基于全周期缓慢结垢的多效蒸发海水淡化慢时变系统优化设计

doi:10.11949/0438-1157.20211022

摘要/Abstract

摘要：

多效蒸发（MED）是最主要的海水淡化方法之一，作为典型的慢时变系统，该系统在长期运行的过程中，往往会由于结垢导致蒸发器传热效率降低，造成减产甚至停工。为避免出现这种问题，工艺设计者会采取冗余设计，增大传热面积，这会导致设备投资的显著增加。为保证MED系统能够全周期运行，且尽可能减少总传热面积，提出了一种全周期优化设计方法。该方法以总传热面积最小为目标，对决策变量在整个周期内进行分段优化，同时考虑结垢过程、工艺变化以及控制方面的需求，对各效传热面积进行裕量设计，通过一步优化求解得到最优操作条件与最小传热面积，实现对慢时变系统的优化设计。最后，以八效MED海水淡化装置为例，同时用等面积法、等温差法、稳态优化设计方法以及全周期优化设计方法对系统进行设计。结果表明，全周期优化设计方法能够最大限度减少传热面积，大大降低了系统的设备投资，是一种有着良好应用前景的多效蒸发海水淡化系统优化设计方法。

关键词: 海水淡化, 多效蒸发, 裕量设计, 全周期, 优化设计, 慢时变

Abstract:

Multi-effect distillation (MED) technology is one of the most important seawater desalination methods. As a typical slow-time-varying system, in the process of long-term operation, the heat transfer efficiency of the evaporator is often reduced due to fouling accumulation, resulting in production reduction or even shutdown. In order to avoid this kind of problem, designers usually adopt redundant designs to increase the heat transfer area, which leads to a significant increase in equipment investment. In order to ensure that the device can effectively operate in a full cycle and reduce the total heat transfer area as much as possible, a full-cycle optimization design method is proposed. This method takes the total heat transfer area as the objective function, and uses decision variables to perform segmental optimization throughout the full-cycle. At the same time, fouling accumulation, process changes and control requirements are considered when designing heat transfer area margins of each effect. It obtains the optimal operating conditions and the minimum heat transfer area in one step, and completes the optimal design of the slow-time-varying system. Finally, taking a MED desalination system with eight effects as an example, the system is designed by using equal area method, equal temperature difference method, steady-state optimization design method, and full-cycle optimization design method at the same time. The results show that the full-cycle optimization design method can minimize the heat transfer area and greatly reduce the equipment investment of the MED system. It is a multi-effect evaporative desalination system optimization design method with good application prospects.

Key words: seawater desalination, multi-effect distillation, margin design, full cycle, optimal design, slow-time-varying

中图分类号:

TQ 021.8

王天媛, 陈春波, 孙琳, 罗雄麟. 基于全周期缓慢结垢的多效蒸发海水淡化慢时变系统优化设计[J]. 化工学报, 2022, 73(2): 759-769.

Tianyuan WANG, Chunbo CHEN, Lin SUN, Xionglin LUO. Optimal design of slow-time-varying system for multi-effect distillation desalination based on full-cycle slow fouling[J]. CIESC Journal, 2022, 73(2): 759-769.

图/表 15

图1 低温多效蒸发系统工艺流程

Fig.1 Process diagram of low-temperature multi-effect distillation system

图2 单效蒸发器示意图

Fig.2 Schematic diagram of single effect evaporation

图3 结垢情况及对传热系数的影响

Fig.3 Fouling accumulation and the effect on heat transfer coefficient

图4 长周期运行淡水产量变化示意图

Fig.4 Schematic diagram of fresh water yield variation in long period operation

表1 MED-TVC系统基本物性参数及设备尺寸

Table 1 Basic physical parameters and equipment size of MED-TVC system

参数	数值
物性参数
外来加热蒸汽压力/MPa	0.5
外来加热蒸汽温度/℃	151.8
进料海水温度/℃	35
进料海水盐分质量含量/%	3.0
浓盐水顶温/℃	<70
换热管参数
长度/m	6
外径/m	0.024
厚度/m	0.0007

