基于状态空间超级结构的多流股换热网络最优设计

doi:10.3969/j.issn.0438-1157.2014.06.028

化工学报 ›› 2014, Vol. 65 ›› Issue (6): 2156-2164.DOI: 10.3969/j.issn.0438-1157.2014.06.028

基于状态空间超级结构的多流股换热网络最优设计

李永强¹, 王兵^1,2, 邹雄¹, 董宏光¹, 姚平经¹

1. 大连理工大学化工学院, 辽宁大连 116024;
2. 中国石油天然气股份有限公司炼油与化工分公司, 北京 100007

收稿日期:2013-09-29 修回日期:2013-12-21 出版日期:2014-06-05 发布日期:2014-06-05
通讯作者: 董宏光
作者简介:李永强（1990- ），男，硕士研究生。
基金资助:
国家自然科学基金项目（21276039）。

Optimal design of multistream heat exchanger network based on state space superstructure

LI Yongqiang¹, WANG Bing^1,2, ZOU Xiong¹, DONG Hongguang¹, YAO Pingjing¹

1. School of Chemical Engineering, Dalian University of Technology, Dalian 116024, Liaoning, China;
2. Refining and Chemicals Company, PetroChina, Beijing 100007, China

Received:2013-09-29 Revised:2013-12-21 Online:2014-06-05 Published:2014-06-05
Supported by:
supported by the National Natural Science Foundation of China(21276039).

摘要/Abstract

摘要： 多流股换热器以其结构紧凑、高效低耗等特点，成为过程强化研究的热门领域，但对于多流股换热的过程与设备优势所在仍然值得商榷。基于多流股换热匹配改进状态空间超级结构，将多流股换热网络综合转化为超级换热器设计。首先，构造级联多流股换热器匹配过程操作算子，通过相邻换热流股匹配，传递温位效应，实现多流股间传热严格计算；借助热容流率混合分配机制，实现各流股间任意分混操作。然后，考虑散热因素，改进目标函数，引入冷热损失和保温材料费用项，清晰体现多流股换热器因换热面互相覆盖而带来的外表面封包优势。进而，建立相应非线性数学规划模型，实现公用工程、设备投资、冷热损耗同步优化。最终，通过文献示例对所提方法可行性与优越性进行验证。

关键词: 传热, 多流股换热器, 状态空间超级结构, 模型, 优化设计, 系统工程

Abstract: Multistream heat exchanger (MHEX) has attracted attention in the process intensification field with its compact structure, high efficiency and low heat loss. However, the potential advantages of its process and equipment are still worth discussing. An improved State-space superstructure based on MHEXs process operator (PO) was proposed to convert the network synthesis into a super-exchanger design. Hierarchy matching MHEXs PO was constructed, and the strict heat transfer calculation among multiple streams was implemented through temperature coordinated effect between adjacent streams. Arbitrary splitting and mixing of any stream was achieved by corresponding mixers and splitters in distribution network (DN). The objective function was ameliorated by taking heat loss into consideration. Through introducing the cost of heat loss and thermal insulation material, the external surface envelope advantage of MHEX was presented clearly owing to coverage between adjacent heat-transfer surfaces. Then, a corresponding nonlinear programming (NLP) mathematical model was formulated for generating the optimal design of MHEXs network while synthesizing the utilities, equipment investment, heat loss and thermal insulation material simultaneously. At last, four case studies were performed to verify the feasibility and superiority of the methodology.

Key words: heat transfer, multistream exchanger, state-space superstructure, model, optimal design, systems engineering

中图分类号:

TQ021.8

李永强, 王兵, 邹雄, 董宏光, 姚平经. 基于状态空间超级结构的多流股换热网络最优设计[J]. 化工学报, 2014, 65(6): 2156-2164.

LI Yongqiang, WANG Bing, ZOU Xiong, DONG Hongguang, YAO Pingjing. Optimal design of multistream heat exchanger network based on state space superstructure[J]. CIESC Journal, 2014, 65(6): 2156-2164.

