Journal
COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING
Volume 289, Issue -, Pages 179-208Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cma.2015.02.010
Keywords
Shearbands; Eigenvalues; Instability; Failure; Non-constant Taylor-Quinney
Funding
- US Department of Energy Office of Science, Office of Advanced Scientific Computing Research, Applied Mathematics program [DE-SC-0008196]
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Shear bands are material instabilities associated with highly localized intense plastic deformation zones which can form in materials undergoing high strain rates. Determining the onset of shear band localization is a difficult task and past work reported in the literature attempt to detect this instability by computing the eigenvalues of the acoustic tensor or by studying the linear stability of the perturbed governing equations. However, both methods have their limitations and are not suited for general rate dependent materials in multidimensions. In this work we propose a novel approach to determine the onset of shear band localization and alleviate the limitations of the above mentioned methods. Owing to the implicit mixed finite elements discretization employed in this work, we propose to cast the instability analysis as a generalized eigenvalue problem by employing a particular decomposition of the element Jacobian matrix. We show that this approach is attractive, as it is applicable to general rate dependent multidimensional cases where no special simplifying assumptions ought to be made. To verify the accuracy of the proposed eigenvalue analysis, we first extend an analytical criterion by applying linear perturbation techniques to the continuous PDE model, considering an elastoplastic material with thermal diffusion and a nonlinear Taylor-Quinney coefficient. While this extension is novel on its own, it requires strenuous derivations and is not easily extended to general multidimension applications. Hence, herein it is only used for verification purposes in 1D. Numerical results on one-dimensional problems show that the eigenvalue analysis exactly recovers the instability point predicted by the analytical criterion with non-linear Taylor-Quinney coefficient. In addition, the proposed generalized eigenvalue analysis is applied on two-dimensional problems where propagation of the instability can be easily determined. (C) 2015 Elsevier B.V. All rights reserved.
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