Space–time finite element method with domain reduction techniques for dynamic soil–structure interaction problems

IF 3.4 Q1 ENGINEERING, MECHANICAL 国际机械系统动力学学报(英文) Pub Date : 2024-06-04 DOI:10.1002/msd2.12106
Vikas Sharma, Shion Shimizu, Kazunori Fujisawa
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Abstract

Design of earth structures, such as dams, tunnels, and embankments, against the vibrational loading caused by high-speed trains, road traffic, underground explosions, and, more importantly, earthquake motion, demands solutions of the dynamic soil–structure Interaction (SSI) problem. This paper presents a velocity-based space–time finite element procedure, v-ST/finite element method (FEM), to solve dynamic SSI problems. The main goal of this study is to present the computation details of implementing viscous boundary conditions of Lysmer–Kuhlemeyer to truncate the unbounded soil domain. Furthermore, additional time-dependent boundary conditions, in terms of the free-field response, are included to facilitate energy flow from the far field to the computation domain at the vertical truncated boundaries. In the FEM, seismic input motion is applied to an effective nodal force vector, which can be obtained explicitly in the numerical simulations. Finally, the response of a concrete gravity dam resting on an elastic half-space to the horizontal component of earthquake motion is computed and successfully compared with the results of semidiscrete FEM using the Newmark- method.

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采用域缩减技术的时空有限元法解决土壤与结构的动态相互作用问题
设计大坝、隧道和堤坝等土体结构时,需要解决由高速列车、道路交通、地下爆炸以及更重要的地震运动引起的振动荷载问题。本文提出了一种基于速度的时空有限元程序--v-ST/有限元法(FEM),用于解决动态 SSI 问题。本研究的主要目标是介绍实施 Lysmer-Kuhlemeyer 粘边界条件以截断无边界土壤域的计算细节。此外,在自由场响应方面还包含了额外的随时间变化的边界条件,以促进能量从远场流向垂直截断边界的计算域。在有限元模型中,地震输入运动被应用于有效的节点力向量,这可以在数值模拟中明确获得。最后,计算了位于弹性半空间上的混凝土重力坝对地震运动水平分量的响应,并成功地与使用纽马克方法的半离散有限元的结果进行了比较。
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