Effect of mass flow rate on performance of organic Rankine cycle forpower generation system with low-temperature waste heat

doi:10.11949/j.issn.0438-1157.20150255

CIESC Journal ›› 2015, Vol. 66 ›› Issue (10): 4185-4192.DOI: 10.11949/j.issn.0438-1157.20150255

Previous Articles Next Articles

Effect of mass flow rate on performance of organic Rankine cycle forpower generation system with low-temperature waste heat

WANG Hui^1,2, MA Xinling¹, MENG Xiangrui¹, WEI Xinli¹

1 School of Chemical Engineering and Energy, Zhengzhou University, Zhengzhou 450001, Henan, China;
2 Mechanical and Electronic Engineering Department, Henan Polytechnic, Zhengzhou, 450046, Henan, China

Received:2015-03-02 Revised:2015-05-22 Online:2015-10-05 Published:2015-10-05
Supported by:
supported by the Key Scientific and Technological Project of Henan Province (142102210072), the Education Department of Henan Province Science and Technology Research Projects (14A480009).

工质流量对ORC低温余热发电系统性能的影响

王慧^1,2, 马新灵¹, 孟祥睿¹, 魏新利¹

1 郑州大学化工与能源学院, 河南郑州 450001;
2 河南职业技术学院机电工程系, 河南郑州 450046

通讯作者: 魏新利
基金资助:
河南省重点科技攻关计划项目(142102210072);河南省教育厅科学技术研究重点项目(14A480009)。

Abstract

Abstract:

An experimental prototype of organic Rankine cycle (ORC) was built for low-temperature waste heat power generation. With R123 as working fluid, heat transfer oil as the waste heat source, and radial inflow turbine as expander, a series of tests were carried out by adjusting the R123 mass flow rate to evaluate the performance of apparatus and system. The temperature rise and entropy increase of hydraulic diaphragm pump were lower, and consumed power increased with the mass flow rate. The pressure drop in the evaporator was greater than that in the condenser, and both increased with the mass flow rate of R123. The isentropic efficiency of the radial inflow turbine increased first and then decreased with the increase of R123 flow rate, with the maximum value of 0.775 kg·s^-1 and the optimum value of 0.215 kg·s^-1. The system output power increased monotonously to 2.009 kW as the flow rate of R123 increased to 0.283 kg·s^-1. Exergy destruction rate of evaporator was the largest parts in total exergy destruction rate, followed by condenser and radial inflow turbine, about 62%, 32% and 6%, respectively, under the optimum condition.

Key words: organic Rankine cycle, waste heat power generation, entropy, thermodynamics, exergy

摘要：

搭建了以自行研发的向心透平为膨胀机的ORC低温余热发电系统实验平台,研究了R123质量流量对循环系统的性能影响。结果表明:液压隔膜泵的温升和熵增均较小,所消耗的功率随流量的增加而增加。工质在蒸发器内的压降明显大于冷凝器内的压降,均随流量的增加而增加;向心透平的等熵效率随质量流量的增加先增加后减小,存在最佳流量0.215 kg·s^-1使透平等熵效率达到最大值0.775;系统输出的电功率随流量的增加而增加,流量为0.283 kg·s^-1时输出系统最大功率为2.009 kW;蒸发器的(火用)损率占系统总(火用)损率的比重最大,冷凝器次之,向心透平第三,在本实验最佳质量流量下,三者的(火用)损率分别为62%、32%、6%。

关键词: 有机朗肯循环, 余热发电, 熵, 热力学, (火用)

CLC Number:

TK11⁺5

WANG Hui, MA Xinling, MENG Xiangrui, WEI Xinli. Effect of mass flow rate on performance of organic Rankine cycle forpower generation system with low-temperature waste heat[J]. CIESC Journal, 2015, 66(10): 4185-4192.

王慧, 马新灵, 孟祥睿, 魏新利. 工质流量对ORC低温余热发电系统性能的影响[J]. 化工学报, 2015, 66(10): 4185-4192.