表2 MED-TVC系统操作条件

Table 2 MED-TVC system operating conditions

效序数	单效进料海水流量/(kg/s)	蒸发器内部压力/kPa	蒸发温度/℃	预热器预热温差/℃	引射蒸汽流量/(kg/s)
1	31.59	27.342	67	4	4.4
2	31.59	23.917	64	4
3	31.59	20.864	61	4
4	31.59	18.148	58	4
5	31.59	15.738	55	4
6	31.59	13.607	52	4
7	31.59	11.727	49	4
8	31.59	10.074	46	—

表3 操作条件设计结果

Table 3 Operating condition results

效序数	蒸发温度/℃			海水进料流量/(kg/s)			预热器预热温差/℃			引射蒸汽流量/(kg/s)
效序数	等温差法	等面积法	稳态优化	等温差法	等面积法	稳态优化	等温差法	等面积法	稳态优化	等温差法	等面积法	稳态优化
1	67	67	68.57	31.59	31.59	48.53	3	4	3	4.4	4.4	4.1
2	64	64	63.47			48.80			3
3	61	61	60.28			45.34			3
4	58	58	57.25			41.36			4
5	55	55	54.35			34.01			5
6	52	52	51.23			27.62			7
7	49	49	48.45			25.32			7
8	46	46	45.76			22.10			-

表4 各效裕量及总传热面积设计结果

Table 4 Design results of each effect margin and heat transfer area

效序数	操作裕量/%	结垢裕量/%	控制裕量/%	总设计裕量/%			总传热面积/m²
效序数	稳态优化	稳态优化	稳态优化	等面积法	等温差法	稳态优化	等面积法	等温差法	稳态优化
1	0.1	13.7	2.0	20.0	20.0	15.8	29202.66	22848.80	21197.64
2	1.6	13.3				16.9
3	0.9	14.6				17.5
4	2.2	16.3				20.5
5	8.0	19.7				29.7
6	13.4	23.1				38.5
7	20.7	21.3				44.0
8	34.4	19.8				56.2

图5 三种设计方法全周期运行下淡水产量结果

Fig.5 Freshwater production results of three design methods in full-cycle operation

图6 全周期运行下各效结垢热阻变化趋势

Fig.6 Variation trend of fouling resistance of each effect under full-cycle operation

图7 MED-TVC系统全周期优化设计下操作条件优化结果

Fig.7 Optimal results of operating conditions under the full-cycle optimization design of the MED-TVC system

图8 各效蒸发器传热面积设计值

Fig.8 Design values of heat transfer area of each evaporator

表5 全周期优化设计换热面积裕量值

Table 5 The values of full-cycle optimization design margin

效序数	总设计裕量/%	总传热面积/m²
1	6.87	18387.08
2	29.63
3	22.31
4	13.87
5	11.26
6	11.38
7	12.58
8	33.29

图9 驱动蒸汽全周期运行结果

Fig.9 Motive steam full-cycle operation results

图10 四种设计方法下总传热面积与总驱动蒸汽量全周期运行结果对比A—全周期优化设计;B—稳态优化设计;C—等温差法设计;D—等面积法设计

Fig.10 Comparison of the total heat transfer area and the total motive steam flow rate under the four design methods for full cycle operation results

