КРАТКИЙ АНАЛИЗ ПО МЕТОДУ ИСПАРИТЕЛЬНОГО ОХЛАЖДЕНИЯ ФОТОЭЛЕКТРИЧЕСКИХ ПАНЕЛЕЙ В УСЛОВИЯХ ЖАРКОГО КЛИМАТА

Аннотация

<p><em>В данной статье рассмотрены проблемы связанные с эксплуатацией фотоэлектрических панелей в условиях регионов с жарким и сухим климатом. Проведен краткий анализ работ ранее проведенных исследований в данном направлении. </em></p>
<p><em>Приведен упрощенной расчет снижения рабочих параметров фотоэлектрических панел с повышением температуры окружающей среды. Рассмотрены способы охлаждения фотоэлектрических панел условно разделяемые на активные и пассивные. На примерах указаны преимущества и недостатки того или иного способа охлаждения фотоэлектрических панел.</em><em> Проведён анализ методов испарительного охлаждения </em><em>фотоэлектрических панелей</em><em> для устранения нагрева солнечных элементов.</em></p>

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Литература

1. Х.К. Зайнутдинова Маркетинг солнечной энергии в Узбекистане. Монография. Издательство «Фан» Академии Наук Узбекистана.2011. 186 с.
2. https://www.irena.org/Publications/2024/Mar/Renewable-capacity-statistics-2024
3. https://www.nature.com/articles/s41563-024-01945-6
4. Martin A. Green, Ewan D. Dunlop, Masahiro Yoshita, Nikos Kopidakis, Karsten Bothe, Gerald Siefer, Xiaojing Hao, “Solar cell efficiency tables” https://doi.org/10.1002/pip.3726 21 June 2023
5. https://eenergy.media/news/28191
6. Jurayev Islom, Yuldoshev Isroil, Jurayeva, Zukhra Effects of Temperature on the Efficiency of Photovoltaic Modules// Proceedings of International Conference on Applied Innovation in IT Том 11, Выпуск 1, Стр. 199 – 206, 2023
7. E. Radziemska, “The effect of temperature on the power drop in crystalline silicon solar cells,” Renewable Energy, vol. 28, no. 1, pp. 1–12, 2003.
8. Tian H, Mancilla-David F, Ellis K, Muljadi E and Jenkins P 2012 A cell-to-module-to-array detailed model for photovoltaic panels Sol Energy 86 pp 2695-2706
9. Evans D L 1981 Simplified method for predicting photovoltaic array output Sol Energy 27 pp. 555-60
10. Petreus D, Farcas C and Ciocan I 2008 Modelling and simulation of photovoltaic cells Acta Technica Napocensis, Electronics and Communications 49 pp 42-7
11. Abdel-Basit W, Abdel-Maksood A and Soliman F 2013 Mathematical Model for Photovoltaic Cells Leonardo J Sci 12 pp 13-28
12. Al-Showany E 2016 The impact of the environmental condition on the performance of the photovoltaic cell American Journal of Energy Engineering 4(1) pp 1-7
13. Marcu M, Niculescu T, Slusariuc R and Popescu F 2016 Modeling and simulation of temperature effect in polycrystalline silicon PV cells IOP Conf Ser: Mater Sci Eng 133 012005
14. Chow T.T. February 2010 A review on photovoltaic/thermal hybrid solar technology Applied Energy 87(2):365-379 https://doi.org/10.1016/j.apenergy.2009.06.037
15. Bayrak F, Oztop HF, Selimefendigil F (2019) Effects of different fan parameters on temperature and efficiency for cooling of photovoltaic panels under natural convection. Sol. Energy 188:484–494. https://doi.org/10.1016/j.solener.2019.06.036
16. Tursunov M.N., Dyskin V.G., Yuldashev I.A., Turdiev B.M The influence of convective heat exchange on the temperature of a solar voltaic array//Applied Solar Energy, Том 50, Выпуск 4, pp. 236 – 237.
17. Dosymbetova Gulbakhar, Mekhilef Saad, Saymbetov Ahmet, Nurgaliyev Madiyar, Kapparova Ainur, Manakov Sergey, Orynbassar Sayat, Kuttybay Nurzhigit, Svanbayev Yeldos, Yuldoshev Isroil, Zholamanov Batyrbek, Koshkarbay Nursultan. Modeling and Simulation of Silicon Solar Cells under Low Concentration Conditions//Energies Том 15, Выпуск 24, December 2022
18. И.Р. Жураев, И.А. Юлдошев, К.С. Аюпов, З.И. Жураева Разработка фотоэлектрической установки на основе тонкопленочных модулей в условиях жаркого климата. Монография. Издания ООО “SarvarPrint”, Ташкент. 130 с.
19. El Mays A, Ammar R, Hawa M, Akroush MA, Hachem F, Khaled M, Ramadan M (2017) Improving photovoltaic panel using fnned plate of aluminum. Energy Procedia 119:812–817. https://doi. org/10.1016/j.egypro.2017.07.103
20. Hernandez-Perez JG, Carrillo JG, Bassam A, Flota-Banuelos M, Patino-Lopez LD (2020) A new passive PV heatsink design to reduce efciency losses: a computational and experimental evaluation. Renew Energy 147:1209–1220. https://doi.org/10. 1016/j.renene.2019.09.088
21. Tripanagnostopoulos Y, Themelis P (2010) Natural fow air cooled photovoltaics. AIP Conf Proc 1203:1013–1018. https://doi.org/ 10.1063/1.3322300
22. Wilson E (2009) Theoretical and operational thermal performance of a “wet” crystalline silicon PV module under Jamaican conditions. Renew Energy 34:1655–1660. https://doi.org/10.1016/j.renene. 2008.10.024
23. Mehrotra, S., Rawat, P., Debbarma, M., Sudhakar, K., 2014. Performance of a Solar Panel With Water Immersion Cooling Technique 3, 1161–1172
24. Xin G, Wang Y, Sun Y, Huang Q, Zhu L (2015) Experimental study of liquid-immersion III-V multi-junction solar cells with dimethyl silicon oil under high concentrations. Energy Convers Manag 94:169–177. https://doi.org/10.1016/j.enconman.2015.01.063
25. Saxena A, Deshmukh S, Nirali S, Wani S (2018) Laboratory based experimental investigation of photovoltaic (PV) thermo-control with water and its proposed real-time implementation. Renew Energy 115:128–138. https://doi.org/10.1016/j.renene.2017.08. 029
26. Alizadeh H, Ghasempour R, Shafi MB, Ahmadi MH, Yan WM, Nazari MA (2018) Numerical simulation of PV cooling by using single turn pulsating heat pipe. Int J Heat Mass Transf 127:203–208. https://doi.org/10.1016/j.ijheatmasstransfer.2018.06.108
27. Gang P, Huide F, Tao Z, Jie J (2011) A numerical and experimental study on a heat pipe PV/T system. Sol Energy 85:911–921. https://doi.org/10.1016/j.solener.2011.02.006
28. Shittu S, Li G, Zhao X, Akhlaghi YG, Ma X, Yu M (2019) Comparative study of a concentrated photovoltaic-thermoelectric system with and without fat plate heat pipe. Energy Convers Manag. 193:1–14. https://doi.org/10.1016/j.enconman.2019.04.055
29. Shittu S, Li G, Zhao X, Zhou J, Ma X, Akhlaghi YG (2020) Experimental study and exergy analysis of photovoltaic-thermoelectric with fat plate micro-channel heat pipe. Energy Convers Manag 207:112515. https://doi.org/10.1016/j.enconman.2020.112515