Abstract
The aim is to study a mathematical model of optimal control of heat flows of a supply and exhaust ventilation system with a built-in integrated heat exchanger-recuperator. To achieve these goals, the methods of mathematical modeling and the creation of a computational model were used in the work. The automatic control of air conditioning system is based on the principle of feedback. An experimental supply and exhaust system with a plate heat exchanger-recuperator, operates in a quasi-stationary heat transfer mode. Exhaust air removed from the room is used as a heating medium. At the same time, the system is controlled with an independent connection scheme to the heat supply system. The air heated in the room is considered as an incompressible gas, the heat exchange between the heating and heated heat carriers is a stationary process, the turbulence of the heating and heated coolant flows is isotropic. As a result of the study, a mathematical model of heat flow control in the supply and exhaust ventilation system with a built-in integrated heat exchanger-recuperator was obtained. The optimal values of the consumed thermal energy and the parameters of the ventilation system operation are obtained.
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Tyutyunov, D., Burtsev, A., Perepelitsa, N., Burtsev, A. (2023). The Mathematical Model of Automated Control of Heat Flows in the Supply and Exhaust Ventilation System. In: Vatin, N., Pakhomova, E.G., Kukaras, D. (eds) Modern Problems in Construction. Lecture Notes in Civil Engineering, vol 287. Springer, Cham. https://doi.org/10.1007/978-3-031-12703-8_18
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