HAZOP information standardization framework based on knowledge ontology

doi:10.16085/j.issn.1000-6613.2019-1445

Abstract

Abstract:

Many human-based HAZOP (hazard and operability analysis) results were stored as paper documents. It is difficult to reuse and share the results. At the same time, the computer-aided HAZOP results can only be recognized by the special software. The results are also difficult to reuse and share. For the problem, the HAZOP information standardization framework was proposed. The HAZOP standard information model including the model structure, definitions of the elements and relationships of elements was proposed basing on knowledge ontology and HAZOP international standard IEC 61882. The HAZOP information standardization approach was proposed based on the model. Every HAZOP record was tagged, trained and identified using BiLSTM neural network in the approach. The human-based HAZOP results can be identified and standardized automatically by the approach. The framework was used for HAZOP of an oil synthesis equipment. It was proved that the HAZOP results can be transformed to the standard form automatically using the framework. The HAZOP information can also be reused and shared easily.

Key words: safety, knowledge ontology, hazard and operability analysis (HAZOP), standardization, model, neural networks

摘要：

大量的危险与可操作性分析（hazard and operability analysis，HAZOP）报告以纸质文档形式保存，难于复用、共享，同时基于计算机软件的分析结果也只有对应的分析软件才能识别，同样存在难于复用、共享的问题。针对此问题，本文提出了基于知识本体的HAZOP信息标准化框架。该框架以知识本体和HAZOP分析国际标准IEC 61882为基础，抽提归纳了HAZOP的标准化信息模型，给出了模型的整体结构、模型中各元素的定义与关系。并在此基础上，提出了HAZOP信息标准化方法，采用BiLSTM神经网络对每一条HAZOP分析的记录进行标注、训练与识别，实现了人工HAZOP分析结果的自动识别与标准化。以某油品合成装置为例，对HAZOP信息标准化方法进行了验证，结果表明基于知识本体的HAZOP信息标准化框架可以自动实现分析结果的标准化，便于分析知识的共享与复用。

关键词: 安全, 知识本体, 危险与可操作性分析, 标准化, 模型, 神经网络

CLC Number:

TH 391.7

Dong GAO, Yao XIAO, Beike ZHANG, Xin XU, Chongguang WU. HAZOP information standardization framework based on knowledge ontology[J]. Chemical Industry and Engineering Progress, 2020, 39(6): 2510-2518.

高东, 肖遥, 张贝克, 许欣, 吴重光. 基于知识本体的HAZOP信息标准化框架[J]. 化工进展, 2020, 39(6): 2510-2518.

