气候变化下结构的风险设计和安全评估:对美国实践的回顾和前进道路

IF 2.6 3区 工程技术 Q2 ENGINEERING, CIVIL
Michel Ghosn, Bruce R. Ellingwood
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引用次数: 0

摘要

摘要桥梁、建筑物和其他基础设施的设计标准规定了气候灾害(如温度、雪、风、洪水)的设计荷载,其依据是考虑地区差异的地图或表格中的重现期。这些设计荷载是在假设过去代表未来的前提下,从历史灾害数据的统计分析中开发出来的。气候变化可能会影响环境危害的频率和强度,这取决于区域差异,提出了按照当前规范设计的结构在其未来使用寿命内是否符合最低安全标准的问题。本文批判性地评估了与使用历史危害数据进行未来设计相关的问题。它回顾了统一可靠性的基本原则,现代设计规范将其作为确保最低安全水平的基础,描述了危险返回期、结构可靠性、风险和结构使用寿命内预期的最大载荷之间的关系。涉及风对结构影响的简单示例演示了如何校准与气候有关的极端事件的结构设计危害图,以满足当前规范中隐含的最低安全标准。本文还介绍了在设计新结构和评估现有设施安全性时考虑气候变化的一种可能的实用方法。关键词:桥梁、建筑、气候变化、危害、概率、可靠性、结构工程、结构安全、风致谢感谢ASCE/SEI结构系统生命周期性能、安全性、可靠性和风险技术委员会第二任务组(TG2)组建的项目组进行了富有成果的技术讨论。作者还感谢Naresh Devineni教授的贡献,他协助分析了风数据集。披露声明作者未报告潜在的利益冲突。注1正常运行或环境影响引起的负荷随时间变化,如果不提供参考时间框架,讨论其概率概率分布或统计参数是没有意义的。按照习惯用法,本文将此时间范围称为使用寿命;这并不意味着该结构是为这段时间设计或保证的。本文所介绍的工作是由作者参与的ASCE/SEI关于气候变化对结构和基础设施系统生命周期性能、安全性、可靠性和风险的影响的特别项目所推动的。该项目由ASCE/SEI结构系统生命周期性能、安全性、可靠性和风险技术委员会组织。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Risk-informed design and safety assessment of structures in a changing climate: a review of U.S. practice and a path forward
AbstractStandards for the design of bridges, buildings and other infrastructure specify design loads for climatic hazards such as temperature, snow, wind, and floods based on return periods presented in maps or tables that account for regional differences. These design loads were developed from statistical analyses of historical hazard data under the assumption that the past is representative of the future. Climate change may affect the frequencies and intensities of environmental hazards which, depending on regional variations, raises questions as to whether structures designed to current specifications will meet minimum safety standards over their future service lives. This paper critically appraises issues related to using historical hazard data for future designs. It reviews basic principles of uniform reliability, that modern design codes use as the basis for ensuring minimum levels of safety, describing the relationship between hazard return periods, structural reliability, risk and the maximum loads expected within a structure’s service life. Simple examples involving wind effects on structures demonstrate how to calibrate structural design hazard maps for climate-related extreme events to meet the minimum standards of safety implied in current specifications. The paper also introduces a possible practical approach to account for climate change when designing new structures and assessing the safety of existing facilities.Keywords: BridgesBuildingsclimate changehazardsprobabilityreliabilitystructural engineeringstructural safetywind AcknowledgmentsThe authors are grateful for the fruitful technical discussions by the project team assembled by Task Group 2 (TG2) of the ASCE/SEI Technical Council on Life-Cycle Performance, Safety, Reliability and Risk of Structural Systems. The authors also acknowledge the contributions of Prof. Naresh Devineni who assisted with the analysis of the wind data set.Disclosure statementNo potential conflict of interest was reported by the author(s).Notes1 Loads due to normal service or environmental effects vary in time, and it is not meaningful to discuss their probabilistic probability distributions or statistical parameter without providing a time frame of reference. Following customary usage, this paper refers to this time frame as a service life; this does not imply that the structure is designed or warranted for this period of time.Additional informationFundingThe work presented in this paper was motivated by an ASCE/SEI Special Project on the Effect of Climate Change on Life-Cycle Performance, Safety, Reliability and Risk of Structures and Infrastructure Systems that the authors participated in. The project was organized by the ASCE/SEI Technical Council on Life-Cycle Performance, Safety, Reliability and Risk of Structural Systems.
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来源期刊
Structure and Infrastructure Engineering
Structure and Infrastructure Engineering 工程技术-工程:机械
CiteScore
9.50
自引率
8.10%
发文量
131
审稿时长
5.3 months
期刊介绍: Structure and Infrastructure Engineering - Maintenance, Management, Life-Cycle Design and Performance is an international Journal dedicated to recent advances in maintenance, management and life-cycle performance of a wide range of infrastructures, such as: buildings, bridges, dams, railways, underground constructions, offshore platforms, pipelines, naval vessels, ocean structures, nuclear power plants, airplanes and other types of structures including aerospace and automotive structures. The Journal presents research and developments on the most advanced technologies for analyzing, predicting and optimizing infrastructure performance. The main gaps to be filled are those between researchers and practitioners in maintenance, management and life-cycle performance of infrastructure systems, and those between professionals working on different types of infrastructures. To this end, the journal will provide a forum for a broad blend of scientific, technical and practical papers. The journal is endorsed by the International Association for Life-Cycle Civil Engineering ( IALCCE) and the International Association for Bridge Maintenance and Safety ( IABMAS).
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