[1] AND K C F, SAHINIDIS N V. A critical review and annotated bibliography for heat exchanger network synthesis in the 20th century[J]. Ind Eng Chem Res, 2002, 41(10):2335-2370. [2] LINNHOFF B, HINDMARSH E. The pinch design method for heat exchanger networks[J]. Chem Eng Sci, 1983, 38(5):745-763. [3] PAPOULIAS S A, GROSSMANN I E. A structural optimization approach in process synthesis Ⅱ:Heat recovery networks[J]. Comput Chem Eng, 1983, 7(6):707-721. [4] FLOUDAS C A, CIRIC A R, GROSSMANN I E. Automatic synthesis of optimum heat exchanger network configurations[J]. AIChE J, 1986, 32(2):276-290. [5] CERDA J, WESTERBURG A W. Synthesizing heat exchanger networks having restricted stream/stream matches using transportation problem formulations[J]. Chem Eng Sci, 1983, 38(10):1723-1740. [6] XU Y C, CHN Q, GUO Z Y. Entransy dissipation-based constraint for optimization of heat exchanger networks in thermal systems[J]. Energy, 2015, 86:696-708. [7] YEE T F, GROSSMANN I E. Simultaneous optimization models for heat integration Ⅱ:Heat exchanger network synthesis[J]. Comput Chem Eng, 1990, 14(10):1165-1184. [8] CASTIER M. Rigorous multiple utility targeting in heat exchanger networks[J]. Energy Convers Mgmt, 2012, 59(3):74-85. [9] LOTFI R, BOOZARJOMEHRY R B. Superstructure optimization in heat exchanger network (HEN) synthesis using modular simulators and a genetic algorithm framework[J]. Ind Eng Chem Res, 2010, 49(10):4731-4737. [10] YERRAMSETTY K M, MURTY C V S. Synthesis of cost-optimal heat exchanger networks using differential evolution[J]. Comput Chem Eng, 2008, 32(8):1861-1876. [11] SILVA A P, RAVAGNANI M A S S, BISCAIA E C. Particle swarm optimisation applied in retrofit of heat exchanger networks[J]. Comput Aided Chem Eng, 2009, 27:1035-1040. [12] DOLAN W,CUMMINGS P, LEVAN M. Process optimization via simulated annealing:Application to network design[J]. AIChE J, 1989, 35(5):725-736. [13] LUO X, WEN Q Y, FIEG G. A hybrid genetic algorithm for synthesis of heat exchanger networks[J]. Comput Chem Eng, 2009, 33(6):1169-1181. [14] CHEN S, CUI G M, ZHANG C W, et al. Optimization of heat integration in dynamic multi-agent differential evolution algorithm[J]. Chinese Journal of Computational Physics, 2016, 33(3):349-357. [15] CHEN J, CUI G, DUAN H. Multipopulation differential evolution algorithm based on the opposition-based learning for heat exchanger network synthesis[J]. Numer Heat Transf A, 2017, 72(2):126-140. [16] ZHANG C W, CUI G M, CHEN S, et al. An improved chaotic ant swarm algorithm for simultaneous synthesis of heat exchanger network[J]. Chinese Journal of Computational Physics, 2017, 34(2):193-204. [17] 肖媛, 崔国民, 李帅龙. 一种新的用于换热网络全局优化的强制进化随机游走算法[J]. 化工学报, 2016, 67(12):5140-5147. [18] BLACKWELL T M. Particle swarms and population diversity[J]. Soft Comput, 2005, 9(11):793-802. [19] LÜ Q, SHEN G, YU R. A chaotic approach to maintain the population diversity of genetic algorithm in network training[J]. Comput Biol Chem, 2003, 27(3):363-371. [20] SALEHINEJAD H, RAHNAMAYAN S, TIZHOOSH H R. Micro-differential evolution:Diversity enhancement and a comparative study[J]. Appl Soft Comput, 2016. [21] 陈家星, 崔国民, 彭富裕, 等. 基于种群多样性的改进差分进化算法应用于换热网络优化[J]. 热能动力工程, 2017, 32(4):29-37. [22] LI S L, CUI G M, CHEN S, et al. An improved particle swarm optimization based on diversity monitor and real-time updating strategy[J]. Chinese Journal of Computational Physics, 2017, 34(3):344-355. [23] BJÖRK K M, WESTERLUND T. Global optimization of heat exchanger network synthesis problems with and without the isothermal mixing assumption[J]. Comput Chem Eng, 2002, 26(11):1581-1593. [24] 肖媛, 崔国民, 彭富裕,等. PSO用于优化换热网络时对全局搜索能力的研究[J]. 热能动力工程, 2016, 31(1):20-26. [25] 何巧乐, 崔国民, 许海珠. 文化基因粒子群算法在换热网络连续变量全局优化中的应用[J]. 石油化工, 2014, 43(1):37-45. [26] PAVÃO L V, COSTA C B, RAVAGNANI M S. Heat exchanger network synthesis without stream splits using parallelized and simplified simulated annealing and particle swarm optimization[J]. Chem Eng Sci, 2017, 158:96-107. [27] 苏海军, 杨煜普, 王宇嘉. 微分进化算法的研究综述[J]. 系统工程与电子技术, 2008, 30(9):1793-1797. [28] HUO Z, ZHAO L, YIN H, et al. A hybrid optimization strategy for simultaneous synthesis of heat exchanger network[J]. Korean J Chem Eng, 2012, 29(10):1298-1309. [29] HUO Z, ZHAO L, YIN H, et al. Simultaneous synthesis of structural-constrained heat exchanger networks with and without stream splits[J]. Canadian Journal of Chemical Engineering, 2013, 91(5):830-842. [30] LEWIN D R. A generalized method for HEN synthesis using stochastic optimization Ⅱ:The synthesis of cost-optimal networks[J]. Computers & Chemical Engineering, 1998, 22(10):1387-1405. [31] PENG F, CUI G. Efficient simultaneous synthesis for heat exchanger network with simulated annealing algorithm[J]. Appl Therm Eng, 2015, 78:136-149. [32] ZHU X X, O'NEILL B K, ROACH J R, et al. A method for automated heat exchanger network synthesis using block decomposition and non-linear optimization[J]. Chemical Engineering Research & Design, 1995, 73(A8):919-930. [33] DUAN H H, CUI G M, CHEN J X, et al. A strategy of differential evolution with opposition-based multi-population parallel[J]. Chinese Journal of Computational Physics, 2016, 33(5):561-569. [34] FIEG G, LUO X, JEZ·OWSKI J. A monogenetic algorithm for optimal design of large-scale heat exchanger networks[J]. Chem Eng Process, 2009, 48(11):1506-1516. [35] BJÖRK K M, PETTERSSON F. Optimization of large-scale heat exchanger network synthesis problems[C]//Iasted International Conference on Modelling and Simulation, DBLP, 2003:313-318. [36] BJÖRK K M, NORDMAN R. Solving large-scale retrofit heat exchanger network synthesis problems with mathematical optimization methods[J]. Chem Eng Process, 2005, 44(8):869-876. |