Large post-liquefaction deformation of sand: Mechanisms and modeling considering water absorption in shearing and seismic wave conditions

IF 8.2 1区 工程技术 Q1 ENGINEERING, CIVIL
Jian-Min Zhang, Rui Wang
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引用次数: 0

Abstract

Large deformation of sand due to soil liquefaction is a major cause for seismic damage. In this study, the mechanisms and modeling of large post-liquefaction deformation of sand considering the significant influence of water absorption in shearing and seismic wave conditions. Assessment of case histories from past earthquakes and review of existing studies highlight the importance of the two factors. Based on the micro and macro scale mechanisms for post-liquefaction shear deformation, the mechanism for water absorption in shearing after initial liquefaction is revealed. This is aided by novel designed constant water-absorption-rate shear tests. Water absorption in shearing can be classified into three types, including partial water absorption, complete water absorption, and compulsory water absorption. Under the influence of water absorption in shearing, even a strongly dilative sand under naturally drained conditions could experience instability and large shear deformation. The mechanism for amplification of post-liquefaction deformation under surface wave load is also explained via element tests and theoretical analysis. This shows that surface wave–shear wave coupling can induce asymmetrical force and resistance in sand, resulting in asymmetrical accumulation of deformation, which is amplified by liquefaction. A constitutive model, referred to as CycLiq, is formulated to capture the large deformation of sand considering water absorption in shearing and seismic wave conditions, along with its numerical implementation algorithm. The model is comprehensively calibrated based on various types of element tests and validated against centrifuge shaking table tests in the liquefaction experiments and analysis projects (LEAP). The model, along with various numerical analysis methods, is adopted in the successful simulation of water absorption in shearing and Rayleigh wave-shear wave coupling induced large liquefaction deformation. Furthermore, the model is applied to high-performance simulation for large-scale soil-structure interaction in liquefiable ground, including underground structures, dams, quay walls, and offshore wind turbines.

砂土的大液化后变形:考虑剪切和地震波条件下吸水的机理和建模
土壤液化引起的砂土大变形是造成地震破坏的主要原因。在本研究中,考虑到剪切和地震波条件下吸水的重要影响,研究了砂土液化后大变形的机理和模型。对以往地震案例的评估和对现有研究的回顾突出了这两个因素的重要性。基于微观和宏观尺度的液化后剪切变形机制,揭示了初始液化后剪切吸水的机制。新设计的恒定吸水率剪切试验对此有所帮助。剪切吸水可分为三种类型,包括部分吸水、完全吸水和强制吸水。在剪切吸水的影响下,即使是自然排水条件下的强扩张性砂也会出现不稳定和较大的剪切变形。此外,还通过元素试验和理论分析解释了在表面波荷载作用下地震后变形的放大机制。这表明,面波-剪切波耦合可在砂中引起不对称的力和阻力,导致不对称的变形累积,并通过液化得到放大。考虑到剪切波和地震波条件下的吸水性,建立了一个称为 CycLiq 的构成模型,以捕捉砂的大变形,并制定了其数值实现算法。在液化实验和分析项目(LEAP)中,根据各种类型的元素试验对模型进行了全面校准,并通过离心振动台试验进行了验证。采用该模型和各种数值分析方法,成功模拟了剪切吸水和瑞利波-剪切波耦合诱发的大液化变形。此外,该模型还被应用于可液化地层中大规模土-结构相互作用的高性能模拟,包括地下结构、水坝、码头墙壁和海上风力涡轮机。
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来源期刊
Underground Space
Underground Space ENGINEERING, CIVIL-
CiteScore
10.20
自引率
14.10%
发文量
71
审稿时长
63 days
期刊介绍: Underground Space is an open access international journal without article processing charges (APC) committed to serving as a scientific forum for researchers and practitioners in the field of underground engineering. The journal welcomes manuscripts that deal with original theories, methods, technologies, and important applications throughout the life-cycle of underground projects, including planning, design, operation and maintenance, disaster prevention, and demolition. The journal is particularly interested in manuscripts related to the latest development of smart underground engineering from the perspectives of resilience, resources saving, environmental friendliness, humanity, and artificial intelligence. The manuscripts are expected to have significant innovation and potential impact in the field of underground engineering, and should have clear association with or application in underground projects.
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