Finite strain fracture of plates and shells with configurational forces and edge rotations
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Wiley
Abstract
We propose a simple and efficient algorithm for FEM-based computational fracture of plates and shells
with both brittle and ductile materials based on edge rotation and load control. Rotation axes are the
crack front nodes and each crack front edge in surface discretizations affects the position of only one or
two nodes. Modified positions of the entities maximize the modified mesh quality complying with the
predicted crack path (which depends on the specific propagation theory in use). Compared with XFEM
or with classical tip remeshing, the proposed solution has algorithmic and generality advantages. The
propagation algorithm is simpler than the aforementioned alternatives and the approach is independent
of the underlying element used for discretization. For history-dependent materials, there are still some
transfer of relevant quantities between elements. However, diffusion of results is more limited than
with tip or full remeshing. To illustrate the advantages of our approach, three prototype models are
used: tip energy dissipation (LEFM), cohesive-zone approaches and ductile fracture. Both the Sutton
crack path criterion and the path estimated by the Eshelby tensor are employed. Traditional fracture
benchmarks, including one with plastic hinges, and newly proposed verification tests are solved. These
were found to be very good