Hierarchical NURBS in frictionless contact
Computer Methods in Applied Mechanics and Engineering
Please cite this item using this persistent URLhttp://hdl.handle.net/11693/21147
This work investigates mortar-based frictionless contact in the context of NURBS discretizations that are subjected to local hierarchical refinement. The investigations emphasize three sets of choices which lead to different contact algorithms that have distinct advantages and disadvantages. First, on the optimization side, both exterior and interior point methods are applied, thus spanning inexact constraint enforcement algorithms of the penalty or barrier type as well as exact ones of the primal-dual type. Second, on the discretization side, the hierarchical basis set of the mortar variables is inherited either directly from the discretization of the slave surface or after an intermediate normalization step to satisfy the partition of unity. Third, in interaction with both optimization and discretization, the kinematic mortar variable is recovered from the actual normal gap through the full or lumped solution of a linear system of equations. The implications of different choices are highlighted through benchmark problems which monitor the solution quality at the global level through the structural force evolution and at the local level through the contact pressure distribution. © 2015 Elsevier B.V.
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Temizer I.; Wriggers P.; Hughes, T.J.R. (2012)A three-dimensional mortar-based frictional contact treatment in isogeometric analysis with NURBS is presented in the finite deformation regime. Within a setting where the NURBS discretization of the contact surface is ...
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