铁路自定心桥墩抗震性能试验与数值研究

IF 1.4 4区工程技术 Q3 ENGINEERING, CIVIL

Earthquakes and Structures Pub Date : 2021-08-01 DOI:10.12989/EAS.2021.21.2.173

X. Xia, Suiwen Wu, X. Wei, Chiyu Jiao, Xingchong Chen

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引用次数: 7

摘要

本文主要对自定心铁路桥墩的隔震机理和抗震性能进行了试验和数值研究。首先，设计并构建了1/25比例的典型铁路自定心桥墩模型，该模型由重力桥墩、扩展基础和基座组成。重力墩与扩展基础刚性连接，然后直接位于桩帽顶部，以便在强震时墩的隆起。在恒轴向荷载和循环侧向荷载作用下对模型进行了拟静力试验，以表征模型的抗震性能。研究发现，当上拔达到一定程度时，侧力、桥墩底部弯矩和桥墩底部受压区宽度基本保持不变。滞回曲线呈反“Z”形，回环窄，自定心效果好，但能量耗散较差。这意味着这类桥墩的侧向力-位移关系可以简化为弹塑性曲线，并应与附加耗能装置一起使用。根据测试结果，在OpenSees平台上提出并开发了一个双弹簧模型来表示测试模型，并利用测试负载历史对其进行了分析。结果表明，双弹簧模型能较好地模拟拟静力试验。因此，该建模技术可用于分析这类桥墩的地震反应。

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Experimental and numerical study on seismic behavior of a self-centering railway bridge pier

This study mainly focuses on experimental and numerical investigation of the isolation mechanism and seismic performance of a self-centering railway bridge pier. To begin, a 1/25 scale typical self-centering railway pier model was designed and constructed, which consisted of a gravity pier, a spread foundation and a pedestal. The gravity pier was rigidly connected to the spread foundation, which was then directly seated at the top of the pile cap to allow the uplift of the pier during strong earthquakes. The model was tested in a pseudo-static manner under constant axial load and cyclic lateral load to characterize its seismic performance. It was found that the lateral load, the bending moment at the pier bottom, and the width of compression zone at the bottom of pier remained essentially constant when the uplift reached a certain extent. The hysteretic curves were in inverse 'Z' shape with narrow loops indicating good self-centering effect but poor energy dissipation. This means that the lateral force-displacement relationship of this type of piers can be simplified as an elasto-plastic curve and they should be used along with additional energy-dissipation devices. Upon the test results, a two-spring model was proposed and developed in the OpenSees platform to represent the test model, which was analyzed using the test load history. The results indicate that the two-spring model can simulate the pseudo-static test with high precision. This modeling technique hence can be employed to analyze seismic response of this type of bridge piers.

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来源期刊

Earthquakes and Structures ENGINEERING, CIVIL-ENGINEERING, GEOLOGICAL

CiteScore

2.90

自引率

20.00%

发文量

审稿时长

>12 weeks

期刊介绍： The Earthquakes and Structures, An International Journal, focuses on the effects of earthquakes on civil engineering structures. The journal will serve as a powerful repository of technical information and will provide a highimpact publication platform for the global community of researchers in the traditional, as well as emerging, subdisciplines of the broader earthquake engineering field. Specifically, some of the major topics covered by the Journal include: .. characterization of strong ground motions, .. quantification of earthquake demand and structural capacity, .. design of earthquake resistant structures and foundations, .. experimental and computational methods, .. seismic regulations and building codes, .. seismic hazard assessment, .. seismic risk mitigation, .. site effects and soil-structure interaction, .. assessment, repair and strengthening of existing structures, including historic structures and monuments, and .. emerging technologies including passive control technologies, structural monitoring systems, and cyberinfrastructure tools for seismic data management, experimental applications, early warning and response