Dynamic Stability Analysis of a Wharf under Cyclic Loading Considering the Weakening Effect of a Soft Foundation

IF 0.8 4区 工程技术 Q4 ENGINEERING, GEOLOGICAL
Bing Xiao
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引用次数: 0

Abstract

Creep deformation and softening of soft soil foundations under long-term wave loading can cause gravity wharves to experience problems such as excessive settlement, displacement, and sliding, compromising the safety of the wharf structure. In this study, we conduct mechanical index and vibration tests on consolidated and undrained soft soil specimens to analyze the changes in the soil dynamic characteristics with strain under different confining pressures. Subsequently, the dynamic deformation and strength characteristics of the soft soil obtained from triaxial tests are used to develop a finite element model of the wave–gravity structure–soft soil foundation system. Using this model, analyses are conducted by varying the friction angle to simulate the change in the soft soil strength as the number of wave cycles increases. The results are evaluated to investigate the failure mechanism of the foundation and the bearing characteristics of the riprap bed atop the soft soil. The results indicate that the shear modulus of the soil is related to the effective confining pressure and the shear strain; this relationship is fitted using the Van Genuchten equation. As the internal friction angle of the soft soil foundation decreases, its stability decreases nonlinearly, its strength decreases, and its sliding failure surface lengthens. However, simply increasing the riprap layer thickness has a limited effect on the overall wharf stability. These findings will improve the design of gravity wharves founded on soft soils in port areas with intense wave action.

考虑软地基削弱效应的循环荷载下的码头动态稳定性分析
软土地基在长期波浪荷载作用下发生蠕变变形和软化,会导致重力式码头出现过度沉降、位移和滑动等问题,影响码头结构的安全性。本研究对固结软土和未排水软土试件进行力学指标和振动试验,分析不同约束压力下软土动力特性随应变的变化。随后,利用三轴试验获得的软土动态变形和强度特征,建立了波浪重力结构-软土地基系统的有限元模型。利用该模型,通过改变摩擦角来模拟软土强度随波浪循环次数增加而发生的变化。对结果进行了评估,以研究地基的破坏机制和软土上护坡床的承载特性。结果表明,土壤的剪切模量与有效约束压力和剪切应变有关;这一关系使用范-格努赫腾方程进行拟合。随着软土地基内摩擦角的减小,其稳定性非线性下降,强度降低,滑动破坏面延长。然而,单纯增加护坡层厚度对码头整体稳定性的影响有限。这些发现将改进波浪作用强烈的港口地区软土地基重力式码头的设计。
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
CiteScore
1.50
自引率
12.50%
发文量
65
审稿时长
6 months
期刊介绍: Soil Mechanics and Foundation Engineering provides the Western engineer with a look at Russian advances in heavy construction techniques. Detailed contributions by experienced civil engineers offer insights into current difficulties in the field, applicable innovative solutions, and recently developed guidelines for soil analysis and foundation design.
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