1. Thermodynamic analysis of transcritical CO2 refrigeration cycle integrated with thermoelectric subcooler and ejector
- Author
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Xi Liu, Li Lin, Xuelai Li, Zhiqiang Wang, Ruansong Fu, and Zhixin Sun
- Subjects
Exergy ,Materials science ,Renewable Energy, Sustainability and the Environment ,020209 energy ,Energy Engineering and Power Technology ,Thermodynamics ,Refrigeration ,02 engineering and technology ,Injector ,Coefficient of performance ,Discharge pressure ,Transcritical cycle ,law.invention ,Subcooling ,Fuel Technology ,020401 chemical engineering ,Nuclear Energy and Engineering ,law ,Thermoelectric effect ,0202 electrical engineering, electronic engineering, information engineering ,0204 chemical engineering - Abstract
In this paper, the new configuration of transcritical CO2 refrigeration cycle combined with a thermoelectric subcooler and an ejector (TES + EJE) is proposed. The thermoelectric subcooler is installed after the gas cooler in the transcritical CO2 refrigeration cycle with an ejector. Comparisons are carried out with the conventional transcritical CO2 refrigeration cycle (BASE), CO2 cycle with a thermoelectric subcooler (TES) and CO2 cycle with an ejector (EJE). Maximum cooling coefficient of performance (COPc) is obtained for the new TES + EJE cycle with a simultaneous optimization of subcooling temperature and discharge pressure. The improved new cycle exhibits higher COPc and lower discharge pressure compared with the other three cycles. Compared with the BASE cycle, the maximum COPc of the TES + EJE cycle is increased by 39.34% and the corresponding optimum discharge pressure is reduced by 8.01% under given operation conditions of 5 °C evaporation temperature and 40 °C gas cooler outlet temperature. The effects of the subcooling temperature, discharge pressure, gas cooler outlet temperature and evaporation temperature on the TES + EJE system performance are also discussed by energy and exergy analysis and results present here.
- Published
- 2019