TY - JOUR

T1 - 3D mixed virtual element formulation for dynamic elasto-plastic analysis

AU - Cihan, Mertcan

AU - Hudobivnik, Blaž

AU - Aldakheel, Fadi

AU - Wriggers, Peter

PY - 2021/9

Y1 - 2021/9

N2 - The virtual element method (VEM) for dynamic analyses of nonlinear elasto-plastic problems undergoing large deformations is outlined within this work. VEM has been applied to various problems in engineering, considering elasto-plasticity, multiphysics, damage, elastodynamics, contact- and fracture mechanics. This work focuses on the extension of VEM formulations towards dynamic elasto-plastic applications. Hereby low-order ansatz functions are employed in three dimensions with elements having arbitrary convex or concave polygonal shapes. The formulations presented in this study are based on minimization of potential function for both the static as well as the dynamic behavior. Additionally, to overcome the volumetric locking phenomena due to elastic and plastic incompressibility conditions, a mixed formulation based on a Hu-Washizu functional is adopted. For the implicit time integration scheme, Newmark method is used. To show the model performance, various numerical examples in 3D are presented.

AB - The virtual element method (VEM) for dynamic analyses of nonlinear elasto-plastic problems undergoing large deformations is outlined within this work. VEM has been applied to various problems in engineering, considering elasto-plasticity, multiphysics, damage, elastodynamics, contact- and fracture mechanics. This work focuses on the extension of VEM formulations towards dynamic elasto-plastic applications. Hereby low-order ansatz functions are employed in three dimensions with elements having arbitrary convex or concave polygonal shapes. The formulations presented in this study are based on minimization of potential function for both the static as well as the dynamic behavior. Additionally, to overcome the volumetric locking phenomena due to elastic and plastic incompressibility conditions, a mixed formulation based on a Hu-Washizu functional is adopted. For the implicit time integration scheme, Newmark method is used. To show the model performance, various numerical examples in 3D are presented.

KW - Dynamics

KW - Finite strains

KW - Plasticity, Mixed formulations

KW - Three-dimensional

KW - Virtual element method (VEM)

UR - http://www.scopus.com/inward/record.url?scp=85104738105&partnerID=8YFLogxK

U2 - 10.1007/s00466-021-02010-8

DO - 10.1007/s00466-021-02010-8

M3 - Article

AN - SCOPUS:85104738105

VL - 68

JO - Computational Mechanics

JF - Computational Mechanics

SN - 0178-7675

IS - 3

ER -