References 20

[1]	Dai Yiping, Wang Jiangfeng, Gao Lin. Parametric optimization and comparative study of organic Rankine cycle (ORC) for low grade waste heat recovery [J]. Energy Conversion and Management, 2009, 50: 576-582.
[2]	Wei Donghong, Lu Xuesheng, Lu Zhen, Gu Jianming. Performance analysis and optimization of organic Rankine cycle (ORC) for waste heat recovery [J]. Energy Conversion and Management, 2007, 48: 1113-1119.
[3]	Li Jing (李晶), Pei Gang (裴刚), Ji Jie (季杰). Analysis of key factors in low-temperature solar-thermal-electric power generation with organic Rankine cycle [J]. CIESC Journal (化工学报), 2009, 60 (4): 826-832.
[4]	Wang Zhiqi (王志奇), Zhou Naijun (周乃君), Xia Xiaojun (夏小君), Wang Xiaoyuan (王晓元). Multi-obj active parametric optimization of power generation system based on organic Rankine cycle [J]. CIESC Journal (化工学报), 2013, 64 (5): 1710-1716.
[5]	Zhang Junhui (张军辉), Liu Juanfan (刘娟芳), Chen Qinghua (陈清华). Optimal evaporating temperature and exergy analysis for organic Rankine cycle [J]. CIESC Journal (化工学报), 2013, 64 (3): 820-826.
[6]	Quoilin S, Declaye S, Tchanche B F, Lemort V. Thermoeconomic optimization of waste heat recovery organic Rankine cycles [J]. Applied Thermal Engineering, 2011, 31 (14/15): 2885-2893.
[7]	Declaye S, Quoilin S, Guillaume L, Lemort V. Experimental study on an open-drive scroll expander integrated into an ORC (organic Rankine cycle) system with R245fa as working fluid [J]. Energy, 2013, 55: 173-183.
[8]	Lemort V, Quoilin S, Cuevas C, Lebrun J. Testing and modeling a scroll expander integrated into an organic Rankine cycle [J]. Applied Thermal Engineering, 2009, 29: 3094-3102.
[9]	Liu Guangbin (刘广彬), Zhao Yuanyang (赵远扬), Li Liansheng (李连生), Shu Pengcheng (束鹏程). Performances analysis of small low temperature waste heat power generation system [J]. Journal of Engineering Thermophysics (工程热物理学报), 2011, 32 (2): 186-189.
[10]	Li Maoqing, Wang Jiangfeng, He Weifeng, Gao Lin, Wang Bo, Ma Shaolin, Dai Yiping. Construction and preliminary test of a low-temperature regenerative organic Rankine cycle (ORC) using R123 [J]. Renewable Energy, 2013, 57: 216-222.
[11]	Wang X D, Zhao L, Wang J L. Experimental investigation on the low-temperature solar Rankine cycle system using R245fa [J]. Energy Conversion and Management, 2011, 52: 946-952.
[12]	Wang X D, Zhao L, Wang J L, Zhang W Z, Zhao X Z, Wu W. Performance evaluation of a low-temperature solar Rankine cycle system utilizing R245fa [J]. Solar Energy, 2010, 84: 353-364.
[13]	Liu Linding (刘林顶). Research on the single screw expander and organic Rankine cycle system [D]. Beijing: Beijing University of Technology, 2010.
[14]	Cipollonea R, Bianchia G, di Battistaa D, Contaldib G, Murgiab S. Mechanical energy recovery from low grade thermal energy sources [J]. Energy Procedia, 2014, 45: 121-130.
[15]	Yamamoto T, Furuhata T, Arai N, Mori K. Design and testing of the organic Rankine cycle [J]. Energy, 2001, 26 (3): 239-251.
[16]	Pei Gang, Li Yunzhu, Li Jing, Ji Jie. Performance evaluation of a micro turbo-expander for application in low-temperature solar electricity generation [J]. Journal of Zhejiang University-SCIENCE A, 2011, 12 (3): 207-213.
[17]	Pei Gang, Li Jing, Li Yunzhu, Wang Dongyue, Ji Jie. Construction and dynamic test of a small-scale organic Rankine cycle [J]. Energy 2011, 36:3215-3223.
[18]	Kang S H. Design and experimental study of ORC (organic Rankine cycle) and radial turbine using R245fa working fluid [J]. Energy, 2012,41: 514-524.
[19]	Li Jing (李晶). Experimental study and numerical optimization of low-temperature solar organic Rankine cycle thermal power generation system [D]. Hefei: University of Science and Technology of China, 2011.
[20]	Ma Xinling (马新灵), Meng Xiangrui (孟祥睿), Wei Xinli (魏新利), Wang Hui (王慧), Yang Kaixuan (杨凯旋). Design and performance study of radial inflow turbine used on organic Rankine cycle waste heat power generation system [J]. Proceedings of the CSEE (中国电机工程学报), 2014, 34 (5): 2289-2296.

