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Journal of Theoretical
and Applied Mechanics
53, 2, pp. 487-500, Warsaw 2015
DOI: 10.15632/jtam-pl.53.2.487
and Applied Mechanics
53, 2, pp. 487-500, Warsaw 2015
DOI: 10.15632/jtam-pl.53.2.487
APPLICATION OF VARIATIONAL AND FEM METHODS TO THE MODELLING AND NUMERICAL ANALYSIS OF THE SLITTING PROCESS FOR GEOMETRICAL AND PHYSICAL NONLINEARITY
Finite element modelling provides a great deal of support in the understanding of technological
processes. However, there are few studies of the slitting process, and those that exist
are simplified for use only in the calculation of steady states of such processes. This paper
proposes the application of variational and finite element methods for the analysis of slitting
and the nonlinearities of this process. Physical and mathematical models of the process and
a new thermo-elastic/thermo-visco-plastic material model are elaborated. The procedure is
implemented in the finite element code ANSYS/LS-DYNA and the model is validated comparing
the numerical and experimental results. The influence of various process conditions
on the strain and stress states and the quality of the final product are analysed. The results
lay the groundwork for further study regarding the numerical analysis of spring-back
behaviour and the effect of tool elasticity on the quality of the final workpiece.
processes. However, there are few studies of the slitting process, and those that exist
are simplified for use only in the calculation of steady states of such processes. This paper
proposes the application of variational and finite element methods for the analysis of slitting
and the nonlinearities of this process. Physical and mathematical models of the process and
a new thermo-elastic/thermo-visco-plastic material model are elaborated. The procedure is
implemented in the finite element code ANSYS/LS-DYNA and the model is validated comparing
the numerical and experimental results. The influence of various process conditions
on the strain and stress states and the quality of the final product are analysed. The results
lay the groundwork for further study regarding the numerical analysis of spring-back
behaviour and the effect of tool elasticity on the quality of the final workpiece.
Keywords: slitting, constitutive laws, modelling, numerical simulation, variational formulation, FEM