基于慢特征分析的分布式动态工业过程运行状态评价

钟林生; 常玉清; 王福利; 高世红

doi:10.16383/j.aas.c230154

基于慢特征分析的分布式动态工业过程运行状态评价

doi: 10.16383/j.aas.c230154

钟林生^1,,
常玉清^1,,
王福利^{1, 2,},
高世红^3,

1.
东北大学信息科学与工程学院沈阳 110819
2.
东北大学流程工业综合自动化国家重点实验室沈阳 110819
3.
山西大学自动化与软件学院太原 030006

基金项目: 国家自然科学基金(62273078, 61973057), 国家重点研发计划(2021YFF0602404, 2021YFC2902703)资助

详细信息

作者简介:
钟林生：东北大学信息科学与工程学院博士研究生. 主要研究方向为复杂工业过程运行状态评价, 机器学习. E-mail: zhonglinsheng_neu@163.com

常玉清：东北大学信息科学与工程学院教授. 主要研究方向为复杂工业过程运行状态评价, 故障诊断. 本文通信作者. E-mail: changyuqing@ise.neu.edu.cn

王福利：东北大学信息科学与工程学院教授. 主要研究方向为复杂工业过程智能控制, 故障诊断和运行状态评价. E-mail: wangfuli@ise.neu.edu.cn

高世红：山西大学自动化与软件学院讲师. 主要研究方向为航天器姿态控制, 有限时间控制和预设性能控制. E-mail: gaoshihong@sxu.edu.cn

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出版历程
- 收稿日期: 2023-03-26
- 录用日期: 2023-11-19
- 网络出版日期: 2024-02-19
- 刊出日期: 2024-04-26

Distributed Operating Performance Assessment of Dynamic Industrial Processes Based on Slow Feature Analysis

1.
College of Information Science and Engineering, Northeastern University, Shenyang 110819
2.
State Key Laboratory of Synthetical Automation for Process Industries, Northeastern University, Shenyang 110819
3.
School of Automation and Software Engineering, Shanxi University, Taiyuan 030006

Funds: Supported by National Natural Science Foundation of China (62273078, 61973057) and National Key Research and Development Program of China (2021YFF0602404, 2021YFC2902703)

More Information

Author Bio:
ZHONG Lin-Sheng　Ph.D. candidate at the College of Information Sci-ence and Engineering, Northeastern University. His research interest covers complex process operating performance assessment and machine learning

CHANG Yu-Qing　Professor at the College of Information Science and Engineering, Northeastern University. Her research interest covers complex process operating performance assessment and fault diagnosis. Corresponding author of this paper

WANG Fu-Li　Professor at the College of Information Science and Engineering, Northeastern Univer-sity. His research interest covers complex process intelligent control, fault diagnosis, and operating performance assessment

GAO Shi-Hong　Lecturer at the School of Automation and Software Engineering, Shanxi University. Her research interest covers spacecraft attitude control, finite-time control, and prescribed performance control

摘要

摘要: 现代工业过程通常具有规模大、流程长和工序多的特点, 导致传统的集中式建模方法会淹没过程的局部变化信息, 从而无法及时识别早期的非优运行状态. 此外, 闭环控制的广泛应用使得过程变量普遍存在时序相关性. 针对以上问题, 提出一种基于慢特征分析(Slow feature analysis, SFA)的分布式动态工业过程运行状态评价方法. 首先, 结合动态时间规整(Dynamic time warping, DTW)和K-medoids聚类算法对过程进行分解; 然后, 对每一变量子块建立相应的动态慢特征分析(Dynamic slow feature analysis, DSFA)模型; 最后, 利用贝叶斯推理获得全局的综合评价指标. 通过在数值案例和金湿法冶金过程的仿真应用, 验证了该方法的有效性.
- 分布式模型 /
- 运行状态评价 /
- 慢特征分析 /
- 动态时间规整 /
- K-medoids聚类
Abstract: The modern industrial processes are generally characterized by large scale, long processes and multiple procedures. In this case, the traditional centralized model may submerge the local change information of the processes, thus failing to identify the early non-optimal operation status in time. In addition, the wide application of closed-loop control brings the universal existence of temporal correlations of process variables. In view of the above problem, a distributed operating performance assessment scheme of dynamic industrial processes based on slow feature analysis (SFA) is proposed. First, the process decomposition is realized by combining dynamic time warping (DTW) and K-medoids clustering algorithms. Second, the corresponding dynamic slow feature analysis (DSFA) model is established for each sub-block. Finally, the overall comprehensive assessment index is obtained through Bayesian inference. The effectiveness of the scheme is verified by numerical examples and gold hydrometallurgy process.
- Distributed model /
- operating performance assessment /
- slow feature analysis (SFA) /
- dynamic time warping (DTW) /
- K-medoids clustering

