乙烯分离与复叠制冷系统用能的综合优化

doi:10.16085/j.issn.1000-6613.2015.12.010

化工进展 ›› 2015, Vol. 34 ›› Issue (12): 4191-4197.DOI: 10.16085/j.issn.1000-6613.2015.12.010

乙烯分离与复叠制冷系统用能的综合优化

张小锋, 湛世辉, 冯霄

中国石油大学(北京)新能源研究院, 北京 102249

收稿日期:2015-06-05 修回日期:2015-07-24 出版日期:2015-12-05 发布日期:2015-12-05
通讯作者: 冯霄,博士,教授,博士生导师,主要研究方向为化工系统工程。E-mailxfeng@cup.edu.cn。
作者简介:张小锋(1986—),男,硕士研究生。
基金资助:
国家重点基础研究发展计划项目(2012CB720500)。

Integrated optimization of ethylene separation process and cascade refrigeration system

ZHANG Xiaofeng, ZHAN Shihui, FENG Xiao

Institute of New Energy, China University of Petroleum(Beijing), Beijing 102249, China

Received:2015-06-05 Revised:2015-07-24 Online:2015-12-05 Published:2015-12-05

摘要/Abstract

摘要： 乙烯装置的分离过程要在低温下进行,由乙烯制冷系统提供所需冷量。乙烯制冷系统为封闭式循环,独立于分离单元之外。将乙烯分离单元与制冷系统同时优化,能有效提高装置用能效率。复叠式制冷级数是当前乙烯工业中使用最为广泛的制冷技术。本文针对乙烯分离过程和配套的复叠制冷系统,采用Aspen Hysys进行模拟并进行(火用)分析,发现系统主要的(火用)损失发生在换热与压缩两部分,其占总(火用)损失的83%,为节能的重点。进而通过夹点技术对冷剂配置进行分析,发现-56℃以上各温位的冷量配置不合理,远超过理论最小值,-56℃以下各温位的冷量基本达到理论最小值。提出了采用多股流换热器的换热网络理论设计方法,并对冷剂进行重新配置,该理论方案可以降低丙烯制冷压缩机约30%的功耗,并节约部分乙烯制冷压缩机功耗,显著降低了乙烯深冷分离能耗。

关键词: 系统工程, (火用), 优化设计, 夹点技术, 乙烯, 复叠制冷

Abstract: The separation process of an ethylene plant should be operated at low temperature,and a refrigeration system supplies the cooling demand. The refrigeration system in an ethylene plant is a closed cycle system independent of the separation process. The energy efficiency can be effectively improved if the separation process and refrigeration system are optimized simultaneously. Cascade refrigerating systems are most widely used in ethylene plants. In this paper,Aspen Hysys is used to simulate and analyze an ethylene separation process with a cascade refrigerating system. The exergy analysis showed lower efficiency of heat exchanger and compressor sections,whose exergy loss contribute 83% of the whole loss of the system. So energy conservation work should focus on the two sections. Then pinch technology is used to analyze refrigerant configuration. It is found that refrigerant usage above -56℃ is far more than the theoretical minimum quantity,and refrigerant usage below -56℃ is reasonable. A novel design method by using multi-pass exchangers for heat exchanger networks is proposed and the refrigerant usage is reconfigured. The new design can reduce about 30% propylene compressor work and some ethylene compressor work consumption,reducing the energy consumption of the ethylene separation significantly.

Key words: systems engineering, exergy, optimal design, pinch, ethylene, cascade refrigerating system

中图分类号:

TQ021.8

张小锋, 湛世辉, 冯霄. 乙烯分离与复叠制冷系统用能的综合优化[J]. 化工进展, 2015, 34(12): 4191-4197.

ZHANG Xiaofeng, ZHAN Shihui, FENG Xiao. Integrated optimization of ethylene separation process and cascade refrigeration system[J]. Chemical Industry and Engineering Progree, 2015, 34(12): 4191-4197.

