Department of Mechanics: Seminar: Abstract Roubicek: Difference between revisions
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stored energies together with dissipation potentials. If the outer | stored energies together with dissipation potentials. If the outer | ||
loading is much slower than the time-scale of internal disipative | loading is much slower than the time-scale of internal disipative | ||
processes, these systems can approximately be considered as rate | processes, these systems can approximately be considered as rate-independent and the dissipated energy potential as positively homogeneous | ||
independent and the dissipated energy potential as positively | of degree 1. Typical examples are damage, plasticity, phase transformations, or fracture in the bulk, or delamination or friction | ||
of degree | |||
in adhesive contacts. The usual global-minimum concept for incremental | in adhesive contacts. The usual global-minimum concept for incremental | ||
problems preserves energy in the limit but may be computationally | problems preserves energy in the limit but may be computationally | ||
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a mixity-mode sensitive delamination (illustrated by numerical | a mixity-mode sensitive delamination (illustrated by numerical | ||
experiments performed by C.G.Panagiotopoulos and R.Vodicka), or | experiments performed by C.G.Panagiotopoulos and R.Vodicka), or | ||
a combination with | a combination with rate-dependent healing. | ||
Latest revision as of 09:17, 3 April 2014
Tomáš Roubíček, Charles University, Prague
Various Solution Concepts in Rate-Independent Evolution Systems
Evolution of mechanical systems is often governed by nonconvex stored energies together with dissipation potentials. If the outer loading is much slower than the time-scale of internal disipative processes, these systems can approximately be considered as rate-independent and the dissipated energy potential as positively homogeneous of degree 1. Typical examples are damage, plasticity, phase transformations, or fracture in the bulk, or delamination or friction in adhesive contacts. The usual global-minimum concept for incremental problems preserves energy in the limit but may be computationally difficult and often less physical than some force-driven locally-minimal solutions. Various concepts of solutions and various time-discretisations will be discussed, together with the role of the maximum-dissipation principle. Abstract considerations will be illustrated on a delamination problem (=an adhesive contact problem), together with some of its variants as a brittle contact or a mixity-mode sensitive delamination (illustrated by numerical experiments performed by C.G.Panagiotopoulos and R.Vodicka), or a combination with rate-dependent healing.