Advanced control and optimization for coal-based syngas to ethylene glycol

doi:10.16085/j.issn.1000-6613.2019-2042

Chemical Industry and Engineering Progress ›› 2020, Vol. 39 ›› Issue (S1): 43-49.DOI: 10.16085/j.issn.1000-6613.2019-2042

• Chemical processes and equipment • Previous Articles Next Articles

Advanced control and optimization for coal-based syngas to ethylene glycol

Bin ZHANG(), Weimin YANG(), Weisheng YANG

State key Laboratory of Green Chemical Engineering and Industrial Catalysis, Sinopec Shanghai Research Institute of Petrochemical Technology, Shanghai 201208, China

Received:2019-12-19 Online:2020-06-29 Published:2020-05-20
Contact: Weimin YANG

合成气制乙二醇生产过程的先进控制及应用

张彬(), 杨为民(), 杨卫胜

中国石化上海石油化工研究院绿色化工与工业催化国家重点实验室，上海 201208

通讯作者: 杨为民
作者简介:张彬（1977—），男，博士，高级工程师，研究方向为化工工艺设计及过程优化控制。E-mail：zbxyh@sina.com.cn。
基金资助:
中国石化科技开发项目(417013-5)

Abstract

Abstract:

Based on dynamic model identification, soft measurement and online optimization, model predictive algorithm was applied to the process of the coal-based syngas to ethylene glycol. First, the advanced control structure and model of the process were given in detail. Then some key indexes of the distillation column, such as temperature, pressure, process quality were predicted online, monitored and closed-loop controlled. Therefore, the operation stability of the production process of synthesis gas to glycol was improved, the conversion rate of raw materials and product yield were also increased, which lead to the energy consumption of the process decreased largely. The industry applications show that the manipulated stability of the distillation was largely improved after the application of the advanced control technique, standard deviation of some main manipulated control variables was decreased about 20%, steam was decreased 3.67% compared the past and labor intensity was also lightened than past.

Key words: coal-based syngas to ethylene glycol, dynamic model identification, model predictive algorithm, advanced control

摘要：

为提升合成气制乙二醇生产过程的操作平稳性、增加反应原料转化率和产品收率，提高装置节能降耗水平，本文针对合成气制乙二醇装置的特点，基于多变量预测控制技术、动态模型辨识、软测量、在线优化技术，搭建过程生产的先进控制结构及模型，实现了对各精馏塔关键指标——温度、压力、产品质量的实时监测、预测及闭环优化控制。工业装置应用表明，先进控制实施后，合成气制乙二醇生产过程的精馏单元操作平稳性大幅提升，主要被控变量的波动标准方差降低20%以上，过程操作强度有效降低，蒸汽消耗降低3.67%。

关键词: 合成气制乙二醇, 动态模型辨识, 多变量预测控制, 先进控制

CLC Number:

TP 273

Bin ZHANG, Weimin YANG, Weisheng YANG. Advanced control and optimization for coal-based syngas to ethylene glycol[J]. Chemical Industry and Engineering Progress, 2020, 39(S1): 43-49.

张彬, 杨为民, 杨卫胜. 合成气制乙二醇生产过程的先进控制及应用[J]. 化工进展, 2020, 39(S1): 43-49.

Figures/Tables 15

References 10

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位号	描述
FIC40201.SV	脱重塔回流设定值
FIC40102.SV	脱重塔再沸器蒸汽
FIC40202.SV	脱重塔塔顶采出
LIC40101.MV	脱重塔塔釜液位阀位
FIC40501.SV	脱轻塔回流量
FIC40401.SV	脱轻塔再沸器塔壳程流量
FIC40502.SV	脱轻塔塔顶采出
FIC40402.SV	脱轻塔塔釜采出
FIC40903.SV	碳酸酯回收塔回流
FIC40801.SV	碳酸酯回收塔再沸器蒸汽量
FIC40902.SV	碳酸酯分离塔塔顶采出

位号	描述
FIC40201.SV	脱重塔回流设定值
FIC40102.SV	脱重塔再沸器蒸汽
FIC40202.SV	脱重塔塔顶采出
LIC40101.MV	脱重塔塔釜液位阀位
FIC40501.SV	脱轻塔回流量
FIC40401.SV	脱轻塔再沸器塔壳程流量
FIC40502.SV	脱轻塔塔顶采出
FIC40402.SV	脱轻塔塔釜采出
FIC40903.SV	碳酸酯回收塔回流
FIC40801.SV	碳酸酯回收塔再沸器蒸汽量
FIC40902.SV	碳酸酯分离塔塔顶采出

位号	描述
TIC40110.PV	脱重塔灵敏板温度
TI40102.PV	脱重塔顶温
TIC40110.PV	脱重塔灵敏板温度
LIC40201.PV	脱重塔回流罐液位
LIC40101.PV	脱重塔塔釜液位
TIC40402.PV	脱轻塔灵敏板温度
TDIC40401.PV	脱轻塔提馏段温差
LIC40501.PV	脱轻塔回流罐液位
LIC40401.PV	脱轻塔塔釜液位
TI40801.PV	碳酸酯回收塔低l层塔盘温度
TI40803.PV	碳酸酯回收塔低m层塔盘温度
TI40804.PV	碳酸酯回收塔低p层塔盘温度
TI40807.PV	碳酸酯回收塔重沸器返塔温度
LIC40901.PV	碳酸酯回收塔回流罐液位

位号	描述
TIC40110.PV	脱重塔灵敏板温度
TI40102.PV	脱重塔顶温
TIC40110.PV	脱重塔灵敏板温度
LIC40201.PV	脱重塔回流罐液位
LIC40101.PV	脱重塔塔釜液位
TIC40402.PV	脱轻塔灵敏板温度
TDIC40401.PV	脱轻塔提馏段温差
LIC40501.PV	脱轻塔回流罐液位
LIC40401.PV	脱轻塔塔釜液位
TI40801.PV	碳酸酯回收塔低l层塔盘温度
TI40803.PV	碳酸酯回收塔低m层塔盘温度
TI40804.PV	碳酸酯回收塔低p层塔盘温度
TI40807.PV	碳酸酯回收塔重沸器返塔温度
LIC40901.PV	碳酸酯回收塔回流罐液位

位号	投运	平均值	标准差	标准差降低
TIC40110.PV	前	92.05	0.659	71.37%
灵敏板温度/℃	后	92.00	0.189
LIC40201.PV	前	48.17	4.217	61.91%
回流罐液位	后	42.24	1.606
FIC40202.SV	前	22.93	1.160	49.65%
塔顶采出/t·h^-1	后	22.71	0.584
LIC40101.PV	前	44.99	0.681	23.20%
塔釜液位	后	45.00	0.523

Advanced control and optimization for coal-based syngas to ethylene glycol

合成气制乙二醇生产过程的先进控制及应用

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Figures/Tables 15

References 10

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位号	投运	平均值	标准差	标准差降低
TIC40402.PV	前	64.51	0.760	82.10%
精馏段温度/℃	后	63.00	0.136
LIC40501.PV	前	42.52	9.346	86.83%
回流罐液位	后	50.43	1.230
FIC40502.SV	前	994.66	147.492	52.23%
回流罐采出/t·h^-1	后	1035.88	70.461
LIC40401.PV	前	46.47	0.150	31.85%
塔釜采出	后	45.00	0.102