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Probabilistic Analysis of Coupled Soil Consolidation |
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| Authors: | Jinsong Huang D. V. Griffiths Gordon A. Fenton |
| Affiliation: | 1Associate Research Professor, Div. of Engineering, Colorado School of Mines, Golden, CO 80401 (corresponding author). E-mail: jhuang@mines.edu 2Professor, Div. of Engineering, Colorado School of Mines, Golden, CO 80401. E-mail: d.v.griffiths@mines.edu 3Professor, Dept. of Engineering Mathematics, Dalhousie Univ., P.O. Box 1000, Halifax, NS, Canada B3J 2X4. E-mail: gordon.fenton@dal.ca |
| Abstract: | Coupled Biot consolidation theory was combined with the random finite-element method to investigate the consolidation behavior of soil deposits with spatially variable properties in one-dimensional (1D) and two-dimensional (2D) spaces. The coefficient of volume compressibility (mv) and the soil permeability (k) are assumed to be lognormally distributed random variables. The random fields of mv and k are generated by the local average subdivision method which fully takes account of spatial correlation, local averaging, and cross correlations. The generated random variables are mapped onto a finite-element mesh and Monte Carlo finite-element simulations follow. The results of parametric studies are presented, which describe the effect of the standard deviation, spatial correlation length, and cross correlation coefficient on output statistics relating to the overall “equivalent” coefficient of consolidation. It is shown that the average degree of consolidation defined by excess pore pressure and settlement are different in heterogeneous soils. The dimensional effect on the soil consolidation behaviors is also investigated by comparing the 1D and 2D results. |
| Keywords: | Finite element method Soil consolidation Probability Coupling |