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| plasticity [2020/03/11 13:25] – pericles | plasticity [2020/03/11 13:30] (current) – pericles |
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| <font 20px/inherit;;inherit;;inherit>**Large strain viscoelastic-viscoplastic constitutive model applied to 2D contact problems**</font> | <font 20px/inherit;;inherit;;inherit>**Large strain viscoelastic-viscoplastic constitutive model applied to 2D contact problems**</font> |
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| Motivated by several manufacturing processes, such as cold metal forming and additive manufacturing, in this work we develop a computational code for numerical simulation of two-dimensional problems addressing three types of nonlinearities: geometric nonlinearity, present in large displacements situations; physical non-linearity, present in the material constitutive model; and contact non-linearity. | Motivated by several manufacturing processes, such as cold metal forming and additive manufacturing, we develop a computational code for numerical simulation of two-dimensional problems addressing three types of nonlinearities: geometric nonlinearity, present in large displacements situations; physical non-linearity, present in large strain / inelastic constitutive models; and contact non-linearity. |
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| In the first step, we develop a computational program for dynamic analysis of two-dimensional elastic solids using the positional finite element method, which naturally takes into account geometric non-linearity in its formulation. | We present a large strain viscoelastic-viscoplastic model by coupling visco-elastic and visco-plastic models based on the multiplicative decomposition of the deformation gradient. Regarding the 2D application, we consider both plane strain and plane stress hypothesis, where the latter is solved numerically by a local Newton-Raphson procedure. The video above shows the expected behaviour of a viscoelastic-viscoplastic cube under loading-unloading. |
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| Following, we implement inelastic constitutive models for large strain problems. In the elasto-plastic model, we adopt von Mises yeld criteria and kinematic hardening based on the Armstrong-Frederick law. The formulation is then generalized to the visco-plastic case, where we consider Perzyna model associated with Norton's law. In the visco-elastic case, Zener's rheological model is employed. Finally, we present a viscoelastic-viscoplastic model by coupling the visco-elastic and visco-plastic models described previously. In every case, the multiplicative decomposition of the deformation gradient is employed. Regarding the 2D application, we consider both plane strain and plane stress hypothesis, where the latter is solved numerically by a local Newton-Raphson procedure. The video above shows the expected behaviour of a viscoelastic-viscoplastic cube under loading-unloading. | //{{ youtube>XD_6Mc1_urw?560x315 }} // |
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| //{{ youtube>XD_6Mc1_urw?560x315 }}// | |
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