Effect of gravity on liquefaction behavior

IF 3.3 2区工程技术 Q2 ENGINEERING, GEOLOGICAL

Soils and Foundations Pub Date : 2025-05-02 DOI:10.1016/j.sandf.2025.101617

R. Sukhumkitcharoen , J. Koseki , M. Otsubo , T. Morimoto

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引用次数: 0

Abstract

Attaining a fully liquefied state with zero effective stress in laboratory element tests is inherently challenging, as this state is typically achieved only in the upper layers of specimens, while the lower layers are still influenced by residual gravitational forces (or self-weight). This challenge has highlighted concerns regarding the potential overestimation of the liquefaction resistance in laboratory-based assessments. In response to this, the present study introduces an advanced bi-axial apparatus designed for testing under both dry and submerged conditions, employing circular plastic rods to enable an analysis with detailed images. Furthermore, discrete element method (DEM) simulations are conducted to replicate analogous environments under varying gravity conditions. The results demonstrate that the configuration of the apparatus, which utilizes lighter materials, significantly diminishes the gravity-induced stress gradient, achieving near-zero effective mean stress in the submerged condition. Both laboratory tests and DEM simulations consistently show similar trends under different gravity settings, such as enhanced contractive behavior, reduced remaining mean stress, and reduced remaining stiffness during the liquefied state in lower gravity environments, resulting in a reduction in liquefaction resistance. These characteristics are attributed to the stimulated loss of inter-particle contacts and an increased number of unstable particles, resulting in weakened void- and contact-based fabrics against cyclic loading under lower gravity conditions. Based on the current testing conditions, a correction factor of approximately 0.6 to 0.8 is advised for bi-axial tests conducted at standard gravity (1g) to convert the liquefaction resistance measured in the laboratory to that suitable for practical applications.

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重力对液化行为的影响

在实验室元件测试中达到零有效应力的完全液化状态本质上是具有挑战性的，因为这种状态通常只在试样的上层实现，而下层仍然受到残余重力（或自重）的影响。这一挑战突出了人们对实验室评估中可能高估液化抗性的担忧。为此，本研究介绍了一种先进的双轴仪器，设计用于在干燥和淹没条件下进行测试，采用圆形塑料棒进行详细图像分析。此外，采用离散元法（DEM）模拟了不同重力条件下的模拟环境。结果表明，该装置采用了较轻的材料，显著减小了重力引起的应力梯度，在水下状态下实现了接近零的有效平均应力。在不同的重力环境下，实验室测试和DEM模拟都一致显示出类似的趋势，例如在低重力环境下，液化状态下的收缩行为增强，剩余平均应力降低，剩余刚度降低，从而导致液化阻力降低。这些特性归因于颗粒间接触的损失和不稳定颗粒数量的增加，导致在较低重力条件下，基于孔隙和接触的织物在循环载荷下变弱。根据目前的测试条件，建议在标准重力（1g）下进行的双轴测试的校正系数约为0.6至0.8，以将实验室测量的液化阻力转换为适合实际应用的液化阻力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Soils and Foundations 工程技术-地球科学综合

CiteScore

6.40

自引率

8.10%

发文量

审稿时长

5 months

期刊介绍： Soils and Foundations is one of the leading journals in the field of soil mechanics and geotechnical engineering. It is the official journal of the Japanese Geotechnical Society (JGS)., The journal publishes a variety of original research paper, technical reports, technical notes, as well as the state-of-the-art reports upon invitation by the Editor, in the fields of soil and rock mechanics, geotechnical engineering, and environmental geotechnics. Since the publication of Volume 1, No.1 issue in June 1960, Soils and Foundations will celebrate the 60th anniversary in the year of 2020. Soils and Foundations welcomes theoretical as well as practical work associated with the aforementioned field(s). Case studies that describe the original and interdisciplinary work applicable to geotechnical engineering are particularly encouraged. Discussions to each of the published articles are also welcomed in order to provide an avenue in which opinions of peers may be fed back or exchanged. In providing latest expertise on a specific topic, one issue out of six per year on average was allocated to include selected papers from the International Symposia which were held in Japan as well as overseas.