基于改进DS理论-FBN的城市内涝灾害应急能力评估

doi:10.16265/j.cnki.issn1003-3033.2025.05.1448

摘要/Abstract

摘要：

为提升城市内涝灾害应急能力,提出一种基于改进DS理论和模糊贝叶斯网络(FBN)结合的应急能力评估模型。首先,从灾害应急管理的全过程出发,建立城市内涝灾害应急能力评估指标体系,并映射为贝叶斯网络(BN);然后,针对评估过程中的信息不确定性以及主观性较强等问题,引入改进DS理论确定指标权重,利用专家知识结合模糊集量化根节点的先验概率,采用事故树分析关键指标并利用排序质心法对基本事件概率赋值,通过FBN模型计算内涝灾害风险概率,在此基础上进行应急能力评估和推理分析;最后,以郑州市主城区为例,利用GeNIe4.0软件生成内涝灾害应急能力评估BN模型,并得到该市的内涝灾害应急能力等级和敏感指标。研究结果表明:该市主城区内涝灾害应急能力为良,影响应急能力的敏感指标为应急响应及时性、预警信息发布规范性、应急处置专业性和内涝信息反馈准确性。

关键词: 模糊贝叶斯网络(FBN), DS理论, 城市内涝灾害, 应急能力评估, 城市雨水系统

Abstract:

In order to improve the emergency response capacity of urban flooding disasters, an emergency response capacity assessment model based on the combination of improved DS evidence theory and FBN was proposed. Firstly, from the whole process of disaster emergency management, the urban flood disaster emergency response capacity assessment index system was established and mapped into a Bayesian network (BN) model. Then, to address the problems of information uncertainty and strong subjectivity in the assessment process, the improved DS theory was introduced to determine the index weights. The expert knowledge combined with the fuzzy set was used to qua.pngy the prior probability of the root node. The accident tree was applied to analyze the key indexes, and the Sorting center of mass method was used to assign basic event probabilities. The probability of flooding disaster risk was calculated through the BN model. Emergency response capacity assessment and reasoning analysis were carried out on the basis of the above results. Finally, take the main urban area of Zhengzhou city as an example, GeNIe4.0 software was used to generate the BN model of emergency response capacity assessment of flooding disaster, and the emergency response capacity level and sensitive indexes of flooding disaster in the city were obtained. The results show that the emergency response capacity of the main urban area of the city is good. The sensitive indicators affecting the emergency response capacity are timeliness of the emergency response, normality of the warning information release, professionalism of the emergency response and accuracy of flooding information feedback.

Key words: fuzzy Bayesian networks (FBN), DS theory, urban flooding disaster, emergency capacity assessment, urban stormwater systems

中图分类号:

X915.5

刘冬华, 张睿阳, 郭梨. 基于改进DS理论-FBN的城市内涝灾害应急能力评估[J]. 中国安全科学学报, 2025, 35(5): 255-262.

LIU Donghua, ZHANG Ruiyang, GUO Li. Emergency response capacity assessment for urban flooding disasters based on improved DS theory and FBN[J]. China Safety Science Journal, 2025, 35(5): 255-262.

