Journal of Jilin University(Engineering and Technology Edition) ›› 2022, Vol. 52 ›› Issue (8): 1759-1763.doi: 10.13229/j.cnki.jdxbgxb20211464

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Therodynamic performance of compound solar energy gas engine heat pump

Zhen-jun XU1(),Hao WANG2,Kai-yuan ZHAO2,Bo-yi HAO2,Qing-qing LI1,Chang-hao WANG1   

  1. 1.College of Civil Engineering&Architecture,Qingdao Agricultural University,Qingdao 266300,China
    2.Mechanical and Electrical Engineering,Qingdao Institute of Technology,Qingdao 266300,China
  • Received:2021-12-31 Online:2022-08-01 Published:2022-08-12

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Abstract:

Based on the current energy utilization status, taking into account the organic combination of solar energy and gas, the gas engine heat pump system with solar energy was proposed and thermodynamic model was established. Exergy for the components of the system was researched, and the conclusion was drawn. With the water temperature increasing, the exergy of the condenser and the evaporator increasing, the exergy of the compressor reduced, but the exergy of the engine and heat exchanger have little change hardly. With the change of engine speeding, the exergy loss of compressor becomes larger, and the exergy loss of condenser and evaporator also showed a similarity law, but other parts of exergy loss almost unchanged. There is little difference in the variation law of useful energy loss of gas engine heat pump with or without composite solar energy. However, after the solar energy is compound, the configuration power of the gas engine can be reduced, the gas quantity can be reduced, and the useful energy loss value of each component except the solar collector plate is reduced, which is of great significance for reducing the total energy consumption of the system.

Key words: power engineering and engineering thermal physics, gas engine heat pump, solar energy, thermodynamics

CLC Number: 

  • TB61

Fig.1

Compound solar gas machine heat pump system process"

Fig.2

Influence curve of exergy with outlet water temperature on system components"

Fig.3

Influence curve of outlet water temperature on exergy loss proportion for each component"

Fig.4

Effect diagram of speed on exergy loss of system under independent solar power supply"

Fig.5

Effect diagram of speed on exergy loss of system under composite solar energy"

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