Optimized design method for internal heat-integrated distillation columns based on column grand composite curve

doi:10.11949/j.issn.0438-1157.20161116

CIESC Journal ›› 2017, Vol. 68 ›› Issue (4): 1482-1489.DOI: 10.11949/j.issn.0438-1157.20161116

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Optimized design method for internal heat-integrated distillation columns based on column grand composite curve

LIU Xuegang¹, HE Chang¹, LEI Yang², HE Changchun¹, ZHANG Bingjian¹, CHEN Qinglin¹

1 School of Chemical Engineering and Technology, Guangdong Engineering Center for Petrochemical Energy Conservation, Sun Yat-Sen University, Guangzhou 510275, Guangdong, China;
2 School of Chemical Engineering and Technology, Wuhan University of Science and Technology, Wuhan 430081 Hubei, China

Received:2016-08-08 Revised:2016-11-26 Online:2017-04-05 Published:2017-04-05
Supported by:
supported by the National Natural Science Foundation of China (21276288, U1462113) and the Natural Science Foundation of Guangdong Province(2015A030313112).

基于塔总组合曲线的内部热耦合精馏塔优化设计方法

刘雪刚¹, 何畅¹, 雷杨², 何昌春¹, 张冰剑¹, 陈清林¹

1 中山大学化学工程与技术学院, 广东省石化过程节能工程技术研究中心, 广东广州 510275;
2 武汉科技大学化学工程与技术学院, 湖北武汉 430081

通讯作者: 陈清林
基金资助:
国家自然科学基金项目（21276288，U1462113）；广东省自然科学基金项目（2015A030313112）。

Abstract

Abstract:

A new graphical design method is presented to simplify the configuration of heat-integrated distillation columns (HIDiCs) based on column grand composite curves (CGCCs). On the basis of the optimal arrangement of the side-exchangers on single rectifying (or on single stripping) section, the optimal design of side-exchangers located on HIDiCs thermal coupling section will be determined by combining with the integrated diagram from CGCCs of rectifying and stripping sections and maximizing the available reduced total exergy loss of HIDiC. As a case study, a styrene-ethylbenzene HIDiC is simulated to demonstrate the accuracy and rationality of the graphical method. The results show that the available reduced total exergy loss of HIDiC reaches the maximum (1.951 MW), and the condenser and reboiler duties are reduced by 63.6% and 68.4% after side heat exchangers arrangement, respectively. For achieving this goal, the side-exchangers should be placed on the 2nd, 12th and 38th stages of the rectifying and on the 20th, 28th and 36th stages of the stripping sections, respectively. Their heat duties are 0.841 MW, 1.496 MW and 2.053 MW, respectively.

Key words: heat-integrated column, column grand composition curve, thermodynamics, exergy analysis, optimization

摘要：

基于塔总组合曲线（CGCC），提出了一种简化内部热耦合精馏塔（HIDiC）结构的图形设计方法。在完成精馏段（或提馏段）单塔段中间换热器优化设置的基础上，结合精馏段与提馏段CGCC的集成图，以HIDiC的可减小过程总（火用）损为目标，确定HIDiC热耦合中间换热器的最优设计。以苯乙烯-乙苯HIDiC为例，计算结果表明，设置中间换热器后，HIDiC可减小过程总（火用）损最大值为1.951 MW，HIDiC的冷凝器、再沸器负荷分别下降63.6%和68.4%；热耦合中间换热器分别设置于精馏段第2、12、和38块塔板，提馏段第20、28和36块塔板，热负荷依次为0.841、1.496和2.053 MW。

关键词: 热耦合精馏塔, 塔总组合曲线, 热力学, （火用）分析, 优化

CLC Number:

TQ028.4

LIU Xuegang, HE Chang, LEI Yang, HE Changchun, ZHANG Bingjian, CHEN Qinglin. Optimized design method for internal heat-integrated distillation columns based on column grand composite curve[J]. CIESC Journal, 2017, 68(4): 1482-1489.

刘雪刚, 何畅, 雷杨, 何昌春, 张冰剑, 陈清林. 基于塔总组合曲线的内部热耦合精馏塔优化设计方法[J]. 化工学报, 2017, 68(4): 1482-1489.

