Restoration Model for Cascading Overload Failure in Syncretic Railway Network

IF 2 4区工程技术 Q2 ENGINEERING, CIVIL

Journal of Advanced Transportation Pub Date : 2024-07-05 DOI:10.1155/2024/8244319

Qingwei Zhong, Su Liu, Jingwei Guo, Linfeng Zhong, Zhihong Yao

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Abstract

The different rail transit systems, such as regional railway and urban rail transit, cooperate to form the syncretic railway network (SRN). With the rapid development of SRN, the limited transportation capacity is inadequate to meet the booming passenger flow during peak hours, where cascading failures caused by large passenger flow become a threat to SRN. This paper adopts a state equation to depict the failure-restoration process and investigates detailed restoration strategies considering the characteristics of recoverable and repeatable failures of stations. Specifically, three different restoration strategies—spontaneous restoration strategy (SRS), active restoration strategy (ARS), and hybrid restoration strategy (HRS)—are proposed, and the varying effects of restoration time, restoration probability, restoration objective, and restoration priority for SRN with ARS are compared. These restoration strategies are applied to the actual SRN in Chengdu, where it is found that HRS has a better effect than other strategies. Furthermore, stations in the metro network with higher passenger flow allocate more restoration resources to improve the robustness of SRN, while the restoration effect of SRN increases noticeably with the restoration coefficient and the reserve coefficient. The restoration strategies presented in this paper can improve the safety management of SRN.

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同步铁路网中级联过载故障的恢复模型

区域铁路和城市轨道交通等不同的轨道交通系统相互配合，形成了同步铁路网（SRN）。随着 SRN 的快速发展，有限的运输能力已无法满足高峰时段激增的客流，大客流引发的级联故障已成为 SRN 的威胁。本文采用状态方程来描述故障-修复过程，并结合车站故障的可恢复性和可重复性特点，研究了详细的修复策略。具体而言，本文提出了三种不同的修复策略--自发修复策略（SRS）、主动修复策略（ARS）和混合修复策略（HRS），并比较了修复时间、修复概率、修复目标和修复优先级对采用 ARS 的 SRN 的不同影响。将这些修复策略应用于成都的实际 SRN，发现 HRS 比其他策略效果更好。此外，地铁网络中客流量较大的车站会分配更多的修复资源以提高 SRN 的鲁棒性，而 SRN 的修复效果会随着修复系数和储备系数的增加而明显提高。本文提出的修复策略可以提高 SRN 的安全管理水平。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Advanced Transportation 工程技术-工程：土木

CiteScore

5.00

自引率

8.70%

发文量

466

审稿时长

7.3 months

期刊介绍： The Journal of Advanced Transportation (JAT) is a fully peer reviewed international journal in transportation research areas related to public transit, road traffic, transport networks and air transport. It publishes theoretical and innovative papers on analysis, design, operations, optimization and planning of multi-modal transport networks, transit & traffic systems, transport technology and traffic safety. Urban rail and bus systems, Pedestrian studies, traffic flow theory and control, Intelligent Transport Systems (ITS) and automated and/or connected vehicles are some topics of interest. Highway engineering, railway engineering and logistics do not fall within the aims and scope of JAT.