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Study of the Thermal Regime of Solar Greenhouses for the Individual Purpose for Their Design Features

  • SOLAR INSTALLATIONS AND THEIR APPLICATION
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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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Authors and Affiliations

  1. Institute of Ion-Plasma and Laser Technologies, Academy of Sciences of the Republic of Uzbekistan, 100040, Tashkent, Uzbekistan

    Sh. I. Klychev

  2. National Scientific and Technical Institute of Renewable Energy Sources, Ministry of Energy of the Republic of Uzbekistan, 100084, Tashkent, Uzbekistan

    B. S. Rasakhodzhaev, Zh. Z. Akhadov & U. Z. Akhmadjonov

  3. Kyrgyz-Uzbek International University, 723500, Osh, Kyrgyz Republic

    Ch. A. Adylov

Authors
  1. Sh. I. Klychev
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  2. B. S. Rasakhodzhaev
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  3. Zh. Z. Akhadov
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  4. U. Z. Akhmadjonov
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  5. Ch. A. Adylov
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Corresponding author

Correspondence to B. S. Rasakhodzhaev.

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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

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