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图 1 基于DDSFA的运行状态评价流程图

Fig. 1 Flow diagram of DDSFA-based operating performance assessment

下载: 全尺寸图片幻灯片

图 2 数值仿真算例中, 案例1的运行状态评价结果

Fig. 2 The operating performance assessment result of case 1 in the numerical example

下载: 全尺寸图片幻灯片

图 3 数值仿真算例中, 案例2的运行状态评价结果

Fig. 3 The operating performance assessment result of case 2 in the numerical example

下载: 全尺寸图片幻灯片

图 4 金湿法冶金过程工艺流程图

Fig. 4 The flow chart of gold hydrometallurgy process

下载: 全尺寸图片幻灯片

图 5 金湿法冶金过程中, 案例3的运行状态评价结果

Fig. 5 The operating performance assessment result of case 3 in gold hydrometallurgy process

下载: 全尺寸图片幻灯片

图 6 金湿法冶金过程中, 案例4的运行状态评价结果

Fig. 6 The operating performance assessment result of case 4 in gold hydrometallurgy process

下载: 全尺寸图片幻灯片

表 1 不同算法在数值仿真算例中的漏报率(%)

Table 1 Missed alarm rates of different methods inthe numerical example (%)

方法	DPCA	DDPCA	DSFA	DDSFA
案例1	20.25	4.25	19.25	7.00
案例2	94.00	90.50	24.00	18.25

下载: 导出CSV

表 2 金湿法冶金过程的变量

Table 2 The variables of gold hydrometallurgy process

序号	子工序	变量名称
1	一次氰化浸出	矿浆浓度
2		入口矿浆流量
3		浸出槽1的${\rm{NaCN}}$流量
4		浸出槽2的${\rm{NaCN}}$流量
5		浸出槽4的${\rm{NaCN}}$流量
6		空气流量
7		浸出槽溶解氧浓度
8		浸出槽1的${\rm{CN}}^-$浓度
9		浸出槽2的${\rm{CN}}^-$浓度
10		浸出槽4的${\rm{CN}}^-$浓度
11	一次洗涤	立式压滤机进料压力
12		立式压滤机液压压力
13		立式压滤机挤压压力
14	二次氰化浸出	矿浆浓度
15		入口矿浆流量
16		浸出槽1的${\rm{NaCN}}$流量
17		浸出槽2的${\rm{NaCN}}$流量
18		浸出槽4的${\rm{NaCN}}$流量
19		空气流量
20		浸出槽溶解氧浓度
21		浸出槽1的${\rm{CN}}^-$浓度
22		浸出槽2的${\rm{CN}}^-$浓度
23		浸出槽4的${\rm{CN}}^-$浓度
24	二次洗涤	立式压滤机进料压力
25		立式压滤机液压压力
26		立式压滤机挤压压力
27	置换	脱氧塔真空度
28		贵液中的$ {\left[ {{\rm{Au}}{{\left( {{\rm{CN}}} \right)}_2}} \right]^ - }$浓度
29		贫液中的$ {\left[ {{\rm{Au}}{{\left( {{\rm{CN}}} \right)}_2}} \right]^ - }$浓度
30		锌粉添加速度

下载: 导出CSV

表 3 金湿法冶金过程变量的子块划分结果

Table 3 Sub-block division result of process variables of gold hydrometallurgy

子块	过程变量
1	27, 28, 29, 30
2	6, 7, 11, 12, 13
3	19, 20, 24, 25, 26
4	1, 2, 3, 4, 5, 8, 9, 10
5	14, 15, 16, 17, 18, 21, 22, 23

下载: 导出CSV

表 4 不同算法在金湿法冶金过程中的漏报率(%)

Table 4 Missed alarm rates of different methods in gold hydrometallurgy process (%)

方法	DPCA	DDPCA	DSFA	DDSFA
案例3	71.50	40.00	25.50	6.00
案例4	68.00	48.75	35.00	26.25

下载: 导出CSV

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