Abstract
In this paper we have developed a design of an energy-efficient greenhouse with a transformable body, in which, by changing the volume and fuel, energy resources are saved due to the transformation of the body. A heat balance has been compiled according to the scheme of a one-dimensional thermal model of energy-efficient solar greenhouses, in which the “solar radiation–transparent fence–plant–heat accumulator–soil” heat energy transfer scheme occurs. When modeling thermal processes, it is quite possible to create a variability in the climatic regime and ensure optimal air heating inside solar greenhouses with a transformable body. The calculations made show that, depending on the volume inside the greenhouse, energy supply due to solar radiation can be 26–35% in January, which is in full compliance with the regulatory documents submitted by KMK 2.08.09-97.
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ACKNOWLEDGMENTS
The authors express special gratitude to the researchers of the National Research Institute of Renewable Energy Sources under the Ministry of Energy of the Republic of Uzbekistan.
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Translated by L. Solovyova
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Klychev, S.I., Rasakhodzhaev, B.S., Akhadov, Z.Z. et al. Study of the Thermal Regime of Solar Greenhouses for the Individual Purpose for Their Design Features. Appl. Sol. Energy 58, 121–126 (2022). https://doi.org/10.3103/S0003701X22010091
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DOI: https://doi.org/10.3103/S0003701X22010091