Enhancing the seismic resilience of structures using a two-stage friction self-centering damper (TFSD)

IF 7.4 2区工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY

Journal of building engineering Pub Date : 2025-10-06 DOI:10.1016/j.jobe.2025.114290

Rui Liu , Jianyang Xue , Zheng Luo , Chengyu Bai

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Abstract

This study investigates a two-stage friction self-centering damper (TFSD), comprising a friction damper (FD) and a self-centering friction damper (SCFD) connected in series. A predefined gap length for frictional sliding in the FD allows energy dissipation firstly, then the SCFD is activated when the deformation exceeding the gap to provide both energy dissipation and self-centering. Cyclic loading tests and numerical modeling were conducted on a specimen of TFSD. A prototype multi-story building structure was used to study the seismic responses influenced by TFSD design parameters, including the ratio of the first-stage sliding force to second-stage sliding force (α) and the gap ratio (γ), which is the ratio of lateral floor displacement corresponding to the gap length to the story height. The advantages of the TFSD braced frame (TFSDF) in controlling structural responses and resisting collapse were evaluated through comparison with the frame braced by buckling-restrained braces (BRBF) and SCFD braces (SCFDF). Experimental results indicate that the TFSD exhibits full hysteresis loops under low deformations, transitioning to flag-shaped loops after the inputs beyond the gap length. The numerical model of TFSD shows good agreement with the experimental results. The parametric analysis on the multi-story case shows that the structure achieves minimal peak inter-story drift ratio (θ_P) and peak floor acceleration (A_P) when α ranges from 0.3 to 0.7, and the residual inter-story drift is governed by γ. Compared to the SCFDF, the TFSDF shows lower peak responses under Design Based Earthquake (DBE) and Maximum Considered Earthquake (MCE) shaking levels, with θ_P and A_P reduced by up to 26 % under MCE shaking level. Moreover, the fragility analysis demonstrates that the TFSDF consistently outperforms both BRBF and SCFDF in collapse resistance across all damage states.

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两级摩擦自定心阻尼器增强结构抗震性能

本文研究了一种两级摩擦自定心阻尼器（TFSD），它由一个摩擦阻尼器（FD）和一个自定心摩擦阻尼器（SCFD）串联组成。FD中预定义的摩擦滑动间隙长度首先允许能量耗散，然后当变形超过间隙时激活SCFD，以提供能量耗散和自定心。对TFSD试件进行了循环加载试验和数值模拟。以某多层原型建筑结构为研究对象，研究了TFSD设计参数对结构地震反应的影响，包括第一级滑动力与第二级滑动力之比（α）和间隙比（γ），即间隙长度对应的楼层侧向位移与层高之比。通过与抗屈曲支撑框架（BRBF）和SCFD支撑框架（SCFDF）的对比，评价了TFSD支撑框架（TFSDF）在控制结构响应和抗倒塌方面的优势。实验结果表明，在低变形条件下，TFSD呈现出完整的磁滞回线，在输入超过间隙长度后转变为旗形回线。数值模型与实验结果吻合较好。多层结构的参数分析表明，当α在0.3 ~ 0.7范围内时，结构达到最小的峰值层间位移比θP和峰值层间加速度AP，剩余层间位移受γ控制。与SCFDF相比，TFSDF在基于设计的地震（DBE）和最大考虑地震（MCE）震动水平下显示出更低的峰值响应，θP和AP在MCE震动水平下减少了26%。此外，脆弱性分析表明，在所有损伤状态下，TFSDF的抗倒塌性能始终优于BRBF和SCFDF。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of building engineering Engineering-Civil and Structural Engineering

CiteScore

10.00

自引率

12.50%

发文量

1901

审稿时长

35 days

期刊介绍： The Journal of Building Engineering is an interdisciplinary journal that covers all aspects of science and technology concerned with the whole life cycle of the built environment; from the design phase through to construction, operation, performance, maintenance and its deterioration.