Abstract
The fundamental concepts of Continuum Damage Mechanics are reviewed, with the objective to conform to a sufficiently general thermodynamic framework. The theories are developed at a macroscopic level, with the capability to describe various types of materials, ductile or brittle, metallic, concrete, composites,… etc., in an unique framework. For that, we consider both elasticity coupled with damage, plasticity and viscoplasticity coupled with damage and the damage growth equations themselves. Moreover, we discuss the important but difficult problems associated with the damage deactivation effects that can take place under compressive loadings.
A special attention is focused on the nature of damage state variables, in correspondence with the choices made in the various thermodynamic potentials, and on the various coupling possibilities. Some applications are presented on metallic materials, concerning ductile damage, creep damage and creep-fatigue interaction. We also discuss briefly the different levels for the inelastic/damage structural analysis and the applications of CDM to the Local Approaches to Fracture. Some illustrations are also given for Metal Matrix Composites and Ceramic Matrix Composites.
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Chaboche, JL. (1999). Thermodynamically Founded CDM Models for Creep and Other Conditions. In: Altenbach, H., Skrzypek, J.J. (eds) Creep and Damage in Materials and Structures. International Centre for Mechanical Sciences, vol 399. Springer, Vienna. https://doi.org/10.1007/978-3-7091-2506-9_5
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DOI: https://doi.org/10.1007/978-3-7091-2506-9_5
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