Thermodynamic analysis of series and parallel two-stage organic rankine cycle for electricity generation enhancement

2017 International Conference on Sustainable Energy Engineering and Application (ICSEEA) Pub Date : 2017-10-01 DOI:10.1109/ICSEEA.2017.8267681

G. Pikra, Nur Rohmah

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Abstract

The electricity generation of ORC system produces low system performance because of the low heat source temperature. Modification of ORC is used to enhance the performance of ORC system. Series and parallel two-stage ORC (sTORC and PTORC) are two from many ORC configuration that can be used to enhance electricity generation. This paper discusses the thermodynamic analysis of STORC and PTORC to determine the enhancement of electricity generation. Hot spring in Cimanggu, Jawa Barat, Indonesia with 78°C and 70 l/minute of temperature and volume flow rate were used as initial data. R227ea was chosen as organic working fluid for each system. The first and second law of thermodynamics was used for the analysis. Analysis of the first law of thermodynamics is carried out to determine net power output and thermal efficiency of the system. The second law of thermodynamic analysis is carried out to determine exergy efficiency of the system. The result shows that net power output of STORC and PTORC is 5.94 kW and 5.01 kW respectively. Thermal and exergy efficiency of STORC are 6.21% and 6.50%, and 5.24% and 5.49% for PTORC.

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串联和并联两级有机朗肯循环增电的热力学分析

由于热源温度低，ORC系统的发电性能较低。为了提高ORC系统的性能，对ORC进行了改进。串联和并联两级ORC (sTORC和PTORC)是许多ORC配置中的两种，可用于增强发电。本文讨论了STORC和PTORC的热力学分析，以确定发电量的增强。以印尼Jawa Barat的Cimanggu温泉为初始数据，水温为78℃，体积流量为70 l/min。每个系统选择R227ea作为有机工质。利用热力学第一和第二定律进行了分析。通过热力学第一定律的分析，确定了系统的净输出功率和热效率。利用热力学第二定律分析确定了系统的火用效率。结果表明，STORC和PTORC的净输出功率分别为5.94 kW和5.01 kW。STORC的热效率为6.21%，火用效率为6.50%，PTORC的热效率为5.24%，火用效率为5.49%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 International Conference on Sustainable Energy Engineering and Application (ICSEEA)

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