过热/过冷对内回热有机朗肯循环影响的热力学分析

doi:10.16085/j.issn.1000-6613.2016.12.008

化工进展 ›› 2016, Vol. 35 ›› Issue (12): 3783-3792.DOI: 10.16085/j.issn.1000-6613.2016.12.008

过热/过冷对内回热有机朗肯循环影响的热力学分析

徐荣吉, 张晓晖, 闫美玉, 王瑞祥, 许淑惠

北京建筑大学北京市建筑能源综合高效综合利用工程技术研究中心, 北京 100044

收稿日期:2016-05-24 修回日期:2016-08-02 出版日期:2016-12-05 发布日期:2016-12-05
通讯作者: 徐荣吉(1981-),男,博士,讲师,研究方向为位太阳能热利用以及传热传质。E-mail:xurongji@bucea.edu.cn。
作者简介:徐荣吉(1981-),男,博士,讲师,研究方向为位太阳能热利用以及传热传质。E-mail:xurongji@bucea.edu.cn。
基金资助:
国家自然科学基金（51506004）、北京市自然科学基金（3162009）及北京市教委科技计划（KM201410016001）项目。

Thermal dynamics analysis on the organic Rankine cycle (ORC) with internal heat regenerator at superheated and subcooling conditions

XU Rongji, ZHANG Xiaohui, YAN Meiyu, WANG Ruixiang, XU Shuhui

Beijing University of Civil Engineering and Architrcture, Beijing Engineering Research Centre of Sustainable Energy and Buildings, Beijing 100044, China

Received:2016-05-24 Revised:2016-08-02 Online:2016-12-05 Published:2016-12-05

摘要/Abstract

摘要： 内回热是简单有效提高有机朗肯循环（ORC）效率的基本方法。由于循环过程的改变，使循环的热力学规律发生了变化。以R245fa为工质，对回热器的回热过程和机理进行了深入分析，提出了基于对数传热温差的内回热器性能计算方法，并利用热力学分析方法，分析了过热温度、过冷温度对内回热有机朗肯循环（IHORC）性能的影响。研究结果发现，内回热减少了循环的蒸发负荷和冷凝负荷，提高了循环效率。随着过热温度的增加，循环效率和膨胀机输出功均几乎呈线性增加。根据循环过冷温度大小，过冷分为一般过冷和深度过冷两种情况：一般过冷时，随着过冷温度的增加，虽然回热器的换热量和换热效率逐渐升高，但是，循环效率逐渐降低，蒸发负荷、冷凝负荷逐渐增加；深度过冷时，循环效率、回热器换热量、回热器效率快速增加，蒸发负荷和冷凝负荷快速降低，回热器能量回收作用开始突显。一般过冷与深度过冷的临界点是回热器出口蒸气干度，当干度小于1时进入深度过冷状态。内回热过程的“回热量”受限于乏气工质的放热量，因此，内回热循环适用于蒸发冷凝温差大、过热和深度过冷工况。

关键词: 热力学, 有机朗肯循环, 内回热, 过热, 过冷

Abstract: Internal heat recovery is a simple and effective way to improve the thermal performance of basic organic Rankine cycle(ORC). Thermodynamics regularity of the cycle is changed due to the process changes of the cycle. The heat recovery process and mechanism of the internal heat regenerator was deeply analysed and R245fa was used as working fluid. A new method that can calculate the performance of the internal regenerator was proposed based on logarithmic temperature difference. The effects of superheat and subcooling temperature on the thermal performance of the IHORC were thermodynamicly analyzed. The results indicated that the evaporation and condensation load was reduced and the thermal efficiency of the cycle was improved. The cycle efficiency and the expander work output were increased almost linearly with the increase of the superheating temperature. According to the subcooling temperatures,there were two kinds of sulbcooling:subcooling and deep subcooling. Under supercooling condition,cycle efficiency gradually decreased,evaporation and condensation load gradually increased with the increase of the subcooling temperature though the heat transfer and efficiency of the regenerator gradually increased. Under deep supercooling condition,for the reason of the heat recovery the cycle efficiency and the heat transfer and efficiency of the regenerator increased with the decrease of the evaperation and condensation load. The critical point of subcooling and deep subcooling depended on the outlet steam dryness. It was deep subcooling when the dryness of less than 1. The recovered heat was restricted by the exhaust gas. The internal regenerative ORC was suitable for conditions of high temperature difference between evaporation and condensation temperature,overheating and deep subcooling.

Key words: thermaldynamics, organic Rankine cycle, internal heat recovery, superheat, subcooling

中图分类号:

TK124

徐荣吉, 张晓晖, 闫美玉, 王瑞祥, 许淑惠. 过热/过冷对内回热有机朗肯循环影响的热力学分析[J]. 化工进展, 2016, 35(12): 3783-3792.

XU Rongji, ZHANG Xiaohui, YAN Meiyu, WANG Ruixiang, XU Shuhui. Thermal dynamics analysis on the organic Rankine cycle (ORC) with internal heat regenerator at superheated and subcooling conditions[J]. Chemical Industry and Engineering Progree, 2016, 35(12): 3783-3792.

