Seismic performance and resilience of composite damping self-centering braced frame structures

IF 6.2 3区 综合性期刊 Q1 Multidisciplinary Fundamental Research Pub Date : 2024-05-01 DOI:10.1016/j.fmre.2022.05.009
Longhe Xu , Xingsi Xie , Zhongxian Li
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Abstract

A magnetorheological self-centering brace (MR–SCB) has been proposed to improve the energy dissipation capability of the brace. In this paper, a 15-story MR–SCB braced frame is numerically analyzed to examine its seismic performance and resilience. The MR–SCB provides higher lateral stiffness than the buckling restrained brace and greater energy dissipation capability than the existing self-centering brace. The brace also exhibits a reliable recentering capacity. Under rare earthquakes, the maximum average residual deformation ratio of the structure is less than the 0.5% limit. Under mega earthquakes, the maximum average interstory drift ratio of the structure does not exceed the 2.0% elastoplastic limit, and its maximum average floor acceleration ratio is 1.57. The effects of mainshock and aftershock on the structural behavior are also investigated. The interstory drift and residual deformation of the structure increase with the increase of the intensity of the aftershock. Under aftershocks with the same intensity as the mainshocks, the maximum increment of the residual deformation ratio of the structure is 81.8%, and the average interstory drift ratios of the 12th, 7th, and 3rd stories of the structure are increased by 13.4%, 9.2% and 7.5%, respectively. The strong aftershock may significantly cause increased damage to the structure, and increase its collapse risk and residual deformation.

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复合阻尼自定心支撑框架结构的抗震性能和回弹性能
有人提出了一种磁流变自定心支撑(MR-SCB),以提高支撑的消能能力。本文对一个 15 层的磁流变自定心支撑框架进行了数值分析,以研究其抗震性能和弹性。与屈曲约束支撑相比,MR-SCB 具有更高的侧向刚度,与现有的自定心支撑相比,MR-SCB 具有更强的能量耗散能力。该支撑还具有可靠的重新定心能力。在罕见地震下,结构的最大平均残余变形率小于 0.5%。在特大地震下,结构的最大平均层间漂移比不超过 2.0% 的弹塑性极限,最大平均楼层加速度比为 1.57。此外,还研究了主震和余震对结构行为的影响。结构的层间漂移和残余变形随着余震强度的增加而增大。在与主震强度相同的余震作用下,结构残余变形率的最大增量为 81.8%,结构的第 12 层、第 7 层和第 3 层的平均层间漂移率分别增加了 13.4%、9.2% 和 7.5%。强余震可能会大大增加对结构的破坏,增加其倒塌风险和残余变形。
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来源期刊
Fundamental Research
Fundamental Research Multidisciplinary-Multidisciplinary
CiteScore
4.00
自引率
1.60%
发文量
294
审稿时长
79 days
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