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通过现实世界相互依赖的城市基础设施理解级联风险

Understanding cascading risks through real-world interdependent urban infrastructure

Reliability Engineering and System Safety · 2023
被引 73 · 同刊同年前 9%
ABS 3

中文导读

研究了沿海洪水事件下电力、供水和污水网络的级联失效,发现考虑相互依赖后受影响用户数比直接受损用户增加216%,为运营商和应急响应提供决策支持。

Abstract

The prevalence of cascading failures is growing as infrastructure becomes more interdependent and climate change exacerbates more extreme hazards. After such events, the general focus is on the magnitude of direct damage or loss; it is less understood how events trigger failures throughout other infrastructure. In this work, we present a methodology to model direct and indirect impacts from an event for a multi-system network, including interconnected infrastructure and end users. We perform a case study of New Zealand’s second largest city, Christchurch, investigating electricity, water supply, and wastewater networks following a range of coastal flooding events and climate change scenarios. For a 10-year average recurrence interval event given no sea-level rise, there is a 216% increase from directly impacted end users to the total number of end users that have lost at least one utility. For the same scenario, this metric is 71%, 129%, and 131% for end users who have lost electricity, water, and wastewater, respectively. The results show a larger estimate of impact on residents and a more geospatially-varied loss of service. This methodology provides insight for utility operators, emergency response, and communities on node criticality, areas of impact, and resource requirements after an event occurs.

基础设施韧性级联失效气候变化城市风险管理