Dynamic centrifuge modeling on the superstructure–pile system considering pile–pile cap connections in dry sandy soils

IF 4.2 2区 工程技术 Q1 ENGINEERING, GEOLOGICAL Soil Dynamics and Earthquake Engineering Pub Date : 2024-09-16 DOI:10.1016/j.soildyn.2024.108979
Gang Zheng , Wenbin Zhang , Davide Forcellini , Haizuo Zhou , Jihui Zhao
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Abstract

In conventional designs, the pile and pile cap are typically considered rigid connections. However, this type of connection experiences a concentrated force during earthquakes, leading to frequent damage at the pile heads. To mitigate pile head damage, semirigid pile‒pile cap connections are proposed. Centrifuge shaking table tests were conducted to investigate the seismic response of the superstructure‒pile foundation system. Two layers of Toyoura sand, including a moderately dense upper layer and a denser bottom layer, were used as the foundation soil. The superstructure was simplified as lumped masses and columns with two different heights and periods. The foundation consisted of a 3 × 3 group of piles. Rigid and semirigid pile‒pile cap connections were evaluated. The experiments investigated the effect of connection type on the distribution of bending moments in the piles and analyzed the acceleration and displacement responses of the superstructure under different pile‒pile cap connections. According to the results, semirigid connections reduced the peak bending moment at the pile head by 50–70 %, especially for low-rise superstructure cases. The influence depth of the connection type on the pile bending moment reaches approximately 10 times the pile diameter. For low-rise superstructure cases, semirigid connections slightly reduced the natural frequency of the superstructure, leading to a decrease in the superstructure acceleration during earthquakes with a short dominant period. The semi-rigid connections reduce the rotation of foundations but promote the translational displacement of foundations. For the mid-rise superstructure cases, semirigid connections reduce the translational displacement and increase the rotational displacement of the foundation. These experiments provide insights into the seismic performance of superstructure‒pile foundation systems with different pile‒pile cap connections and can serve as a reference for seismic design in similar engineering practices.

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考虑到干砂土中的桩帽连接,对上部结构-桩系统进行动态离心建模
在传统设计中,桩和桩帽通常被视为刚性连接。然而,这种连接方式在地震中会受到集中力的作用,导致桩头经常损坏。为减轻桩头损坏,建议采用半刚性桩-桩帽连接。为研究上部结构-桩基系统的地震响应,进行了离心振动台试验。地基土采用两层丰浦砂,包括密度适中的上层和密度较大的下层。上部结构简化为具有两种不同高度和周期的块状质量和柱。地基由 3 × 3 组桩组成。对刚性和半刚性桩-桩帽连接进行了评估。实验研究了连接类型对桩内弯矩分布的影响,并分析了不同桩帽连接下上部结构的加速度和位移响应。结果表明,半刚性连接可将桩头处的峰值弯矩降低 50-70%,尤其是在低层上部结构的情况下。连接类型对桩弯矩的影响深度约为桩直径的 10 倍。对于低层上部结构,半刚性连接可略微降低上部结构的固有频率,从而降低主周期较短的地震中上部结构的加速度。半刚性连接减少了地基的旋转,但促进了地基的平移。对于中层上部结构,半刚性连接减少了地基的平移位移,增加了地基的旋转位移。这些实验为采用不同桩帽连接的上部结构-桩基础系统的抗震性能提供了启示,可为类似工程实践中的抗震设计提供参考。
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来源期刊
Soil Dynamics and Earthquake Engineering
Soil Dynamics and Earthquake Engineering 工程技术-地球科学综合
CiteScore
7.50
自引率
15.00%
发文量
446
审稿时长
8 months
期刊介绍: The journal aims to encourage and enhance the role of mechanics and other disciplines as they relate to earthquake engineering by providing opportunities for the publication of the work of applied mathematicians, engineers and other applied scientists involved in solving problems closely related to the field of earthquake engineering and geotechnical earthquake engineering. Emphasis is placed on new concepts and techniques, but case histories will also be published if they enhance the presentation and understanding of new technical concepts.
期刊最新文献
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