参考文献 30

1	高从堦, 陈国华. 海水淡化技术与工程手册[M]. 北京:化学工业出版社, 2004.
	Gao C J, Chen G H. Handbook of Seawater Desalination Technology and Engineering[M]. Beijing: Chemical Industry Press, 2004.
2	张建丽, 张忠梅. TVC-MED海水淡化装置工艺系统设计分析[J]. 神华科技, 2010, 8(1): 37-40, 73.
	Zhang J L, Zhang Z M. Technological system design and analysis of TVC-MED sea water desalinating unit[J]. Shenhua Science and Technology, 2010, 8(1): 37-40, 73.
3	徐贤英. 海水淡化技术的现状及其应用[J]. 工程建设, 2006, 38(4): 55-59.
	Xu X Y. Present situation and application of seawater desalination[J]. Engineering Construction, 2006, 38(4): 55-59.
4	Darwish M A, El-Dessouky H. The heat recovery thermal vapour-compression desalting system: a comparison with other thermal desalination processes[J]. Applied Thermal Engineering, 1996, 16(6): 523-537.
5	阮奇, 黄诗煌, 叶长燊, 等. 复杂逆流多效蒸发系统常规设计的模型与算法[J]. 化工学报, 2001, 52(7): 616-621.
	Ruan Q, Huang S H, Ye C S, et al. Conventional design model of complex countercurrentmulti-effect evaporation and its algorithm[J]. Journal of Chemical Industry and Engineering (China), 2001, 52(7): 616-621.
6	苏保卫, 王越, 王志, 等. 塔式多效蒸馏海水淡化装置的进料优化[J]. 水处理技术, 2004, 30(4): 191-195.
	Su B W, Wang Y, Wang Z, et al. Feed optimization of multi effect stack desalination system[J]. Technology of Water Treatment, 2004, 30(4): 191-195.
7	刘晓华, 沈胜强, Genthner K, 等. 多效蒸发海水淡化系统模拟计算与优化[J]. 石油化工高等学校学报, 2005, 18(4): 16-19, 3.
	Liu X H, Shen S Q, Genthner K, et al. Simulation and optimization of MEE seawater desalination system[J]. Journal of Petrochemical Universities, 2005, 18(4): 16-19, 3.
8	龚路远, 杨勇, 沈胜强. 横管降膜低温多效蒸发海水淡化系统的优化设计[J]. 节能, 2011, 30(5): 4-8, 2.
	Gong L Y, Yang Y, Shen S Q. Optimization design of the low-temperature multi-effect distillation desalination system with horizontal pipe falling film evaporation[J]. Energy Conservation, 2011, 30(5): 4-8, 2.
9	唐智新, 吴礼云, 梁红英, 等. 低温多效蒸馏海水淡化蒸发器结垢原因分析及清洗[J]. 冶金动力, 2015, 34(9): 61-65.
	Tang Z X, Wu L Y, Liang H Y, et al. Cause analysis and cleaning of scaling in the LT-MED seawater desalination evaporator[J]. Metallurgical Power, 2015, 34(9): 61-65.
10	Albagawi J. Fouling analysis and its mitigation in heat exchangers[D]. Saudi Arabia: King Fahd University of Petroleum and Minerals, 2002.
11	程达芳. 多效蒸发过程模拟: 以最优法求解多效蒸发各个参数[J]. 高校化学工程学报, 1989, 3(2): 84-93.
	Cheng D F. Simulation of multiple - effect evaporation processes-parameters evaluation of multiple - effect evaporation with optimization method[J]. Journal of Chemical Engineering of Chinese Universities, 1989, 3(2): 84-93.
12	刘晓华, 沈胜强, 罗建松, 等. 水电联产低温多效蒸发海水淡化系统优化研究[J]. 大连理工大学学报, 2012, 52(4): 492-496.
	Liu X H, Shen S Q, Luo J S, et al. Research on optimization of power and water cogeneration system with LT-MED for seawater desalination[J]. Journal of Dalian University of Technology, 2012, 52(4): 492-496.
13	谢府命, 许锋, 梁志珊, 等. 乙炔加氢反应器全周期操作优化[J]. 化工学报, 2018, 69(3): 1081-1091.
	Xie F M, Xu F, Liang Z S, et al. Full-cycle operation optimization of acetylene hydrogenation reactor[J]. CIESC Journal, 2018, 69(3): 1081-1091.
14	Chen C B, Sun L, Liu D J, et al. Impact of cumulative fouling characteristics on full-cycle operation optimisation of multi-effect distillation desalination system[J].Chem. Eng. Trans., 2019, 76: 649-654.
