Thermodynamic Efficiency of Heat Pump Air Conditioning System with Using Mixing Chamber in the Closed Pool on a Hot Season

Authors

DOI:

https://doi.org/10.20535/1810-0546.2016.2.60738

Keywords:

Heat pump, Swimming pool, Air conditioning, Coefficient of performance

Abstract

Background. Removal of a large amount of moisture entering the premises as a result of the evaporation, and temperature and humidity maintenance in the room of the pool is the main problem, which should effectively address heat pump air handling system.

Objective. Objective is the thermodynamic analysis of heat pump air conditioning scheme for the indoor pool on a hot period of the year depending on the parameters of the system and the outside air. The scheme provides for the mixing chamber mounting before, and then after the heat pump.

Methods. The mathematical model of heat pump air conditioning system was built, implementation of which was conducted by numerical method of successive approximations.

Results. The scheme from mixing chamber to the heat pump is characterized by relatively low values of the scheme performance coefficient, due to the relatively high heat load of the heat pump evaporator; the increase of the recycling rate and a significant decrease in the proportion of fresh supply air contributes to the preservation of cold air in the system and increases the coefficient of the entire heat pump air scheme.

Conclusions. Pool heat pump air conditioning system with the recirculation of exhaust air and the mixing chamber after the heat pump in warm or hot season has the highest thermodynamic efficiency by the values of the coefficient of the whole circuit, and the working range of changes in temperature and relative humidity of the outside air.

Author Biographies

Михайло Костянтинович Безродний, National technical university of Ukraine "Kyiv polytechnic institute"

Mykhailo K. Bezrodnyi, doctor of engineering, full professor, professor at the Department of theoretical and industrial heat engineering of Heat Power Department

Дмитро Сергійович Кутра, National technical university of Ukraine "Kyiv polytechnic institute"

Dmytro S. Kutra, Candidate of Engineering Sciences, assistant at the Department of theoretical and industrial heat engineering of Heat Power Department

Ігор Володимирович Сергієнко, National technical university of Ukraine "Kyiv polytechnic institute"

Ihor V. Serhiienko, master at the Department of theoretical and industrial heat engineering of Heat Power Department

References

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Published

2016-03-16

Issue

Section

Art