Abstract. This article deals with calculating temperature field of the inflatable collector made of polymer materials. The efficiency of the considered power system depends on the intensity of the absorber heating. In its turn, the process of heating coolant is affected by a great number of external environmental factors. The developed mathematical model and program product let the researchers consider various influence degree of each factor separately and in a complex.
Growing plants in extremely cold environmental conditions is a difficult and expensive process. The required microclimate is usually created for plants artificially on the protected ground. For this purpose, we have developed an industrial prototype of a mini greenhouse, which allows to grow single plants. Laboratory tests have confirmed that the mini greenhouse provides optimal internal environment conditions due to the design features. This leads to a significant reduction in the cost of plants growing.
This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.This article presents a study of the temperature field of an inflatable collector made of polymer materials. The efficiency of the power system under consideration depends on the intensity of the absorber heating. In turn, the heating of the coolant is influenced by many external environmental factors. The developed mathematical model and software product allow us to consider the degree of influence of each factor individually and collectively.
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