Calibration of DEM material parameters to simulate stress-strain behaviour of unsaturated soils during uniaxial compression

•Calibration of a DEM model at reasonable computational cost was achieved with Kriging.•DEM parameters were correlated with bulk density, clay content and water content.•Deformation was a combination of elastic and plastic processes, also at low stresses. Discrete element method (DEM) is an appealin...

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Bibliographic Details
Published in:Soil & tillage research 2019-11, Vol.194, p.104303, Article 104303
Main Authors: De Pue, Jan, Di Emidio, Gemmina, Verastegui Flores, R. Daniel, Bezuijen, Adam, Cornelis, Wim M.
Format: Article
Language:English
Subjects:
Discrete element method
Elastoplastic
Soil compaction
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Summary:•Calibration of a DEM model at reasonable computational cost was achieved with Kriging.•DEM parameters were correlated with bulk density, clay content and water content.•Deformation was a combination of elastic and plastic processes, also at low stresses. Discrete element method (DEM) is an appealing technique to simulate soil deformation. However, the calibration of the material parameters in the model remains challenging due to the high computational cost associated with it. In this study, the stress-strain relation of 125 unsaturated soil samples was simulated using DEM and material parameters were calibrated with Kriging. The Young's modulus and friction angle were found to be the most sensitive DEM material parameters, and they had a significant correlation with the bulk density, clay content and water content of the undisturbed soil samples. The DEM simulation showed that the deformation process was a combination of elastic and plastic processes, also at low stresses. Further improvement such as the coupling with (and calibration of) a fluid dynamics model might allow to more accurately simulate the dynamic behaviour of unsaturated soil compression.
ISSN:0167-1987
1879-3444
DOI:10.1016/j.still.2019.104303