Effect of Critical Temperature on the Energy and Exergy of Transcritical Organic Rankine Cycles with Zeotropic Mixture Working Fluids in Low-grade Heat

CSME 2022/06
Volume 43 No.3 : 251-264

Effect of Critical Temperature on the Energy and Exergy of Transcritical Organic Rankine Cycles with Zeotropic Mixture Working Fluids in Low-grade Heat

Jui-Ching Hsieh^a and Ding-Xuan Huang^a
^aDepartment of Mechanical Engineering, National Chin-Yi University of Technology, Taichung, Taiwan 41170, ROC.

Abstract: A thermodynamic analysis model of the transcritical organic Rankine cycle associated with zeotropic mixtures has been developed. This model was employed to investigate the effects of critical mixture temperature on the first and second law efficiencies of thermodynamics, specific power, net-power-to-cost ratio, irreversibility of the components, and exergy loss of the heat source at expander inlet temperatures of 150–190 °C. The results indicate that evaporator irreversibility and exergy loss of the heat source significantly decreased with an increase in the expander inlet temperature and decrease in the mixture critical temperature, which resulted in improved specific power and second law efficiency. However, the condenser irreversibility was increased with a decrease in the mixture critical temperature owing to the effects of condensation pressure for low critical temperature fluid. Based on the analysis, a universal criterion for the temperature difference between the critical temperature and expander inlet temperature on the maximal second law efficiency has been proposed. Finally, the high critical temperature of the mixed fluid is accompanied by a low condensation pressure, resulting in high first law efficiency, low condenser irreversibility and excellent netpower-to-cost ratio.

Keywords: transcritical organic Rankine cycle; zeotropic mixtures; exergy;

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