15	Chen C B, Luo X L, Wang T Y, et al. Minimum motive steam consumption on full cycle optimization with cumulative fouling consideration for MED-TVC desalination system[J]. Desalination, 2021, 507: 115017.
16	王传芳, 罗雄麟. 控制裕量及其在管壳式换热器设计中的应用[J]. 炼油技术与工程, 2004, 34(2): 21-25.
	Wang C F, Luo X L. Overdesign for control and its application in tube-shell heat exchanger design[J]. Petroleum Refinery Engineering, 2004, 34(2): 21-25.
17	陈军. 低温多效蒸发海水淡化系统工艺流程模拟及优化[D]. 北京: 北京化工大学, 2013.
	Chen J. Process simulation and optimization of low temperature seawater multi-effect distillation system[D]. Beijing: Beijing University of Chemical Technology, 2013.
18	王世昌. 海水淡化工程[M]. 北京: 化学工业出版社, 2003.
	Wang S C. Desalination Project [M]. Beijing: Chemical Industry Press, 2003.
19	Al-Shammiri M, Safar M. Multi-effect distillation plants: state of the art[J]. Desalination, 1999, 126(1/2/3): 45-59.
20	贾利涛, 刘旭明, 唐智新. 低温多效海水淡化阻垢剂溶垢试验研究[J]. 冶金动力, 2020, 39(12): 66-70.
	Jia L T, Liu X M, Tang Z X. Experimental study on scale dissolving by multi-effect scale inhibitor in low temperature seawater desalination[J]. Metallurgical Power, 2020, 39(12): 66-70.
21	孙雪, 吴礼云, 李强, 等. 海水淡化产量降低原因分析及提产实践[J]. 水处理技术, 2018, 44(5): 123-126.
	Sun X, Wu L Y, Li Q, et al. Reasons analysis of seawater desalination production reduction and practice of increasing production[J]. Technology of Water Treatment, 2018, 44(5): 123-126.
22	帅露, 蔡振, 周一卉, 等. 基于Lingo的MED-TVC系统优化设计[J]. 计算机与应用化学, 2016, 33(1): 33-38.
	Shuai L, Cai Z, Zhou Y H, et al. The optimization of MED-TVC system based on Lingo[J]. Computers and Applied Chemistry, 2016, 33(1): 33-38.
23	曹炳元, 周雪刚. 具有∨-·算子的格线性规划问题[J]. 汕头大学学报(自然科学版), 2005, 20(2): 5-11.
	Cao B Y, Zhou X G. Lattice linear programming with max-product composition operator[J]. Journal of Shantou University (Natural Science Edition), 2005, 20(2): 5-11.
24	孙琳, 迟进浩, 罗雄麟. 换热器设计裕量与旁路设计分析[J]. 计算机与应用化学, 2008, 25(11): 1369-1373.
	Sun L, Chi J H, Luo X L. The analysis of the overdesign and the bypass design for the heat exchanger[J]. Computers and Applied Chemistry, 2008, 25(11): 1369-1373.
25	钱颂文. 换热器设计手册[M]. 北京: 化学工业出版社, 2002.
	Qian S W. Heat Exchanger Design Manual[M]. Beijing:Chemical Industry Press, 2002.
26	Fikar M, Latifi M A, Fournier F, et al. Control vector parametrisation versus iterative dynamic programming in dynamic optimisation of a distillation column[J]. Computers & Chemical Engineering, 1998, 22: S625-S628.
27	Fikar M, Latifi M A, Corriou J P, et al. CVP-based optimal control of an industrial depropanizer column[J]. Computers & Chemical Engineering, 2000, 24(2): 909-915.
28	王平, 田学民. 一种改进的CVP方法及其在动态优化中的应用[J]. 控制与决策, 2009, 24(11): 1757-1760.
	Wang P, Tian X M. Enhanced control vector parameterization method and its application in dynamic optimization[J]. Control and Decision, 2009, 24(11): 1757-1760.
29	李国栋. 基于控制向量参数化的动态优化研究[D]. 杭州: 浙江大学, 2015.
	Li G D. Control vector parameterization based dynamic optimization research[D]. Hangzhou: Zhejiang University, 2015.
30	Xu L, Wang S Y, Wang S C, et al. Studies on heat-transfer film coefficients inside a horizontal tube in falling film evaporators[J]. Desalination, 2004, 166: 215-222.

