Impact of failure mode uncertainty on seismic fragility and collapse risk of buildings

IF 4.3 2区 工程技术 Q1 ENGINEERING, CIVIL
Eyitayo A. Opabola, Abbie Liel, Kenneth Elwood
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Abstract

Laboratory tests on nominally identical reinforced concrete (RC) components have demonstrated the existence of failure mode variability and its significant impact on the strength and deformation capacity of RC components. In comparison with record-to-record and modeling uncertainties, the impact of failure mode uncertainty on the seismic fragility of RC structural systems has received less attention. This study presents a methodology for propagating failure mode variability in the probabilistic seismic assessment of RC structural systems. In the proposed methodology, strength hierarchy calculations are used to identify the structural system's susceptibility to failure mode variability. Subsequently, a number of segregate models corresponding to the number of failure mode combinations are developed. Nonlinear response history analyses of the segregates are used to quantify each segregate's seismic fragility and risk. Finally, the total probability theorem is used to derive the combined seismic fragility of the structure. The proposed methodology is demonstrated using an older-type (pre-1970s) four-story RC frame building archetype with ground floor columns susceptible to failure mode switch between flexure- and flexure-shear mechanisms. The results show that the seismic fragility and collapse risk of the RC buildings with failure mode variability significantly changes when failure mode variability is propagated. In the example, accounting for component-level failure mode variability can shift the median collapse fragility by more than 20%. Furthermore, the collapse risk (i.e., probability of collapse in 50 years) of the archetype changed by at least 30%. Similar changes may be observed in other types of structures with significant failure mode uncertainty, not limited to RC structures.

Abstract Image

失效模式不确定性对建筑物地震脆性和倒塌风险的影响
对名义上完全相同的钢筋混凝土(RC)构件进行的实验室测试表明了破坏模式变异性的存在及其对 RC 构件强度和变形能力的重大影响。与记录到记录和建模不确定性相比,破坏模式不确定性对 RC 结构系统地震脆性的影响受到的关注较少。本研究提出了一种在 RC 结构系统概率抗震评估中传播破坏模式变异性的方法。在建议的方法中,强度分级计算用于确定结构系统对破坏模式变异的易感性。随后,开发出与失效模式组合数量相对应的多个分隔模型。对分隔体进行非线性响应历史分析,以量化每个分隔体的地震脆性和风险。最后,利用总概率定理得出结构的综合地震脆性。所提出的方法通过一个老式(1970 年代以前)四层 RC 框架结构建筑原型进行了演示,该建筑的底层柱子易受挠曲和挠剪机制之间破坏模式切换的影响。结果表明,当失效模式变异传播时,具有失效模式变异的 RC 建筑的地震脆性和倒塌风险会发生显著变化。在示例中,考虑构件级失效模式变异可使倒塌脆性中值偏移 20% 以上。此外,原型的倒塌风险(即 50 年内倒塌的概率)至少改变了 30%。类似的变化也可能出现在具有重大失效模式不确定性的其他类型结构中,而不仅限于 RC 结构。
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来源期刊
Earthquake Engineering & Structural Dynamics
Earthquake Engineering & Structural Dynamics 工程技术-工程:地质
CiteScore
7.20
自引率
13.30%
发文量
180
审稿时长
4.8 months
期刊介绍: Earthquake Engineering and Structural Dynamics provides a forum for the publication of papers on several aspects of engineering related to earthquakes. The problems in this field, and their solutions, are international in character and require knowledge of several traditional disciplines; the Journal will reflect this. Papers that may be relevant but do not emphasize earthquake engineering and related structural dynamics are not suitable for the Journal. Relevant topics include the following: ground motions for analysis and design geotechnical earthquake engineering probabilistic and deterministic methods of dynamic analysis experimental behaviour of structures seismic protective systems system identification risk assessment seismic code requirements methods for earthquake-resistant design and retrofit of structures.
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