Semi-analytical method for solving stresses in slope under general loading conditions

IF 5.8 4区 工程技术 Q1 MECHANICS
P. Wu, Xuejun Sun, Dayong Zhu Zhu
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Abstract

Abstract Assessing the stress distribution within the slope in geotechnical engineering is critical. Despite the widely available numerical methods, no analytical solutions are available for determining the stress distribution within a slope under general loading conditions. This study presents a method of analytically approximating elastic stresses within a slope of arbitrary inclination subject to general surcharges and supporting forces. The prototype model of this problem is equivalent to a superposition of two sub-models: a half-plane body subjected to an initial earth stress field as well as surcharges on the crest (Model I) and a slope loaded by the release stresses caused by excavation, together with supporting forces on its inclined surface and bottom (Model II). The former stresses can be calculated analytically using Flamant’s solution, and the latter stresses can be further thought of as being composed of two additional components: one in an infinite plane with a half-infinite hole loaded by virtual tractions upon hole’s boundary (Model II1), which can be analytically approximated, and the other in a half-plane subjected to virtual tractions along the ground surface (Model II2), which can be calculated analytically as well. The two sets of virtual tractions that lead to stresses in Model II are calculated using an iterative process. The current approach provides analytical approximations of elastic stress solutions for slopes that are sufficiently close to the exact ones as accurate as much. A case study demonstrates that such solutions are in good agreement with those of the finite-element method’s over the entire region, the stresses within the region up to 10−11 times the slope’s height away from the slope toe can also be accurately determined using the current method. With this method, contour plots of stresses within a slope inclined at various angles are presented, which can be applied directly in practical engineering.
一般荷载条件下求解边坡应力的半解析方法
摘要在岩土工程中,评估边坡内的应力分布至关重要。尽管有广泛可用的数值方法,但在一般荷载条件下,没有分析解可用于确定边坡内的应力分布。本文提出了一种分析近似任意倾斜斜坡在一般附加费和支撑力作用下的弹性应力的方法。该问题的原型模型相当于两个子模型的叠加:一个半平面体受到初始土应力场以及顶部附加费的影响(模型I),另一个边坡受到开挖引起的释放应力以及斜面和底部支撑力的影响(模式II)。前者的应力可以使用Flamant解进行解析计算,后者的应力可进一步认为由两个附加分量组成:一个在无限平面内,半无限孔由孔边界上的虚拟牵引加载(模型II1),可以进行解析近似,另一个在沿着地面受到虚拟牵引的半平面中(模型II2),这也可以通过解析计算。模型II中导致应力的两组虚拟牵引力是使用迭代过程计算的。目前的方法为斜坡提供了弹性应力解的解析近似,这些解与精确解足够接近。一个案例研究表明,这种解决方案与有限元法在整个区域的解决方案非常一致,使用当前方法也可以准确地确定距离坡脚10−11倍斜坡高度的区域内的应力。利用该方法,给出了不同角度倾斜边坡内应力的等值线图,可直接应用于实际工程中。
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
Applied Rheology
Applied Rheology 物理-力学
CiteScore
3.00
自引率
5.60%
发文量
7
审稿时长
>12 weeks
期刊介绍: Applied Rheology is a peer-reviewed, open access, electronic journal devoted to the publication in the field of applied rheology. The journal provides the readers with free, instant, and permanent access to all content worldwide; and the authors with extensive promotion of published articles, long-time preservation, language-correction services, no space constraints and immediate publication.
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