Scenario construction and risk analysis of confined space operations based on Bayesian networks

doi:10.16265/j.cnki.issn1003-3033.2026.05.0797

Abstract

Abstract:

In order to accurately identify risks and effectively prevent accidents in confined space operations, a scenario-based accident evolution model grounded in key elements was developed to conduct quantitative risk analysis. This study addressed confined space operations by systematically organizing their key elements, which encompass physical characteristics, spatiotemporal context, environmental conditions, safety management, and emergency decision-making. The Web Ontology Language (OWL) was employed to standardize the description of these elements and represent the scenarios, thereby enabling a structured and standardized characterization of accident evolution. Drawing upon data from nearly 50 domestic confined space accident cases, as well as current standards and expert knowledge, the study performed state-based description and correlation analysis on critical aspects, including gas detection, ventilation, personal protective equipment, and accident consequences throughout the operational process. A BN structure and probability parameters were established accordingly. An empirical analysis of a confined space poisoning accident was conducted to validate the model. The results show that the systematic identification of critical safety factors contributes to the structured management of accident knowledge. Furthermore, the BN model constructed on this basis enables quantitative risk assessment and scenario deduction. The empirical findings demonstrate that risk-ignorant rescue attempts constitute the primary factor exacerbating outcomes in confined space accidents, particularly when multiple non-professional responders enter without personal protective equipment. Therefore, emergency plans should clearly define rescue procedures, responsibilities, and protection requirements.

Key words: Bayesian network(BN), confined space, operations scenario, risk analysis, scenario construction, scenario deduction

CLC Number:

X913.4安全系统工程

Wang Haijun, Zhang Yue. Scenario construction and risk analysis of confined space operations based on Bayesian networks[J]. China Safety Science Journal, 2026, 36(5): 38-47.

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情景要素	具体分类	说明
孕灾环境	封闭或半封闭设备	船舱、储罐、反应釜、冷藏箱、压力容器、锅炉等
	地上受限空间	储藏室、酒糟池、发酵池、垃圾站、温室、粮仓等
	地下受限空间	地下管道、地下工程、暗沟、隧道、涵洞、废井、地窖、污水池(井)、沼气池、化粪池、下水道等
	受限空间周边范围	受限空间外部受事故影响范围
致灾因子	人的因素	违章进入受限空间;作业前未检测通风;作业时未佩戴个体防护装备
	物的因素	可燃气;粉尘和气溶胶;其他有害物质
	环境因素	氧含量;温度;湿度
	管理因素	受限空间作业责任未落实;事故应急预案及响应缺陷
管控措施	作业安全管理;应急决策	作业安全责任落实;通风;疏散;急救;消防
承灾载体	人员伤亡;经济损失; 环境破坏;影响范围	人员窒息中毒;火灾;爆炸

节点类型	节点名称	节点状态
节点类型	节点名称	State1	State2	State3	State4
输入变量	安全作业责任	责任明确且措施到位	责任明确但措施不到位	责任模糊且措施不足	责任缺失且违法违规操作
	应急预案	完备且演练充分	完备但无演练	不完备但有演练	不完备且无演练
	气体检测	检测全面且连续有效	检测气体类型不全或频次不足	检测设备异常或使用错误	未进行检测
	通风措施	连续性强制通风	间歇性通风或自然通风	通风措施或装置存在缺陷	无通风措施
	防护装备	装备齐全且佩戴规范	装备齐全但佩戴不规范	装备不齐全	无有效装备
	温度/℃	18~26	26~35	>35	≤18
	湿度/%	30~60	60~85	>85	≤30
状态变量	氧气体积分数/%	≤16	16~19.5	19.5~23.5	>23.5
	有害气、蒸气体积分数/%	≤30 MAC	30~100 MAC	>100 MAC	—
	可燃气、蒸气体积分数/%	≤5 LEL	5~10 LEL	>10 LEL	—
	盲目施救	严格按照应急预案组织施救	施救程序不规范或装备不足	未佩戴防护装备盲目施救	多人未佩戴防护装备盲目施救
输出变量	窒息	无人员缺氧	人员轻度缺氧可自行撤离	人员中度缺氧需他人协助撤离	人员重度缺氧出现昏迷或死亡
	中毒	无人员中毒	人员轻度中毒可自行恢复	人员中度中毒需医疗救治	人员重度中毒出现昏迷或死亡
	火灾	未发生火灾	小范围起火可自行扑灭	火势蔓延需专业消防介入	火势较大导致人员伤亡
	爆炸	未发生爆炸	存在爆炸性混合物但未引爆	小规模爆炸未导致人员伤亡	大规模爆炸导致人员伤亡、结构损毁等连锁反应

地区	行业	受限空间类型	事故起数
北京	建筑;市政	电缆井;污水池	28
浙江	工贸	污水池;腌制池	3
河南	工贸;危化	污水池;好氧池;储罐	3
湖南	工贸	污水池;纸浆池;腌制池	3
河北	工贸	污水池;浮渣池	2
辽宁	工贸	腌制池	2
广东	工贸;市政	污水池	2
山西	工贸;危化	污水井;冷却池	2
四川	工贸;市政	腌制池;污水池	2
上海	工贸;建筑	储罐;地下工程	2
山东	工贸	回水循环池	1

根节点	State1	State2	State3	State4
安全作业责任	0.010	0.010	0.157	0.823
温度	0.071	0.898	0.031	—
湿度	0.754	0.246	—	—

情景	时间	孕灾环境	致灾因子	承灾载体	管控措施
初始情景	13:00左右	地上受限空间(原料浆池)	人的因素:作业前未检测通风、作业时未佩戴个体防护装备物的因素:有害气含量高(硫化氢) 环境因素:氧含量低(玉米浆可能混入地下水,并长期处于厌氧环境)	3人在池底进行抽浆作业,2人在池边协助	受限空间安全作业责任未落实
中间情景	13:30左右			池底作业的3人中毒晕倒,池边协助的1人入池救援,1人外出呼救	未采取有效防护措施,盲目施救
中间情景	13:44左右			公司人员共7人到达现场,3人入池救援	未采取有效防护措施,盲目施救
结束情景	14:17左右			寿光市消防救援大队和公司人员协作救出池内7人,11人送医救治,7人经抢救无效死亡	—