Theories of elastoplasticity coupled with continuum damage mechanics
Inelastic material constitutive relations for elastoplasticity coupled with continuum damage mechanics are investigated. For elastoplasticity, continuum damage mechanics, and the coupled formulations, rigorous thermodynamic frameworks are derived. The elastoplasticity framework is shown to be sufficiently general to encompass J[sub 2] plasticity theories including general isotropic and kinematic hardening relations. The concepts of an intermediate undamaged configuration and a fictitious deformation gradient are used to develop a damage representation theory. An empirically-based, damage evolution theory is proposed to overcome some observed deficiencies. Damage deactivation, which is the negation of the effects of damage under certain loading conditions, is investigated. An improved deactivation algorithm is developed for both damaged elasticity and coupled elastoplasticity formulations. The applicability of coupled formulations is validated by comparing theoretical predictions to experimental data for a spectrum of materials and loads paths. The pressure-dependent brittle-to-ductile transitional behavior of concrete is replicated. The deactivation algorithm is validated using tensile and compression data for concrete. For a ductile material, the behavior of an aluminum alloy is simulated including the temperature-dependent ductile-to-brittle behavior features. The direct application of a coupled model to fatigue is introduced. In addition, the deactivation algorithm in conjunction with an assumed initial damage and strain is introduced as a novel method of simulating the densification phenomenon in cellular solids.
- Research Organization:
- Sandia National Labs., Albuquerque, NM (United States)
- Sponsoring Organization:
- DOE; USDOE, Washington, DC (United States)
- DOE Contract Number:
- AC04-76DP00789
- OSTI ID:
- 6840093
- Report Number(s):
- SAND-92-1436; ON: DE93007426
- Country of Publication:
- United States
- Language:
- English
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Thermodynamically consistent theories for elastoplasticity coupled with damage
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Related Subjects
360103* -- Metals & Alloys-- Mechanical Properties
360203 -- Ceramics
Cermets
& Refractories-- Mechanical Properties
360603 -- Materials-- Properties
ALGORITHMS
ALLOYS
ALUMINIUM
ALUMINIUM ALLOYS
BUILDING MATERIALS
COMPRESSION
CONCRETES
DAMAGE
DEFORMATION
ELASTICITY
ELEMENTS
MATERIALS
MATHEMATICAL LOGIC
MATHEMATICAL MODELS
MECHANICAL PROPERTIES
MECHANICS
METALS
PLASTICITY
STRAINS
STRESSES
TENSILE PROPERTIES