图/表 14

图1

图2

表1

图3

表2

图4

表3

表4

表5

表6

表7

表8

图5

图6

参考文献 22

[1]	赵超辉, 万金红, 张云霞, 等. 城市内涝特征、成因及应对研究综述[J]. 灾害学, 2023, 38(1): 220-228.
	ZHAO Chaohui, WAN Jinhong, ZHANG Yunxia, et al. Review of the characteristics, causes and governance of urban flood in China[J]. Journal of Catastrophology, 2023, 38(1): 220-228.
[2]	汪军能, 秦年秀, 姜彤, 等. IPCC AR6报告解读:气候变化对城市、住宅和关键基础设施的影响与适应[J]. 气候变化研究进展, 2022, 18(4): 433-441.
	WANG Junneng, QIN Nianxiu, JIANG Tong, et al. Interpretation of IPCC AR6: impacts and adaptations of climate change on cities, settlements and key infrastructure[J]. Climate Change Research, 2022, 18(4): 433-441.
[3]	中华人民共和国应急管理部. 国家防灾减灾救灾委员会办公室应急管理部发布2023年全国自然灾害基本情况[EB/OL].(2024-01-20).https://www.mem.gov.cn/xw/yjglbgzdt/202401/t20240120_475697.shtml.
[4]	LI Xianghai, LI Mengjie, CUI Kaikai, et al. Evaluation of comprehensive emergency capacity to urban flood disaster: an example from Zhengzhou city in Henan province, China[J]. Sustainability, 2022, 14(21): DOI:10.3390/SU142113710.
[5]	LIU Delin, YANG Zhuowei, XU Xiangyang, et al. Assessment and influencing factors of urban residents' flood emergency preparedness capacity: an example from Jiaozuo city, China[J]. International Journal of Disaster Risk Reduction, 2024, 102: DOI: 10.1016/j.ijdrr.2024.104294.
[6]	刘云熹, 时德轶, 张鹏, 等. 城市灾害事故应急能力评估指标体系构建研究[J]. 中国安全生产科学技术, 2024, 20(1): 179-186.
	LIU Yunxi, SHI Deyi, ZHANG Peng, et al. Research on construction of index system for emergency capability assessment of urban disasters and accidents[J]. Journal of Safety Science and Technology, 2024, 20(1): 179-186.
[7]	MILI R R, HOSSEINI A K, IZADKHAHI O Y. Developing a holistic model for earthquake risk assessment and disaster management interventions in urban fabrics[J]. International Journal of Disaster Risk Reduction, 2018,27:355-365.
[8]	齐春泽, 代文锋. 基于云模型的城市灾害应急能力评价[J]. 统计与决策, 2019, 35(4): 41-45.
	QI Chunze, DAI Wenfeng. Evaluation on capability of urban emergency response to disaster based on cloud model[J]. Statistics & Decision, 2019, 35(4): 41-45.
[9]	彭恒明, 王铁骊. 基于Z-numbers的城市内涝灾害应急能力评价研究[J]. 中国安全生产科学技术, 2020, 16(5): 115-121.
	PENG Hengming, WANG Tieli. Study on evaluation of emergency capacity for urban waterlogging disaster based on Z-numbers[J]. Journal of Safety Science and Technology, 2020, 16(5): 115-121.
[10]	胡孙琪, 徐晓玲, 胡煜文, 等. 基于AHP-模糊综合法的城市应急管理能力评价研究[J]. 武汉理工大学学报:信息与管理工程版, 2022, 44(2): 188-194.
	HU Sunqi, XU Xiaoling, HU Yuwen, et al. Evaluation of city emergency management capability based on AHP-fuzzy comprehensive evaluation[J]. Journal of Wuhan University of Technology: Information & Management Engineering, 2022, 44(2): 188-194.
[11]	KONG Dewei, LIN Zelong, LI Wei, et al. Development of an improved Bayesian network method for maritime accident safety assessment based on multiscale scenario analysis theory[J]. Reliability Engineering and System Safety, 2024,251: DOI: 10.1016/j.ress.2024.110344.
[12]	WANG Shuang, WANG Jiashi, WANG Xinjian. Risk analysis of human evacuation aboard passenger ships based on fuzzy DEMATEL-ISM-BN[J]. Ocean Engineering, 2024, 313(3): DOI: 10.1016/j.oceaneng.2024.119520.
[13]	李金蓉, 杨玉中. DS理论-贝叶斯网络下的煤矿通风系统风险评估[J]. 中国安全科学学报, 2022, 32(8): 146-153. doi: 10.16265/j.cnki.issn1003-3033.2022.08.1633
	LI Jinrong, YANG Yuzhong. Risk assessment of ventilation system in coal mines based on DS theory and Bayesian network[J]. China Safety Science Journal, 2022, 32(8): 146-153. doi: 10.16265/j.cnki.issn1003-3033.2022.08.1633
[14]	蒋俊, 陈妍, 贺钢锋, 等. 城市应急准备能力评估体系构建及应用[J]. 中国安全科学学报, 2023, 33(6): 190-197. doi: 10.16265/j.cnki.issn1003-3033.2023.06.2446
	JIANG Jun, CHEN Yan, HE Gangfeng, et al. Construction and application of urban emergency preparedness capability assessment index system[J]. China Safety Science Journal, 2023, 33(6): 190-197. doi: 10.16265/j.cnki.issn1003-3033.2023.06.2446
[15]	徐瑞华, 张攀科, 罗帆, 等. 河南省社区居民洪涝灾害应急能力评价研究[J]. 安全与环境工程, 2024, 31(3): 23-31.
	XU Ruihua, ZHANG Panke, LUO Fan, et al. Evaluation of flood disaster emergency response capacity of community residents in Henan Province[J]. Safety and Environmental Engineering, 2024, 31(3): 23-31.
[16]	GB 50318—2017, 城市排水工程规划规范[S].
	GB 50318-2017, Code for urban wastewater and stormwater engineering planning[S].
[17]	GB 51222—2017, 城镇内涝防治技术规范[S].
	GB 51222-2017, Technical specification for urban flood control[S].
[18]	DENG Xinyang, ZHENG Xi, SU Xiaoyan. An evidential game theory framework in multi-criteria decision[T]. Applied Mathematics and Computation, 2014, 244: 783-793.
[19]	杨震, 刘哲明, 郭梨. 金属矿深井充填管道系统失效风险可视化分析方法[J]. 金属矿山, 2022 (4): 173-179.
	YANG Zhen, LIU Zheming, GUO Li. Visual analysis method of failure risk of deep filling pipeline system in metal mine[J]. Metal Mine, 2022(4): 173-179.
[20]	GUAN Xinjian, YU Fengjiao, XU Hongshi, et al. Flood risk assessment of urban metro system using random forest algorithm and triangular fuzzy number based analytical hierarchy process approach[J]. Sustainable Cities and Society, 2024,109: DOI:10.1016/j.scs.2024.105546.
[21]	赵振武, 贾朋霖. 融合改进D-S理论与贝叶斯网络的机场旅客风险研究[J]. 安全与环境学报, 2023, 23(12): 4425-4434.
	ZHAO Zhenwu, JIA Penglin. Research on airport passenger risk by fusing improved D-S theory and Bayesian network[J]. Journal of Safety and Environment, 2023, 23(12): 4425-4434.
[22]	田晓敏, 李晓冬. 基于故障树-模糊贝叶斯网络的装配式建筑施工质量风险分析[J]. 科学技术与工程, 2024, 24(30): 13 119-13 126.
	TIAN Xiaomin, LI Xiaodong. Quality risk analysis of prefabricated building construction based on fault tree analysis-fuzzy Bayesian network[J]. Science Technology and Engineering, 2024, 24(30): 13 119-13 126.

