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How can solar panels collectors enhance energy efficiency? Utilization of the novel optimization techniques

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dc.contributor.author Kuterbekov, Kairat A.
dc.contributor.author Kabyshev, Asset M.
dc.contributor.author Bekmyrza, Kenzhebatyr Zh.
dc.contributor.author Kubenova, Marzhan M.
dc.contributor.author Ayalew, Abebe T.
dc.date.accessioned 2024-10-11T04:41:41Z
dc.date.available 2024-10-11T04:41:41Z
dc.date.issued 2024
dc.identifier.issn 17481317
dc.identifier.other doi.org/10.1093/ijlct/ctae048
dc.identifier.uri http://rep.enu.kz/handle/enu/17644
dc.description.abstract Solar energy, which is widely acknowledged for its economic feasibility and sustainable nature, functions as a critical substitute for finite fossil fuels, effectively alleviating ecological consequences. The purpose of this study is to investigate the implementation of solar collectors as a means of harnessing the ample and unaltered solar radiation in Iran, specifically in locations situated within the solar belt. The incorporation of solar energy not only aids in the expansion of energy sources through diversification but also mitigates the rising expenses linked to fossil fuels. The preservation of natural resources, coupled with limited renewable energy options, further accentuates the importance of solar energy. The optimization of solar panel collector angles in photovoltaic systems assumes paramount importance for maximizing energy efficiency. This study, conducted in Yazd, Iran, utilized innovative mathematical and particle swarm optimization (PSO) models to assess ideal inclination angles. Results indicate peak solar energy absorption during June and July, contrasting with minimal absorption in January. The Klein model prescribes inclination angles based on γ values, while the PSO algorithm determines optimal slope and azimuth angles across various periods. Significant enhancements in energy generation, ranging from 23.24 to 25.02% across optimization models, were observed compared to a horizontal surface. These findings underscore the imperative of optimizing solar panel placement in urban settings to augment energy generation. Utilizing the optimal orientation for the photovoltaic power supply system can result in an annual reduction of 1169.6 kg of CO2 emissions in the building, emphasizing the positive environmental impact achievable through strategic solar panel configurations. ru
dc.language.iso en ru
dc.publisher International Journal of Low-Carbon Technologies ru
dc.relation.ispartofseries 19, 1049–1059;
dc.subject solar panel ru
dc.subject collector ru
dc.subject novel optimization ru
dc.subject energy efficiency ru
dc.subject electricity production ru
dc.subject CO2 emission ru
dc.title How can solar panels collectors enhance energy efficiency? Utilization of the novel optimization techniques ru
dc.type Article ru


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