1966
DOI: 10.1680/geot.1966.16.3.231
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Stresses in Foundation Soils Due to Vertical Subsurface Loading

Abstract: Synopsis Based on the work of R. D. Mindlin solutions have been obtained for the stresses created by vertical subsurface loading in a semi-infinite, homogeneous, isotropic, elastic medium obeying Hooke's law. The original Mindlin solution and two extensions of it have been considered and the results are presented in the form of dimensionless stress coefficients. For practical application the complex expressions for the vertical-stress coefficients have been evaluated by electronic computer and the results giv… Show more

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Cited by 46 publications
(26 citation statements)
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“…The numerical results are in good agreement with the Mindlin's [3] and Geddes's solutions [5] when the medium is homogeneous and isotropic (as seen in Figure 6 in the illustrative examples section), and with Wang's solutions [7] when the medium is homogeneous but cross-anisotropic (as seen in Figures 7-9 in the Illustrative Examples section).…”
Section: Case A: Stresses Due To a Point Loadsupporting
confidence: 79%
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“…The numerical results are in good agreement with the Mindlin's [3] and Geddes's solutions [5] when the medium is homogeneous and isotropic (as seen in Figure 6 in the illustrative examples section), and with Wang's solutions [7] when the medium is homogeneous but cross-anisotropic (as seen in Figures 7-9 in the Illustrative Examples section).…”
Section: Case A: Stresses Due To a Point Loadsupporting
confidence: 79%
“…where x is a singular point; a; b are the lower, upper limit, respectively; e is a tiny parameter with respect to the integral interval b À a: Thus, the stresses for an end-bearing pile in the inhomogeneous and cross-anisotropic halfspace, as seen in Figure 2, can be obtained by substituting Z by L in Equation (5). The numerical results are in good agreement with the Mindlin's [3] and Geddes's solutions [5] when the medium is homogeneous and isotropic (as seen in Figure 6 in the illustrative examples section), and with Wang's solutions [7] when the medium is homogeneous but cross-anisotropic (as seen in Figures 7-9 in the Illustrative Examples section).…”
Section: Case A: Stresses Due To a Point Loadmentioning
confidence: 99%
“…Furthermore, since the assumptions inherent in the analyses, vertical surface displacements for compound forms of loading can be acquired by superposition. With results from the three types of loadings analysed a great deal of loadings can be treated [14]. For instance, in the case of a friction load varying linearly from a maximum at the ground surface to zero at the pile length L, the solution, u d z(oblique) , is obtained from the following relationship:…”
Section: Case C: Vertical Surface Displacement Due To a Linear Variatmentioning
confidence: 99%
“…Normally, for a friction pile, load distributions around the pile shaft are due to the shear forces acting along the interface of the pile and the soil [13]. The loads practically could be considered as a uniformly or linearly varying distributed with depth from the surface to the pile length [13,14]. However, for an end-bearing pile, which relies primarily on the concentrated soil resistance at the tip of the pile, and the tip's resistance, could be modelled as a point load [11].…”
Section: Introductionmentioning
confidence: 99%
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