References

1	吴重光. 危险与可操作性分析(HAZOP)基础及应用[M]. 北京: 中国石化出版社, 2012.
1	WU C G. Hazard and operability analysis basic and application[M]. Beijing: China Petrochemical Press, 2012.
2	李毅, 熊亮, 邓海发, 等. SIL评估及HAZOP分析技术在海洋平台安全评估中的应用[J]. 中国安全生产技术, 2013, 9(8): 119-124.
2	LI Y, XIONG L, DENG H F, et al. Application of SIL evaluation and HAZOP analysis technology in safety assessment of offshore platform[J]. Journal of Safety Science and Technology, 2013, 9(8): 119-124.
3	肖成侠, 陈全. HAZOP在煤矿通风系统安全风险分析中的应用[J]. 中国安全生产技术, 2013, 9(11): 97-102.
3	XIAO C X, CHEN Q. Application of HAZOP in safety risk analysis of mine ventilation system[J]. Journal of Safety Science and Technology, 2013, 9(11): 97-102.
4	周帅, 施富强, 柴俭. HAZOP-偏离度在铁路安全风险分析中的应用[J]. 中国安全科学学报, 2014, 24(8): 92-96.
4	ZHOU S, SHI F Q, CHAI J. HAZOP-based safety risk analysis technology for railway operation[J]. Journal of Safety Science and Technology, 2014, 24(8): 92-96.
5	桂阳, 张明广, 虞奇, 等. 苯硝化工艺HAZOP分析的定量化研究[J]. 工业安全与环保, 2016, 42(10): 44-46.
5	GUI Y, ZHANG M G, YU Q, et al. Study on HAZOP quantitative analysis of benzene nitrification based on simulation[J]. Industry Safety and Environment Protection, 2016, 42(10): 44-46.
6	WU J, LIND M. Management of system complexity in HAZOP for the oil & gas industry[J]. IFAC-PapersOnLine, 2018, 51(8): 211-216.
7	POLAT S. Predictive analysis and recommendation for managing risk and avoiding hazard in chemical and oil & gas industrial infrastructures[D]. Calgary: University of Calgary, 2018.
8	许晶, 刘义, 张毅, 等. 基于HAZOP的应急指导系统研究与开发[J]. 安全健康与环境, 2016, 16(1): 14-17.
8	XU J, LIU Y, ZHANG Y, et al. The research and development of emergency guidance system based on HAZOP[J]. Safety Health & Environment, 2016, 16(1): 14- 17.
9	TAYLOR J R. Automated HAZOP revisited[J]. Process Safety and Environmental Protection, 2017, 111: 635-651.
10	VENKATASUBRAMANIAN V. Intelligent systems for HAZOP analysis of complex process plants[J]. Computers and Chemical Engineering, 2000, 24: 2291-2302.
11	赵劲松, 赵利华, 崔林, 等. 基于案例推理的HAZOP分析自动化框架[J]. 化工学报, 2008, 59(1): 111-117.
11	ZHAO J S, ZHAO L H, CUI L. Case based reasoning framework for automating HAZOP analysis[J]. Journal of Chemical Industry and Engineering (China), 2008, 59(1): 111-117.
12	ZHANG Y L, ZHANG W T, ZHANG B K. Automatic HAZOP analysis method for unsteady operation in chemical based on qualitative simulation and inference[J]. Chinese Journal of Chemical Engineering, 2015, 23: 2065 -2074.
13	CHEN J, LIU X, JING S, et al. A process simulation-based quantitative HAZOP analysis method[C]//2016 IEEE International Conference on Service Operations and Logistics, and Informatics (SOLI). IEEE, 2016: 239-244.
14	RAONI R, SECCHI A R, DEMICHELA M. Employing process simulation for hazardous process deviation identi?cation and analysis[J]. Safety Science, 2018, 101: 209-219.
15	KO?CIELNY J M, SYFERT M, FAJDEK B, et al. The application of a graph of a process in HAZOP analysis in accident prevention system[J]. Journal of Loss Prevention in the Process Industries, 2017, 50(A): 55-66.
16	SUALIM S, MOHAMAD R, SAADON N A. Ontology of mutation testing for Java operators[J]. International Journal of Innovative Computing, 2018, 8(2): 49-60.
17	ZHANG S, TEIZER J, BOUKAMP F. Automated ontology-based job hazard analysis (JHA) in building information modelling (BIM)[C]// Proceedings of CIB W099 International Conference on “Modelling and Building Health and Safety. Korea: Korea Institute of Architecture and Management, 2012: 74-81.
18	ZHANG X, LIND M, J?RGENSEN S B, et al. Extending MFM function ontology for representing separation and conversion in process plant[C]//Proceedings of 7th International Conference on Water and Flood Management, 2019.
19	ISO. Industrial automation systems and integration-Integration of life-cycle data for process plants including oil and gas production facilities—Part 1: Overview and fundamental principles: ISO 15926-1: 2004[S]. 2004.
20	LEE B H. Using FMEA models and ontologies to build diagnostic models[J]. Artificial Intelligence for Engineering Design, Analysis and Manufacturing, 2001, 15: 281-293.
21	KURAOKA K, BATRES R. An ontological approach to represent HAZOP information[R]. Process Systems Engineering Laboratory, Tokyo Institute of Technology, Technical Report TR-2003.
22	BATRES R, SUZUKI T, SHIMADA Y, et al. A graphical approach for hazard identification[C]//18th European Symposium on Computer Aided Process Engineering IFP, CAPE Working Party of the European Federation of Chemical Engineering, France. 2008: 197-202.
23	吴重光, 许欣, 纳永良, 等. 基于知识本体的过程安全分析信息标准化[J]. 化工学报, 2012, 63(5): 1485-1491.
23	WU C G, XU X, NA Y L, et al. Standardized information for process hazard analysis based on ontology[J]. CIESC Journal, 2012, 63(5): 1485-1491.
24	张贝克, 许欣, 纳永良, 等. 基于图形化剧情对象模型的安全评价及应用[J]. 化工学报, 2013, 64(7): 2511-2519.
24	ZHANG B K, XU X, NA Y L, et al. Hazard analysis and application based on graphical scenario object model[J]. CIESC Journal, 2013, 64(7): 2511-2519.
25	WU C G, XU X, ZHANG B K, et al. Domain ontology for scenario-based hazard evaluation[J]. Safety Science, 2013, 60: 21-34.
26	GAO D, ZHANG B K, XU X, et al. Scenario object model based on-line hazard analysis for chemical process[J]. Kem. Ind., 2017, 66 (11/12): 601-610.
27	CHEN T, XU R, HE Y, et al. Improving sentiment analysis via sentence type classification using BiLSTM-CRF and CNN[J]. Expert Systems with Applications, 2017, 72: 221-230.

