Multivariable fragility surfaces for earthquake-induced damage assessment of buildings integrating structural features

IF 3.8 2区 工程技术 Q2 ENGINEERING, GEOLOGICAL
Mahshad Jamdar, Kiarash M. Dolatshahi, Omid Yazdanpanah
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Abstract

This study introduces three types of multivariable fragility surfaces, integrating effective structural features to improve damage assessment. The incorporation of additional information such as building occupancies, structural responses, and underlying soil types enhances the accuracy of conventional fragility curve predictions. Additionally, three modification factors are proposed to further refine conventional fragility curves and provide more precise predictions. The multivariable fragility surfaces are developed for eccentric brace frames modeled in Opensees software which is validated by experimental results and subjected to incremental dynamic analysis with 44 far-field ground motions. The influence of soil flexibilities on structural responses is incorporated through Winkler springs, representing soil-structure interaction. Diverse occupancies, such as hospitals, museums, and residential structures, are assessed using various peak floor acceleration thresholds and story drift ratios, employing multidimensional limit state functions to consider both structural and nonstructural losses. To account for uncertainties in structural responses and a single intensity measurement, a damage-sensitive feature derived from roof acceleration response, obtained through signal processing and system identification techniques, is introduced. The results for the proposed multivariable fragility surfaces indicate that the spectral acceleration corresponding to a 50% probability of exceedance could vary between 10.2 and 89%, in comparison to the corresponding conventional fragility curves. Finally, to evaluate the application of the enhanced fragility surface and modification factors, two instrumented EBF buildings, a 4-story EBF building, and a real 5-story hospital EBF, are selected as case studies. With additional details on soil types, occupancies, and structural responses, the process of employing modification factors resulting in enhanced fragility curves is demonstrated.

Abstract Image

Abstract Image

综合结构特征的建筑物地震诱发损伤评估多变量脆度面
本研究介绍了三种类型的多变量脆性面,整合了有效的结构特征,以改进破坏评估。将建筑占用率、结构响应和底层土壤类型等附加信息纳入其中,可提高传统脆性曲线预测的准确性。此外,还提出了三个修正系数,以进一步完善传统脆性曲线并提供更精确的预测。多变量脆性曲面是针对在 Opensees 软件中建模的偏心支撑框架开发的,该软件通过实验结果进行了验证,并对 44 种远场地面运动进行了增量动态分析。土壤挠性对结构响应的影响是通过温克勒弹簧来体现的,它代表了土壤与结构之间的相互作用。使用不同的楼层峰值加速度阈值和楼层漂移率对医院、博物馆和住宅等不同的建筑进行了评估,并采用多维极限状态函数来考虑结构和非结构损失。为了考虑结构响应和单一强度测量的不确定性,引入了通过信号处理和系统识别技术从屋顶加速度响应中获得的损伤敏感特征。所提出的多变量脆性面的结果表明,与相应的传统脆性曲线相比,50% 超限概率对应的频谱加速度可在 10.2% 到 89% 之间变化。最后,为了评估增强脆性面和修正系数的应用情况,我们选择了两座带仪器的建筑物作为案例研究,一座是 4 层楼高的 EBF 建筑,另一座是真实的 5 层楼高的医院 EBF 建筑。通过对土壤类型、使用情况和结构响应的更多细节,展示了使用修正系数生成增强脆性曲线的过程。
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来源期刊
Bulletin of Earthquake Engineering
Bulletin of Earthquake Engineering 工程技术-地球科学综合
CiteScore
8.90
自引率
19.60%
发文量
263
审稿时长
7.5 months
期刊介绍: Bulletin of Earthquake Engineering presents original, peer-reviewed papers on research related to the broad spectrum of earthquake engineering. The journal offers a forum for presentation and discussion of such matters as European damaging earthquakes, new developments in earthquake regulations, and national policies applied after major seismic events, including strengthening of existing buildings. Coverage includes seismic hazard studies and methods for mitigation of risk; earthquake source mechanism and strong motion characterization and their use for engineering applications; geological and geotechnical site conditions under earthquake excitations; cyclic behavior of soils; analysis and design of earth structures and foundations under seismic conditions; zonation and microzonation methodologies; earthquake scenarios and vulnerability assessments; earthquake codes and improvements, and much more. This is the Official Publication of the European Association for Earthquake Engineering.
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