-6982-2024-4-80-89
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The Research was Carried out within the Framework of the Project «Solar-diesel Complex Management Systems» with the Support of the Ministry of Science and Higher Education of the Russian Federation (Grant no. FSWF-2022-0006)
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Conflict of interests: the authors declare no conflict of interest
Published
2024-06-18
Issue
No 4 (2024): Вulletin № 4
Section
Energy Systems and Complexes (2.4.5)