The active design of mixtures based on transition temperature of heat source for organic Rankine cycle

This paper presents a theoretical EEM (exergy efficiency model) to study active design of mixtures based on the transition temperature of heat source for subcritical ORC (organic Rankine cycle). 15 working fluids with critical temperature from 100 °C to 200°C are under evaluation. The exergy efficie...

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Bibliographic Details
Published in:Energy procedia 2019-02, Vol.158, p.1730-1736
Main Authors: Chen, Guibing, An, Qingsong, Zhao, Jun, Chang, Nini, Wang, Yongzhen, Yin, Hongmei, Hu, Likai, Gong, Yulie, Li, Xiaowei
Format: Article
Language:English
Subjects:
Critical temperature
Optimal evaporating temperature(OET)
Organic Rankine Cycle(ORC)
Reverse design
Transition temperature of heat source temperature
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Summary:This paper presents a theoretical EEM (exergy efficiency model) to study active design of mixtures based on the transition temperature of heat source for subcritical ORC (organic Rankine cycle). 15 working fluids with critical temperature from 100 °C to 200°C are under evaluation. The exergy efficiency can be calculated quickly by the latent heat, specific heat at constant pressure and critical temperature based on the EEM. The maximal exergy efficiency will be obtained when the critical temperature of working fluid approaches to the heat source temperature. From the angle of reverse design, the ratios of mixtures can be calculated, whose exergy efficiency is higher than pure working fluids. Under the transition temperature, the exergy efficiency exists the maximum value with the OET. The increase of the OET is monotonous but not linear as the heat source temperature goes up.
ISSN:1876-6102
1876-6102
DOI:10.1016/j.egypro.2019.01.402