Probabilistic pile reinforced slope stability analysis using load transfer factor considering anisotropy of soil cohesion

IF 1.8 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Engineering reports : open access Pub Date : 2024-03-20 DOI:10.1002/eng2.12877
Jiahui Wen, Xuesong Chu, Liang Xu, Guangming Yu, Liang Li
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Abstract

A probabilistic limit equilibrium framework combining empirical load transfer factor and anisotropy of soil cohesion is developed to conduct pile-reinforced slope reliability analysis. The anisotropy of soil cohesion is determined conditioned on that the thrust force direction is parallel to the major principal direction and it is easily combined with load transfer factor, which are related with soil parameters, and pile parameters. The proposed method is illustrated against a homogeneous soil slope. The sensitivity studies of pile parameters on factor of safety (FS; calculated at respective means of soil parameters) and β demonstrated that the anisotropy of soil cohesion tends to pose significant effect on reliability index β than on FS. The effect of anisotropy of soil cohesion on FS is found to be slightly different under different pile locations, whereas its effect on β is observed to be least if piles are drilled at the middle part of slope and more significant effect is observed when piles are drilled at the lower and upper part of slope. The plots from the sensitivity studies provide an alternative tool for pile designs aiming at the target reliability index β. The proposed method contributes to the pile-reinforced slope stability within limit equilibrium framework.

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考虑土体内聚力各向异性,利用荷载传递因子进行桩加固边坡稳定性概率分析
结合经验荷载传递系数和土体内聚力各向异性,建立了一个概率极限平衡框架,用于进行桩加固边坡可靠性分析。土的内聚力各向异性是在推力方向平行于主要主方向的条件下确定的,它很容易与荷载传递系数(与土的参数和桩的参数有关)相结合。所提出的方法以均质土坡为例进行了说明。桩参数对安全系数(FS,按各自土质参数计算)和 β 的敏感性研究表明,土质内聚力的各向异性对可靠度指数 β 的影响大于对安全系数的影响。在不同桩位下,土的内聚力各向异性对 FS 的影响略有不同,而在斜坡中部钻孔打桩时,土的内聚力各向异性对 β 的影响最小,在斜坡下部和上部钻孔打桩时,土的内聚力各向异性对 β 的影响更大。灵敏度研究得出的曲线图为以目标可靠性指数 β 为目标的桩基设计提供了一种替代工具。 所提出的方法有助于在极限平衡框架内实现桩加固边坡的稳定性。
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5.10
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0.00%
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审稿时长
19 weeks
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