[1]	XU Chenyang, DU Jian, ZHANG Lei. Chemical reaction evaluation based on graph network [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 205-212.
[2]	ZHANG Fan, TAO Shaohui, CHEN Yushi, XIANG Shuguang. Initializing distillation column simulation based on the improved constant heat transport model [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4550-4558.
[3]	WU Zhenghao, ZHOU Tianhang, LAN Xingying, XU Chunming. AI-driven innovative design of chemicals in practice and perspective [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 3910-3916.
[4]	ZHANG Zhichen, ZHU Yunfeng, CHENG Weishu, MA Shoutao, JIANG Jie, SUN Bing, ZHOU Zichen, XU Wei. Research advances on runaway decomposition of high pressure polyethylene: Reaction mechanism, initiation system and model [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 3979-3989.
[5]	GUO Jin, ZHANG Geng, CHEN Guohua, ZHU Ming, TAN Yue, LI Wei, XIA Li, HU Kun. Research progress on vehicle liquid hydrogen cylinder design [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4221-4229.
[6]	ZHANG Zhen, LI Dan, CHEN Chen, WU Jinglan, YING Hanjie, QIAO Hao. Separation and purification of salivary acids with adsorption resin [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4153-4158.
[7]	QIAO Xu, ZHANG Zhuxiu. Consideration and exploration of the development path for inherent safety of chemical engineering [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3319-3324.
[8]	WU Zhanhua, SHENG Min. Pitfalls of accelerating rate calorimeter for reactivity hazard evaluation and risk assessment [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3374-3382.
[9]	SHAN Xueying, ZHANG Meng, ZHANG Jiafu, LI Lingyu, SONG Yan, LI Jinchun. Numerical simulation of combustion of flame retardant epoxy resin [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3413-3419.
[10]	WANG Jiaxin, PAN Yong, XIONG Xinyi, WAN Xiaoyue, WANG Jianchao. Reaction process and hazards of dinitrotoluene preparation by one-step catalytic nitration of toluene [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3420-3430.
[11]	BAI Yadi, DENG Shuai, ZHAO Ruikai, ZHAO Li, YANG Yingxia. Exploration on standardized test scheme and experimental performance of temperature swing adsorption carbon capture unit [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3834-3846.
[12]	ZHAO Yi, YANG Zhen, ZHANG Xinwei, WANG Gang, YANG Xuan. Molecular simulation of self-healing behavior of asphalt under different crack damage and healing temperature [J]. Chemical Industry and Engineering Progress, 2023, 42(6): 3147-3156.
[13]	LU Shijian, ZHANG Yuanyuan, WU Wenhua, YANG Fei, LIU Ling, KANG Guojun, LI Qingfang, CHEN Hongfu, WANG Ning, WANG Feng, ZHANG Juanjuan. Health risk assessment of nitrosamine pollutant diffusion in a million ton CO₂ capture project [J]. Chemical Industry and Engineering Progress, 2023, 42(6): 3209-3216.
[14]	ZHOU Lei, SUN Xiaoyan, TAO Shaohui, CHEN Yushi, XIANG Shuguang. Development and application of refinery short-cut column model [J]. Chemical Industry and Engineering Progress, 2023, 42(6): 2819-2827.
[15]	ZHAO Jingbin, WANG Yanfu, WANG Tao, MA Weikai, WANG Chen. Vulnerability assessment of storage tanks based on Monte Carlo simulation and dynamic event tree [J]. Chemical Industry and Engineering Progress, 2023, 42(5): 2751-2759.