Abstract
In this study, a probabilistic approach for evaluating the bearing capacity of surface footings is discussed. The evaluation is based on a kinematic approach. The considered substrate consists of two different layers of soil: a top layer formed of medium or dense sand followed by a layer of soft clay. The sand layer is assumed to be homogenous, whereas the undrained shear strength of the soft clay layer is assumed to be spatially variable, described by a lognormal random field. The random field is discretized according to Vanmarcke’s spatial averaging along dissipation regions in the considered failure mechanism. The mechanism utilizes plane strain conditions; however, due to consideration of the soil spatial variability in three dimensions, the impact of the length of the foundation on the random bearing capacity evaluation is considered in this study. As a result of the discretization procedure, a set of correlated random variables is obtained (each associated with an individual dissipation region in the failure mechanism). A series of numerical analyses are performed for two thicknesses of the first layer and a set of anisotropic correlation structures for the spatial variability of the undrained shear strength. The proposed method is computationally efficient and allows consideration of three-dimensional spatial variability in soil strength properties. The results are discussed and compared with those obtained by other methods.
Highlights
Bearing capacity evaluations of shallow foundations in the case of spatially variable soil are currently used primarily for two-dimensional analysis
This study provides an efficient method for analysing such engineering problems and demonstrates that the random bearing capacity of two-layered soil in the case of spatial variability in the bottom layer can be efficiently evaluated by the developed kinematic approach
An original adaptation of the two-dimensional failure mechanism for two-layered soil proposed by Michałowski and Shi [3] to random analyses is shown in the present study
Summary
Bearing capacity evaluations of shallow foundations in the case of spatially variable soil are currently used primarily for two-dimensional analysis. One of the reasons for this situation is numerical efficiency, which limits the use of three-dimensional finite element formulations for random analyses. An especially important situation is when the bottom layer is a soft soil and the top layer is a strong soil. This scenario has been extensively examined in the case of deterministic analyses (e.g., [2,3,4,5]); there have been very few studies on random analyses of two-layered soil (e.g., [6]). It is worth mentioning that it is possible to perform these types of two-dimensional analyses by using OptumCE software
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