用高强度钢筋加固的高强度混凝土框架结构的地震脆性分析

Juan Liu, Jianwei Zhang, Zuozhou Zhao
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摘要

摘要 为研究柱中使用高强度钢筋对框架结构抗震能力和抗震弹性的影响,基于增量动力分析(IDA),利用 11 次地面运动记录,对三个 8 层钢筋混凝土(RC)框架结构进行了地震脆性评估。主要参数是框架柱的纵向钢筋配置,其中第一个结构的柱子采用 HRB 600 级钢筋,第二个结构采用等面积超高强度(UHS)钢筋(即屈服强度约为 1425 兆帕),第三个结构采用等强度 UHS 钢筋。我们开发了一个 RC 框架结构的数值模型,然后利用之前的实验结果进行了验证。根据两个典型的工程需求参数(EDP),即最大层间漂移和残余层间漂移,计算了各种性能极限状态下的超限概率。结果表明,在框架柱中使用 UHS 纵向钢筋代替 HRB 600 级钢筋会降低结构的消能能力,从而不可避免地导致框架的最大层间响应增大。然而,在基于残余层间漂移的可修复极限状态下,观察到 UHS 增强框架的超限概率要低得多,这表明 UHS 增强 RC 框架具有更高的抗震能力。此外,与等面积替代相比,等强度替代是一种更为理想的设计方法,它可以使用更少的 UHS 钢筋来实现相当的修复能力和更小的最大层间漂移增加。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Seismic fragility analysis of high‐strength concrete frame structures reinforced with high‐strength steel bars
SummaryTo investigate the influence of using high‐strength steel bars in columns on the seismic resistance capacity and seismic resilience of frame structures, seismic fragility evaluation of three 8‐story reinforced concrete (RC) frame structures was conducted based on the incremental dynamic analysis (IDA) using 11 ground motion records. The main parameter is the longitudinal reinforcement configuration in the frame columns, where the first structure is reinforced with HRB 600 grade steel bars in the columns, the second structure is replaced with equal area ultra‐high‐strength (UHS) steel bars (i.e., with a yield strength of approximately 1425 MPa), and the third structure is replaced with equal strength UHS steel bars. A numerical model of the RC frame structure was developed and then validated using previous experimental results. The exceeding probabilities at various performance limit states were calculated based on two typical engineering demand parameters (EDPs) of maximum interstory drift and residual interstory drift. The results showed that using UHS longitudinal steel bars instead of HRB 600 grade steel bars in frame columns could reduce the energy dissipation capacity of the structure, inevitably leading to an increase in the maximum interstory response of the frame. However, much lower exceedance probability was observed in the UHS‐enhanced frame under the repair available limit state based on the residual interstory drift, indicating that the UHS‐enhanced RC frame had higher seismic resilience. In addition, compared to equal area substitution, equal strength substitution is a more ideal design method that can use fewer UHS steel bars to achieve comparable reparability and a smaller increase in maximum interstory drift.
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