Seismic performance study of plastic hinge region using PVA-ECC composite bridge piers

IF 5.6 1区工程技术 Q1 ENGINEERING, CIVIL Engineering Structures Pub Date : 2024-11-04 DOI:10.1016/j.engstruct.2024.119261

Shenwei Chen , Shengqiang Ma , Wenjie Ma

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Abstract

This study explores the use of high tensile ductility engineered cementitious composites (ECC) to replace the plastic hinge region in conventional reinforced concrete (RC) pier, aiming to enhance seismic performance. Experiments and numerical simulations were performed on a traditional reinforced concrete pier and three composite piers with different replacement heights of ECC in the plastic hinge area. The findings demonstrated that the use of ECC led to a substantial enhancement in the piers' ultimate displacement, displacement ductility factor, and energy dissipation capacity, with improvements of more than 20.3 %, 17.1 %, and 80 % correspondingly. Increasing the replacement height from 300 mm to 400 mm boosted the displacement ductility coefficient by 10 %. Numerical analyses corroborated these findings, indicating a decline in seismic performance with higher axial pressure ratios. At an axial pressure ratio of 0.2, ductility increased by over 1 % for every 100 mm increase in ECC height up to 400 mm, beyond which the increase was less than 1 %. Thus, ECC in the plastic hinge improves seismic performance, with greater enhancement discovered at higher replacement heights within a certain range.

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使用 PVA-ECC 复合材料桥墩的塑性铰区抗震性能研究

本研究探讨了使用高拉伸延性工程水泥基复合材料（ECC）替代传统钢筋混凝土（RC）桥墩的塑性铰区，以提高抗震性能。研究人员对一个传统钢筋混凝土桥墩和三个在塑性铰区采用不同替代高度 ECC 的复合桥墩进行了实验和数值模拟。研究结果表明，使用 ECC 后，桥墩的极限位移、位移延性系数和耗能能力都得到了大幅提高，分别提高了 20.3%、17.1% 和 80%。置换高度从 300 毫米增加到 400 毫米后，位移延性系数提高了 10%。数值分析证实了这些发现，表明轴压比越高，抗震性能越差。在轴压比为 0.2 的情况下，ECC 高度每增加 100 毫米，延性就会增加 1%以上，最高可达 400 毫米，超过这一数值后，延性的增加就不到 1%了。因此，塑性铰链中的 ECC 可提高抗震性能，在一定范围内，更换高度越高，提高幅度越大。

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来源期刊

Engineering Structures 工程技术-工程：土木

CiteScore

10.20

自引率

14.50%

发文量

1385

审稿时长

67 days

期刊介绍： Engineering Structures provides a forum for a broad blend of scientific and technical papers to reflect the evolving needs of the structural engineering and structural mechanics communities. Particularly welcome are contributions dealing with applications of structural engineering and mechanics principles in all areas of technology. The journal aspires to a broad and integrated coverage of the effects of dynamic loadings and of the modelling techniques whereby the structural response to these loadings may be computed. The scope of Engineering Structures encompasses, but is not restricted to, the following areas: infrastructure engineering; earthquake engineering; structure-fluid-soil interaction; wind engineering; fire engineering; blast engineering; structural reliability/stability; life assessment/integrity; structural health monitoring; multi-hazard engineering; structural dynamics; optimization; expert systems; experimental modelling; performance-based design; multiscale analysis; value engineering. Topics of interest include: tall buildings; innovative structures; environmentally responsive structures; bridges; stadiums; commercial and public buildings; transmission towers; television and telecommunication masts; foldable structures; cooling towers; plates and shells; suspension structures; protective structures; smart structures; nuclear reactors; dams; pressure vessels; pipelines; tunnels. Engineering Structures also publishes review articles, short communications and discussions, book reviews, and a diary on international events related to any aspect of structural engineering.