符号	故障	符号	故障
Z	雨水系统排水能力不足	X₄	管网建设不完善
E₁	小排水系统排水能力不足	X₅	雨水设施组件老化
E₂	蓄排设施失效	X₆	雨污分流不彻底
Y₁	雨水排水设施压力增大	X₇	源头减排设施欠缺
Y₂	蓄排设施欠缺	X₈	不透水面增加
X₁	运维管理不当	X₉	河道运力不足
X₂	调度措施不当	X₁₀	调蓄设施欠缺
X₃	雨水设施规划设计标准低	X₁₁	排放通道缺乏

内涝灾害风险概率/%	评估等级	评估级别
[0,20)	1	应急能力优
[20,40)	2	应急能力良
[40,60)	3	应急能力一般
[60,80)	4	应急能力较差
[80,100)	5	应急能力差

评价集	符号	模糊评价值
高	V₁	0.9
较高	V₂	0.7
中	V₃	0.5
较低	V₄	0.3
低	V₅	0.1

指标	专家1	专家2	专家3	专家4
A₁₁	({V₁},0.8;{V₂},0.2})	({V₁,1})	({V₁},0.9;{V₂},0.1})	({V₁},0.5;{V₂},0.5})
A₁₂	({V₁},0.2;{V₂},0.8})	({V₂},1})	({V₁},0.3;{V₂},0.7})	({V₁},0.1;{V₂},0.9})
A₁₃	({V₂},0.8;{V₃},0.2})	({V₂},0.3;{V₃},0.7})	({V₂},0.6;{V₃},0.4})	({V₂},0.5;{V₃},0.5})
A₁₄	({V₁},0.6;{V₂},0.4})	({V₁},0.3;{V₂},0.7})	({V₁},0.7;{V₂},0.3})	({V₁},0.2;{V₂},0.8})

指标	专家1	专家2	专家3	专家4
A₁₁	0.317 3	0.227 6	0.272 4	0.182 7
A₁₂	0.270 6	0.229 4	0.229 4	0.270 6
A₁₃	0.205 1	0.205 1	0.294 9	0.294 9
A₁₄	0.274 7	0.274 7	0.225 3	0.225 3