参考文献

[1] Richard H M,Mark Whitney. Process based mixed refrigrants for ethylene plant:US,005768913A[P].1998.
[2] Vitus Tuan Wei,Qi Ma,James Tzong-chaur Wu. Olefin plant refrigrantion systerm:US,6750113B2[P]. 2004-05-16.
[3] Linnhoff B,Dhole V R. Shaftwork targets for low-temperature process design[J]. Chemical Engineering Science,1992,47(8):2081-2091.
[4] Timmerhaus K D. Simulation of cryogenic refrigerant process:US,005768913A[P]. 1998-06-23.
[5] Kanoglu M. Exergy analysis of multistage cascade refrigeration cycle used for natural gas liquefaction[J]. International Journal of Energy Research,2002,26(8):763-774.
[6] Mehrpooya M,Jarrahian A,Pishvaie M R. Simulation and exergy-method analysis of an industrial refrigeration cycle used in NGL recovery units[J]. International Journal of Energy Research,2006,30(15):1336-1351.
[7] Remeljej C W,Hoadley A F A. An exergy analysis of small-scale liquefied natural gas (LNG) liquefaction processes[J]. Energy,2006,31:2005-2019.
[8] 赵路,杨敬一,徐心茹,等. LNG混合制冷系统有效能分析[J]. 计算机与应用化学,2010(9):1277-1282.
[9] Mahabadipour H,Ghaebi H. Development and comparison of two expander cycles used in refrigeration system of olefin plant based on exergy analysis[J]. Applied Thermal Engineering,2013,50(1):771-780.
[10] Mafi M N,Mousavi S M,Amidpour M. Exergy analysis of multistage cascade low temperature refrigeration systems used in olefin plants[J]. International Journal of Refrigeration,2009,32(2):279-294.
[11] Chang H. Exergy analysis and exergoeconomic analysis of an ethylene process[J]. Tamkang Journal of Science and Engineering,2001,4(2):95-104.
[12] Dinh H,Zhang J,Xu Q. 2012 AIChE Annual Meeting[C]. United States:American Institute of Chemical Engineers,2012.
[13] Krishnadevarajan K,Zhang J,Xu Q. 2011 AIChE Annual[C]. United States:American Institute of Chemical Engineers,2011.
[14] Zhang J,Wen Y,Xu Q. 2010 AIChE Annual Meeting[C]. United States:American Institute of Chemical Engineers,2010.
[15] Zhang J,Xu Q. Cascade refrigeration system synthesis based on exergy analysis[J]. Computers and Chemical Engineering:2011,35(9):1901-1914.
[16] Mafi M,Amidpour M,Naeynian S M M. Comparison of low temperature mixed refrigerant cycles for separation systems[J]. International Journal of Energy Research,2009,33(4):358-377.
[17] Fabrega F M,Rossi J S,d'Angelo J V H. Exergetic analysis of the refrigeration system in ethylene and propylene production process[J]. Energy,2010,35(3):1224-1231.
[18] Abdollahi-Demneh F,Moosavian M A,Omidkhah M R,et al. Calculating exergy in flowsheeting simulators:A HYSYS implementation[J]. Energy,2011,36(8):5320-5327.
[19] Marmolejo-Correa D,Gundersen T. A comparison of exergy efficiency definitions with focus on low temperature processes[J]. Energy,2012,44(1):4774-4789.
[20] Tirandazi B,Mehrpooya M,Vatani A,et al. Exergy analysis of C₂₊ recovery plants refrigeration cycles[J]. Chemical Engineering Research and Design,2011,89(6):676-689.
[21] 冯霄. 化工节能原理与技术[M]. 北京:化学工业出版社,2009.

乙烯分离与复叠制冷系统用能的综合优化

Integrated optimization of ethylene separation process and cascade refrigeration system

PDF (PC)

可视化

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]	李梦圆, 郭凡, 李群生. 聚乙烯醇生产中回收工段第三、第四精馏塔的模拟与优化[J]. 化工进展, 2023, 42(S1): 113-123.
[2]	杨建平. 降低HPPO装置反应系统原料消耗的PSE[J]. 化工进展, 2023, 42(S1): 21-32.
[3]	陈匡胤, 李蕊兰, 童杨, 沈建华. 质子交换膜燃料电池气体扩散层结构与设计研究进展[J]. 化工进展, 2023, 42(S1): 246-259.
[4]	张凤岐, 崔成东, 鲍学伟, 朱炜玄, 董宏光. 胺液吸收-分步解吸脱硫工艺的设计与评价[J]. 化工进展, 2023, 42(S1): 518-528.
[5]	孙玉玉, 蔡鑫磊, 汤吉海, 黄晶晶, 黄益平, 刘杰. 反应精馏合成甲基丙烯酸甲酯工艺优化及节能[J]. 化工进展, 2023, 42(S1): 56-63.
[6]	刘炫麟, 王驿凯, 戴苏洲, 殷勇高. 热泵中氨基甲酸铵分解反应特性及反应器结构优化[J]. 化工进展, 2023, 42(9): 4522-4530.
[7]	谈继淮, 余敏, 张彤彤, 黄能坤, 王梓雯, 朱新宝. 新型栲胶聚丙氧基醚酯的合成及增塑PVC性能[J]. 化工进展, 2023, 42(9): 4847-4855.
[8]	王晨, 白浩良, 康雪. 大功率UV-LED散热与纳米TiO₂光催化酸性红26耦合系统性能[J]. 化工进展, 2023, 42(9): 4905-4916.
[9]	李志远, 黄亚继, 赵佳琪, 于梦竹, 朱志成, 程好强, 时浩, 王圣. 污泥与聚氯乙烯共热解重金属特性[J]. 化工进展, 2023, 42(9): 4947-4956.
[10]	白志华, 张军. 二乙烯三胺五亚甲基膦酸/Fenton体系氧化脱除NO[J]. 化工进展, 2023, 42(9): 4967-4973.
[11]	张智琛, 朱云峰, 成卫戍, 马守涛, 姜杰, 孙冰, 周子辰, 徐伟. 高压聚乙烯失控分解研究进展：反应机理、引发体系与模型[J]. 化工进展, 2023, 42(8): 3979-3989.
[12]	李蓝宇, 黄新烨, 王笑楠, 邱彤. 化工科研范式智能化转型的思考与展望[J]. 化工进展, 2023, 42(7): 3325-3330.
[13]	周龙大, 赵立新, 徐保蕊, 张爽, 刘琳. 电场-旋流耦合强化多相介质分离研究进展[J]. 化工进展, 2023, 42(7): 3443-3456.
[14]	薛凯, 王帅, 马金鹏, 胡晓阳, 种道彤, 王进仕, 严俊杰. 工业园区分布式综合能源系统的规划与调度[J]. 化工进展, 2023, 42(7): 3510-3519.
[15]	孙征楠, 李洪晶, 荆国林, 张福宁, 颜飚, 刘晓燕. EVA及其改性聚合物在原油降凝剂领域的应用[J]. 化工进展, 2023, 42(6): 2987-2998.