参考文献

[1] HUNG T C,ShAI T Y,Wang S K.A review of organic Rankine cycles(ORCs)for the recovery of low-grade waste heat[J].Energy,1997,22(7):661-667.
[2] HUNG T C.Waste heat recovery of organic Rankine cycle using dry fluids[J].Energy Conversion and Management,2001,42(5):539-553.
[3] DESAI N B,Bandyopadhyay S.Process integration of organic Rankine cycle[J].Energy,2009,34(10):1674-1686.
[4] RAYEGAN R,Tao Y X.A procedure to select working fluids for solar Organic Rankine Cycles (ORCs)[J].Renewable Energy,2011,36(2):659-670.
[5] HUNG T.Triple cycle:a conceptual arrangement of multiple cycle toward optimal energy conversion[J].Journal of Engineering for Gas Turbines and Power,2002,124(2):429-436.
[6] KOROBITSYN M A.New and advanced energy conversion technologies-analysis of cogeneration,combined and integrated cycles[M].Enschede:Febodruk BV,1998.
[7] SOMAYAJI C.First and second law analysis of Organic Rankine Cycle[D].Mississippi:Mississippi State University,2008.
[8] SOMAYAJI C,MAGO P J,CHAMRA L M.Second law analysis and optimization of organic Rankine cycle[C]//Proceedings of the ASME Power Conference,Mississippi,2006:591-596,866.
[9] 张红光,张健,杨凯,等.柴油机全工况下抽气回热式有机朗肯循环系统分析[J].农业机械学报,2014,458(8):19-26.
[10] 张红光,张健,杨凯,等.抽气回热式有机朗肯循环系统热力学分析[J].农业机械学报,2013,44(5):35-40.
[11] 刘强,申爱景,段远源.抽气回热式有机朗肯循环热经济性的定量分析[J].化工学报,2014,65(2):437-444.
[12] 韩中合,叶依林,王璟.分级抽汽回热式太阳能低温有机朗肯循环系统的热力性能分析[J].汽轮机技术,2012(2):81-85.
[13] 韩中合,潘歌,范伟,等.内回热器对低温有机朗肯循环热力性能的影响及工质选择[J].化工进展,2016,35(1):40-47.
[14] 曹园树,胡冰,梁立鹏,等.基于(火用)分析的再热/抽气回热/内回热有机朗肯循环的优化[J].可再生能源,2015,33(5):741-746.
[15] 徐荣吉,席奂,何雅玲.内回热/无回热有机朗肯循环的实验研究[J].工程热物理学报,2013,34(2):205-210.
[16] 顾伟.低品位热能有机物朗肯动力循环机理研究和实验验证[D].上海:上海交通大学,2010.

过热/过冷对内回热有机朗肯循环影响的热力学分析

Thermal dynamics analysis on the organic Rankine cycle (ORC) with internal heat regenerator at superheated and subcooling conditions

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	王胜岩, 邓帅, 赵睿恺. 变电吸附二氧化碳捕集技术研究进展[J]. 化工进展, 2023, 42(S1): 233-245.
[2]	董佳宇, 王斯民. 超声强化对二甲苯结晶特性及调控机理实验[J]. 化工进展, 2023, 42(9): 4504-4513.
[3]	杨许召, 李庆, 袁康康, 张盈盈, 韩敬莉, 吴诗德. 含Gemini离子液体低共熔溶剂热力学性质[J]. 化工进展, 2023, 42(6): 3123-3129.
[4]	马润梅, 杨海超, 李正大, 李双喜, 赵祥, 章国庆. 表面强化镀层对高速轴承腔密封端面变形及摩擦磨损影响分析[J]. 化工进展, 2023, 42(4): 1688-1697.
[5]	贺山明, 潘界昌, 徐国钻, 李文君, 梁勇. 粗钨酸钠溶液亚铁盐沉淀法除铬、钒的热力学分析及实验验证[J]. 化工进展, 2023, 42(4): 2171-2179.
[6]	王晓月, 张伟敏, 姚正阳, 郭晓宏, 李聪明. 逆水煤气变换反应研究进展[J]. 化工进展, 2023, 42(3): 1583-1594.
[7]	孙潇, 朱光涛, 裴爱国. 氢液化装置产业化与研究进展[J]. 化工进展, 2023, 42(3): 1103-1117.
[8]	陈钰, 刘冲, 邱于荟, 贲梓欣, 牟天成. 离子液体和低共熔溶剂绿色回收废旧锂离子电池的研究进展[J]. 化工进展, 2022, 41(S1): 485-496.
[9]	杨瑜锴, 夏永鹏, 徐芬, 孙立贤, 管彦洵, 廖鹿敏, 李亚莹, 周天昊, 劳剑浩, 王瑜, 王颖晶. 赤藓糖醇相变储热材料研究进展[J]. 化工进展, 2022, 41(8): 4357-4366.
[10]	张瑞瑞, 王宁, 高志, 于晓慧, 杨宾. 赤藻糖醇/甘露醇过冷特性分析[J]. 化工进展, 2022, 41(6): 2959-2966.
[11]	王宇晶, 张楠, 刘涉江, 苗辰, 刘秀丽. 热化学清洗含油污泥的效果评价及机理[J]. 化工进展, 2022, 41(6): 3333-3340.
[12]	张凝凝, 丁华, 高燕, 白向飞, 张昀朋, 孙南翔. 新疆淖毛湖煤中钠在CO₂气化过程的迁移行为[J]. 化工进展, 2022, 41(5): 2348-2355.
[13]	马进伟, 方浩, 陈茜茜, 陈海飞, 童维维. 基于焓-熵-㶲平衡的无盖板PV/T系统热力学分析与优化[J]. 化工进展, 2022, 41(4): 1840-1847.
[14]	任首龙, 陆庭中, 唐波, 高颖, 戴远哲, 吉利, 赵胜悟. 辐射冷却材料研究进展[J]. 化工进展, 2022, 41(4): 1982-1993.
[15]	陈磊, 闫兴清, 胡延伟, 于帅, 杨凯, 陈绍云, 关辉, 喻健良, HMAHGEREFTE Haroun, MARTYNOV Sergey. 二氧化碳管道意外泄漏减压过程的断裂控制研究进展[J]. 化工进展, 2022, 41(3): 1241-1255.