Finite element implementation and application of a sand model in micropolar theory
Autor: | Zhen-Yu Yin, Lijian Wu, Jiangxin Liu, Pierre-Yves Hicher |
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Jazyk: | angličtina |
Rok vydání: | 2021 |
Předmět: |
Technology
Materials science General Chemical Engineering Science 0211 other engineering and technologies General Physics and Astronomy 02 engineering and technology Micropolar technique Granular material 01 natural sciences Mesh independency Numerical simulations General Materials Science 0101 mathematics 021101 geological & geomatics engineering General Environmental Science Plane stress Rotational degree 010102 general mathematics General Engineering Mechanics Finite element method Shear (sheet metal) General Earth and Planetary Sciences Element (category theory) Strain localization |
Zdroj: | SN Applied Sciences, Vol 3, Iss 8, Pp 1-14 (2021) |
ISSN: | 2523-3971 2523-3963 |
Popis: | Abstract In traditional finite element failure analyses of geotechnical structures, the micro grain rotations cannot be modelled and numerical solutions are mesh dependent. In this study, a user element including rotational degree of freedom has been developed based on micropolar theory (Cosserat theory), then an enhanced non-associated sand model is calibrated with laboratory data and used to model the plane strain tests. The simulated results demonstrate the polarized model is able to model reasonably the sand behavior as well as the grain rotations in the localized region. What’s more, with this enhanced model, the mesh independent numerical solutions in terms of mechanical responses, shear bands thickness and orientations have been obtained. Article highlights In failure analysis of geostructures, significant rotations of soil grains have been observed to occur in the strain localized regions, but the current commercial Finite Element tools cannot model the micro rotations. Therefore, a user defined element must be developed to include the rotational degree of freedom. The micropolar approach is proven to be effective to model the grain rations in present paper. More suitable than other classical soil or sand constitutive models, the selected non-associated sand model in present paper is capable of describing well the contraction and shear dilatancy behaviors of sand. Then the model has been enhanced by means of micropolar technique, in this way, the reasonable strain localization phenomena in laboratory tests could be predicted well. There are always the mesh dependent problems for traditional simulations of the strain localization phenomena in finite element analysis. It can be found in present paper that the mesh independent numerical solutions are obtained by means of micropolar technique. Furthermore, the micropolar approach can obviously improve convergence difficulties in finite element analyses. |
Databáze: | OpenAIRE |
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