References 21

[1]	赵雄, 罗祎青, 闫兵海, 等. 内部能量集成精馏塔的模拟研究及其节能特性分析[J]. 化工学报, 2009, 60(1):142-150.ZHAO X, LUO Y Q, YAN B H, et al. Simulation study of internally heat-integrated distillation column and its characteristics for energy saving[J]. CIESC Journal, 2009, 60(1):142-150.
[2]	李萱, 李洪, 高鑫, 等. 热耦合精馏工艺的模拟[J]. 化工进展, 2016, 35(1):48-56.LI X, LI H, GAO X, et al. Simulation on heat integrated distillation technology[J]. Chemical Industry and Engineering Progress, 2016, 35(1):48-56.
[3]	JANA A K. Heat integrated distillation operation[J]. Appl. Energy, 2010, 87(5):1477-1494.
[4]	常亮, 刘兴高. 内部热耦合空分塔的节能优化分析[J]. 化工学报, 2012, 63(9):2936-2940.CHANG L, LIU X G. Energy optimization analysis of internal thermally coupled air separation columns[J]. CIESC Journal, 2012, 63(9):2936-2940.
[5]	安维中, 袁希钢. 基于随机优化的热耦合复杂精馏塔系统的综合(Ⅰ):模型化方法[J]. 化工学报, 2006, 57(7):1591-1598.AN W Z, YUAN X G. Synthesis of thermally coupled complex distillation system based on stochastic optimization (Ⅰ):Problem formulation[J]. Journal of Chemical Industry and Engineering(China), 2006, 57(7):1591-1598.
[6]	安维中, 袁希钢. 基于随机优化的热耦合复杂精馏系统的综合(Ⅱ):计算举例与分析[J]. 化工学报, 2006, 57(7):1599-1604.AN W Z, YUAN X G. Synthesis of thermally coupled complex distillation system based on stochastic optimization(Ⅱ):Example illustration and analysis[J]. Journal of Chemical Industry and Engineering(China), 2006, 57(7):1599-1604.
[7]	李春利, 陈媛, 张林, 等. 内部热耦合精馏塔的操作性能与模拟[J]. 化工进展, 2015, 34(11):3879-3885.LI C L, CHEN Y, ZHANG L, et al. Operation performance and simulation of internally heat-integrated distillation column[J]. Chemical Industry and Engineering Progress, 2015, 34(11):3879-3885.
[8]	孙兰义, 扎寇·奥鲁轶驰. 内部热耦合精馏塔构型研究[J]. 化学工程, 2006, 34(11):4-7.SUN L Y, OLUJIC Z. Study on configurations for a heat integration distillation column[J]. Chemical Engineering (China), 2006, 34(11):4-7.
[9]	HUANG K, SHAN L, ZHU Q, et al. Adding rectifying/stripping section type heat integration to a pressure-swing distillation (PSD) process[J]. Appl. Therm. Eng., 2008, 28(8/9):923-932.
[10]	马江鹏, 陈海胜, 黄克谨. 简化外部热耦合双精馏塔的控制与优化[J]. 化工学报, 2011, 62(8):2195-2199.MA J P, CHEN H S, HUANG K J. Control and optimization of simplified externally heat-integrated double distillation columns[J]. CIESC Journal, 2011, 62(8):2195-2199.
[11]	WANG Y, HUANG K, WANG S. A simplified scheme of externally heat-integrated double distillation columns (EHIDDiC) with three external heat exchangers[J]. Ind. Eng. Chem. Res., 2010, 49(7):3349-3364.
[12]	ZHANG X, HUANG K, CHEN H, et al. Comparing three configurations of the externally heat-integrated double distillation columns (EHIDDiCs)[J]. Comput. Chem. Eng., 2011, 35(10):2017-2033.
[13]	武国松. 简化设计对理想热耦合精馏塔(HIDiC)性能的影响[D]. 北京:北京化工大学, 2010.WU G S. Impact of simplifications on the performance of an ideal heat-integrated distillation column (ideal HIDiC)[D]. Beijing:Beijing University of Chemical Technology, 2010.
[14]	陈海胜. 简化内部热耦合精馏塔的综合与设计[D]. 北京:北京化工大学, 2010.CHEN H S. Synthesis and design of a simplified ideal heat-integrated distillation column[D]. Beijing:Beijing University of Chemical Technology, 2010.
[15]	BANDYOPADHYAY S, MALIK R K, SHENOY U V. Invariant rectifying-stripping curves for targeting minimum energy and feed location in distillation[J]. Comput. Chem. Eng., 1999, 23(8):1109-1124.
[16]	DHOLE V R, LINNHOFF B. Distillation column targets[J]. Comput. Chem. Eng., 1993, 17(5/6):549-560.
[17]	BANDYOPADHYAY S, MALIK R K, SHENOY U V. Feed preconditioning targets for distillation through invariant rectifying-stripping curves[J]. Ind. Eng. Chem. Res., 2003, 42(26):6851-6861.
[18]	BANDYOPADHYAY B. Thermal integration of a distillation column through side-exchangers[J]. Chem. Eng. Res. Des. 2007, 85(1):155-166.
[19]	李会泉, 祝刚, 王世广, 等. 复杂精馏塔的用能分析法[J]. 高校化学工程学报, 1998, 12(2):146-151.LI H Q, ZHU G, WANG S G, et al. Analysis of energy utilization of complex distillation column[J]. Journal of Chemical Engineering of Chinese Universities, 1998, 12(2):146-151.
[20]	BANDYOPADHYAY S. Effect of feed on optimal thermodynamic performance of a distillation column[J]. Chem. Eng. J., 2002, 88(1):175-186.
[21]	WEI Z, WU S, ZHANG B, et al. An exergy grand composite curve based procedure for arranging side exchangers on distillation columns[J]. Comput. Aided Chem. Eng., 2012, 31(1):1592-1596.

Optimized design method for internal heat-integrated distillation columns based on column grand composite curve

基于塔总组合曲线的内部热耦合精馏塔优化设计方法

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