Effect of mass flow rate on performance of organic Rankine cycle forpower generation system with low-temperature waste heat

工质流量对ORC低温余热发电系统性能的影响

PDF (PC)

Knowledge

Cited

Abstract

Cite this article

share this article

References 20

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Xin YANG, Wen WANG, Kai XU, Fanhua MA. Simulation analysis of temperature characteristics of the high-pressure hydrogen refueling process [J]. CIESC Journal, 2023, 74(S1): 280-286.
[2]	Minghui CHANG, Lin WANG, Jiajia YUAN, Yifei CAO. Study on the cycle performance of salt solution-storage-based heat pump [J]. CIESC Journal, 2023, 74(S1): 329-337.
[3]	Zhenghao JIN, Lijie FENG, Shuhong LI. Energy and exergy analysis of a solution cross-type absorption-resorption heat pump using NH₃/H₂O as working fluid [J]. CIESC Journal, 2023, 74(S1): 53-63.
[4]	Jianbo HU, Hongchao LIU, Qi HU, Meiying HUANG, Xianyu SONG, Shuangliang ZHAO. Molecular dynamics simulation insight into translocation behavior of organic cage across the cellular membrane [J]. CIESC Journal, 2023, 74(9): 3756-3765.
[5]	Manzheng ZHANG, Meng XIAO, Peiwei YAN, Zheng MIAO, Jinliang XU, Xianbing JI. Working fluid screening and thermodynamic optimization of hazardous waste incineration coupled organic Rankine cycle system [J]. CIESC Journal, 2023, 74(8): 3502-3512.
[6]	Guang WANG, Fashun SHAN, Yucheng QIAN, Jianfang JIAO. Incipient fault detection method for chemical process based on ensemble learning transfer entropy [J]. CIESC Journal, 2023, 74(7): 2967-2978.
[7]	Xueyan WEI, Yong QIAN. Experimental study on the low to medium temperature oxidation characteristics and kinetics of micro-size iron powder [J]. CIESC Journal, 2023, 74(6): 2624-2638.
[8]	Yurong DANG, Chunlan MO, Kerui SHI, Yingcong FANG, Ziyang ZHANG, Zuoshun LI. Comprehensive evaluation model combined with genetic algorithm for the study on the performance of ORC system with zeotropic mixture [J]. CIESC Journal, 2023, 74(5): 1884-1895.
[9]	Yuanjing MAO, Zhi YANG, Songping MO, Hao GUO, Ying CHEN, Xianglong LUO, Jianyong CHEN, Yingzong LIANG. Estimation of SAFT-VR Mie equation of state parameters and thermodynamic properties of C₆—C₁₀ alcohols [J]. CIESC Journal, 2023, 74(3): 1033-1041.
[10]	Yujun MA, Xiangjun LIU. Theoretical studies of water recovery from flue gas by using ceramic membrane [J]. CIESC Journal, 2022, 73(9): 4103-4112.
[11]	Jinyu GUO, Zhe WANG, Yuan LI. Fault detection method based on kernel entropy independent component analysis [J]. CIESC Journal, 2022, 73(8): 3647-3658.
[12]	Hongchao LIU, Suhang CHEN, Xianli DUAN, Fan WU, Xiaofei XU, Xianyu SONG, Shuangliang ZHAO, Honglai LIU. Transport behavior of Janus graphene quantum dots in biomembrane: a molecular dynamics simulation [J]. CIESC Journal, 2022, 73(7): 2835-2843.
[13]	Jian CAO, Nannan YE, Guancong JIANG, Yao QIN, Shibo WANG, Jiahua ZHU, Xiaohua LU. Mass transfer resistance analysis of the interaction between porous carbon and hydrogen peroxide based on microcalorimetry [J]. CIESC Journal, 2022, 73(6): 2543-2551.
[14]	Miao LI, Hong ZHAO, Biao JIANG, Siyuan CHEN, Long YAN. Thermodynamic analysis on synthesis of key intermediate BaC₂ in coal to acetylene [J]. CIESC Journal, 2022, 73(5): 1908-1919.
[15]	Xue FU, Tingting CHEN, Tingting CHEN, Yingjie XU. Research progress on the conductivity properties of ionic liquids [J]. CIESC Journal, 2022, 73(5): 1883-1893.