An alternative formulation for quasi-static frictional and cohesive contact problems

An alternative formulation for quasi-static frictional and cohesive contact problems

It is known by Engineering practitioners that quasi-static contact problems with friction and cohesive laws often present convergence difficulties in Newton iteration. These are commonly attributed to the non-smoothness of the equilibrium system. However, non-uniqueness of solutions is often an obst...

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Bibliographic Details
Published in:Computational mechanics Vol. 53; no. 4; pp. 807 - 824
Main Authors: Areias, P., Pinto da Costa, A., Rabczuk, T., Queirós de Melo, F. J. M., Dias-da-Costa, D., Bezzeghoud, Mourad
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-04-2014
Springer
Springer Nature B.V
Subjects:
Algorithms
Classical and Continuum Physics
Coefficient of friction
Cohesion
Computational Science and Engineering
Contact
Convergence
Degrees of freedom
Engineering
Friction
Iterative methods
Mathematical analysis
Mathematical models
Original Paper
Robustness (mathematics)
Smoothness
Theoretical and Applied Mechanics
Three dimensional
Ultrasonic testing
Friction
Cohesive law
Complementarity
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Summary:It is known by Engineering practitioners that quasi-static contact problems with friction and cohesive laws often present convergence difficulties in Newton iteration. These are commonly attributed to the non-smoothness of the equilibrium system. However, non-uniqueness of solutions is often an obstacle for convergence. We discuss these conditions in detail and present a general algorithm for 3D which is shown to have quadratic convergence in the Newton–Raphson iteration even for parts of the domain where multiple solutions exist. Chen–Mangasarian replacement functions remove the non-smoothness corresponding to both the stick-slip and normal complementarity conditions. Contrasting with Augmented Lagrangian methods, second-order updating is performed for all degrees-of-freedom. Stick condition is automatically selected by the algorithm for regions with multiple solutions. The resulting Jacobian determinant is independent of the friction coefficient, at the expense of an increased number of nodal degrees-of-freedom. Aspects such as a dedicated pivoting for constrained problems are also of crucial importance for a successful solution finding. The resulting 3D mixed formulation, with 7 degrees-of-freedom in each node (displacement components, friction multiplier, friction force components and normal force) is tested with representative numerical examples (both contact with friction and cohesive force), which show remarkable robustness and generality.
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ISSN:0178-7675
1432-0924
DOI:10.1007/s00466-013-0932-x