[1]	陈哲文, 魏俊杰, 张玉明. 超临界水煤气化耦合SOFC发电系统集成及其能量转化机制[J]. 化工学报, 2023, 74(9): 3888-3902.
[2]	齐聪, 丁子, 余杰, 汤茂清, 梁林. 基于选择吸收纳米薄膜的太阳能温差发电特性研究[J]. 化工学报, 2023, 74(9): 3921-3930.
[3]	文兆伦, 李沛睿, 张忠林, 杜晓, 侯起旺, 刘叶刚, 郝晓刚, 官国清. 基于自热再生的隔壁塔深冷空分工艺设计及优化[J]. 化工学报, 2023, 74(7): 2988-2998.
[4]	江锦波, 彭新, 许文烜, 门日秀, 刘畅, 彭旭东. 泵出型螺旋槽油气密封泄漏特性及参数影响研究[J]. 化工学报, 2023, 74(6): 2538-2554.
[5]	孙永尧, 高秋英, 曾文广, 王佳铭, 陈艺飞, 周永哲, 贺高红, 阮雪华. 面向含氮油田伴生气提质利用的膜耦合分离工艺设计优化[J]. 化工学报, 2023, 74(5): 2034-2045.
[6]	刘尚豪, 贾胜坤, 罗祎青, 袁希钢. 基于梯度提升决策树的三组元精馏流程结构最优化[J]. 化工学报, 2023, 74(5): 2075-2087.
[7]	周必茂, 许世森, 王肖肖, 刘刚, 李小宇, 任永强, 谭厚章. 烧嘴偏转角度对气化炉渣层分布特性的影响[J]. 化工学报, 2023, 74(5): 1939-1949.
[8]	王泽栋, 石至平, 刘丽艳. 考虑气泡非均匀耗散的矩形反应器声流场数值模拟及结构优化[J]. 化工学报, 2023, 74(5): 1965-1973.
[9]	李纪元, 李金旺, 周刘伟. 不同扰流结构冷板传热性能研究[J]. 化工学报, 2023, 74(4): 1474-1488.
[10]	许文烜, 江锦波, 彭新, 门日秀, 刘畅, 彭旭东. 宽速域三种典型型槽油气密封泄漏与成膜特性对比研究[J]. 化工学报, 2023, 74(4): 1660-1679.
[11]	陈俊先, 姬忠礼, 赵瑜, 张倩, 周岩, 刘猛, 刘震. 基于微波技术的天然气管道内颗粒物在线检测方法研究[J]. 化工学报, 2023, 74(3): 1042-1053.
[12]	魏进家, 刘蕾, 杨小平. 面向高热流电子器件散热的环路热管研究进展[J]. 化工学报, 2023, 74(1): 60-73.
[13]	魏朋, 陈珺, 王志国, 刘飞. 基于双部分丢弃的模拟移动床产率提高策略[J]. 化工学报, 2022, 73(7): 3099-3108.
[14]	赵涛岩, 曹江涛, 李平, 冯琳, 商瑀. 区间二型模糊免疫PID在环己烷无催化氧化温度控制系统中的应用[J]. 化工学报, 2022, 73(7): 3166-3173.
[15]	万景, 张霖, 樊亚超, 刘勰民, 骆培成, 张锋, 张志炳. 基于介尺度PBM模型的生物反应器放大模拟及实验研究[J]. 化工学报, 2022, 73(6): 2698-2707.