洪涝灾害下城市大规模人员疏散分区规划方法

吕伟, 江惠华, 汪京辉, 杨晓婷

doi:10.16511/j.cnki.qhdxxb.2024.26.014

清华大学学报（自然科学版） >

2024 , Vol. 64 >Issue 11: 1880 - 1892

DOI: https://doi.org/10.16511/j.cnki.qhdxxb.2024.26.014

专题：公共安全科学与技术

洪涝灾害下城市大规模人员疏散分区规划方法

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武汉理工大学安全科学与应急管理学院, 武汉 430070

收稿日期: 2023-10-15

网络出版日期: 2024-11-05

基金资助

国家自然科学基金资助项目(52072286)

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Urban large-scale evacuation zoning planning methods for flooding disasters

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School of Safety Science and Emergency Management, Wuhan University of Technology, Wuhan 430070, China

Received date: 2023-10-15

Online published: 2024-11-05

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摘要

为提高城市大尺度转移效率, 基于城市兴趣点(points of interest, POI)功能区分布情况, 考虑城市人口在昼夜时段的分布热点及灾害对路网的破坏作用, 对洪涝灾害影响边界内城市灾民进行科学分区分配, 建立双层规划优化模型。上层模型利用遗传算法求解系统总成本最小问题, 下层模型应用用户均衡方式求解疏散人员分配问题, 形成一整套综合考虑人口热点分布和洪涝灾害风险对路网影响的疏散分区和路网规划方法, 并以武汉市武昌区为研究对象, 验证疏散分区规划方法的可行性。结果表明：该文所提出的疏散分区规划方法可行, 考虑城市人口在昼夜时段的分布热点和灾害风险对路网影响的疏散方法更合理。研究结果可为组织管理部门应急疏散规划工作提供参考。

关键词： 疏散分区规划; 双层规划优化模型; 城市热点; 灾害风险

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吕伟, 江惠华, 汪京辉, 杨晓婷 . 洪涝灾害下城市大规模人员疏散分区规划方法[J]. 清华大学学报（自然科学版）, 2024 , 64(11) : 1880 -1892 . DOI: 10.16511/j.cnki.qhdxxb.2024.26.014

Abstract

[Objective] Safe and effective evacuation of individuals during extreme weather conditions is critical in evacuation planning. Compared with traditional personnel evacuation and emergency transportation studies, evacuation zone planning is in its early stages. It lacks comprehensive consideration of major urban disaster scenarios, particularly beyond hurricanes. Additionally, there is no unified system for defining problems or measuring urban population hotspots, spatiotemporal disaster impacts, and exit distribution in evacuation planning. To address the practical issues of evacuating affected individuals during heavy rain and flood disasters, this paper proposes a model for delineating evacuation zones. [Methods] Starting with establishing evacuation needs and quantifying the impact of disasters on road segments, this study considers urban population distribution hotspots and the characteristics of heavy rain and flood disasters. Through modeling analysis, geographic information system (GIS) visualization, and other methods, a model is developed for the integrated delineation of evacuation zones and the allocation of evacuees at exits. The main components include the following: (1) To identify hotspot areas in urban functional zones and establish evacuation needs based on the city’s road network. (2) To assess the risk of heavy rain and flood disasters, establish a risk indicator system for flood risk assessment (including causative factors, disaster-prone environments, disaster-prone bodies, and disaster prevention and mitigation capabilities), and develop a road damage model to determine road network damage. (3) To construct a two-tier planning optimization model to determine evacuation paths and exit allocations. (4) To use Wuhan’s Wuchang district as an example, the effectiveness of the proposed method for large-scale urban evacuation zone planning under flood disasters is validated. The upper-level model provides the proportion of evacuees that each evacuation point should accommodate, with these allocation ratios stored in chromosomes as input for the lower level. The lower-level problem uses the incoming allocation ratios to calculate the evacuation flow for each OD pair and evaluates the fitness of the upper-level chromosomes. This is achieved using the Frank-Wolfe algorithm. The two-tier framework allows for detailed treatment of complex evacuation planning problems, ensuring the global minimization of total evacuation time and individual minimization of evacuee travel time. [Results] The innovative aspects included identifying evacuation needs in urban hotspots and constructing road damage levels under risk zoning for heavy rain and flood disasters. The two-tier planning optimization model minimized overall evacuation time and individual travel time, making the evacuation plan more realistic and reasonable. [Conclusions] The proposed method for large-scale urban evacuation zone planning is feasible, risk assessment is essential in actual evacuation planning. Significant differences exist in day and night population distribution with daytime populations primarily concentrated in commercial and work areas and nighttime populations concentrated in residential areas. Emergency management departments should develop varied evacuation plans for different periods. Due to potential road damage during disasters, preplan alternative evacuation routes and make real-time dynamic adjustments during evacuations.

Key words： evacuation zone planning; two-tier planning and optimization model; urban hotspots; disaster risk

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