参考文献 23

[1]	Boehme R,Parise J A R, Marques R P. Simulation of multistream plate-fin heat exchangers of an air separation unit [J]. Cryogenics, 2003, 43:325-334
[2]	Ghosh I, Sarangi S K, Das P K. An alternate algorithm for the analysis of multistream plate fin heat exchangers [J]. Heat Mass Transfer, 2006, 49:2889-2902
[3]	Ghosh I, Sarangi S K, Das P K. Synthesis of multistream heat exchangers by thermally linked two-stream modules [J]. Heat Mass Transfer, 2010, 53:1070-1078
[4]	Picon-Nunez M, Polley G T, Medina-Flores M. Thermal design of multi-stream heat exchangers[J]. Applied Thermal Engineering, 2002, 22:1643-1660
[5]	Tahouni Nassim, Miryahyaie Samira, Joda Fatemeh, Fallahi Hamid Reza,Hassan Mohammad. Pressure drop optimization in design of multi-stream plate-fin heat exchangers, considering variable physical properties [J]. Canadian Journal of Chemical Engineering, 2013, 91(10):1650-1659
[6]	Joda Fatemeh, Tahouni Nassim, Panjeshahi Mohammad Hassan. Application of genetic algorithms in design and optimization of multi-stream plate-fin heat exchangers [J]. Canadian Journal of Chemical Engineering, 2013, 91(10):870-881
[7]	Xiao Yunhan(肖云汉), Zhu Mingshan(朱明善), Wang Buxuan(王补宣). A comprehensive approach to optimal synthesis of heat exchanger networks [J]. Journal of Chemical Industry and Engineering(China)(化工学报), 1993, 44(6):635-643
[8]	Huo Zhaoyi(霍兆义), Zhao Liang(赵亮), Yin Hongchao(尹洪超), Sun Wence(孙文策). A hybrid swarm intelligence algorithm for simultaneous synthesis of heat exchanger network [J].CIESC Journal(化工学报), 2012, 63(4):1116-1123
[9]	Fang Dajun(方大俊), Cui Guomin(崔国民). Global optimization of heat exchanger networks using differential evolution algorithm [J]. CIESC Journal(化工学报),2013, 64(9): 3285-3290
[10]	Yee T F, Grossmann I E, Kravanja Z. Simultaneous optimization models for heat integration(I):Area and energy targeting and modeling of multi-stream exchangers [J]. Computers and Chemical Engineering, 1990, 10:1151-1164
[11]	Kamath R S, Biegler L T, Grossmann I E. Modeling multistream heat exchangers with and without phase changes for simultaneous optimization and heat integration [J]. AIChE J., 2012, 58:190-204
[12]	Faruque Hasan M M, Karimi I A, Alfadala H E, Grootjans H. Operational modeling of multistream heat exchangers with phase changes [J]. AIChE J., 2009, 55:150-171
[13]	Luo X, Li M, Roetzel W. A general solution for one-dimensional multistream heat exchangers and their networks [J]. Heat Mass Transfer, 2002, 45:2695-2705
[14]	Luo X, Guan X, Li M, Roetzel W. Dynamic behavior of one-dimensional flow multistream heat exchangers and their networks[J]. Heat Mass Transfer, 2003, 46:705-715
[15]	Wei Guanfeng(魏关锋). Multi-stream heat exchanger networks synthesis with genetic/simulated annealing algorithm[D]. Dalian: Dalian University of Technology, 2003
[16]	Wei Guanfeng(魏关锋), Yao Pingjing(姚平经), Luo Xing(罗行), et al. Study on multi-stream heat exchanger networks synthesis with genetic algorithm [J]. Journal of Chemical Engineering of Chinese Universities(高校化学工程学报), 2003, 17(4): 425-430
[17]	Xiao Wu(肖武). Large scale multi-stream heat exchanger network synthesis based on the stream effective temperatureLevel[D]. Dalian: Dalian University of Technology, 2006
[18]	Xiao Wu, Dong Hongguang, Li Xinqiang, Yao Pingjing, Luo Xing, Roetal Wilfried. Synthesis of Large-scale multistream heat exchanger networks based on stream pseudo-temperature [J]. Chinese Journal of Chemical Engineering, 2006, 14(5):574-583
[19]	Xiao Wu, Yao Pingjing, Luo Xing,Roetzel Wilfried. A new and efficient NLP formulation for synthesis large scale multi-stream heat exchanger networks [J]. Journal of the Chinese Institute of Chemical Engineers, 2006, 37(4):383-394
[20]	Yuan Dongwen, Wang Yao, Xiao Wu, Yao Pingjing, Luo Xing, Wilfried Roetzel. An automated method for synthesizing a multi-stream heat exchanger network based on stream pseudo-temperature [J]. Computer Aided Chemical Engineering, 2006, 21:919-924
[21]	Luo Li(罗立). Study on the identification and construction of multi-stream heat exchanger networks[D]. Dalian: Dalian University of Technology, 2004
[22]	Ma Xiangkun(马相坤). Study on flexible synthesis of multi-stream heat exchanger network in the low temperature processes[D]. Dalian: Dalian University of Technology, 2007
[23]	Bagajewicz M J, Manousiouthakis V. Mass/heat-exchange network representation of distillation networks [J]. AIChE J., 1992, 38:1769-1800

基于状态空间超级结构的多流股换热网络最优设计

Optimal design of multistream heat exchanger network based on state space superstructure

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