之設定
Alvin Chen
Outline
Elastic Behavior
Compressibility (Hyperelasticity)Strain energy potentials (Hyperelasticity)Example
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Elastic Behavior
Linear elasticity
Small elastic strains (normally less then 5%)Isotropic, orthotropic, or fully anisotropic
Can have property depend on temperature and/or other field variables
Hypoealsticity
Small elastic strains-the stresses should not be large compared to the elastic modulus of the materialLoad path is monotonic
If temperature is to be included “UHYPEL”
Hyperfoam
Isotropic and nonlinear, energy dissipation and stress softening effectsCellular solids whose porosity permits very large volumetric changesDeform elastically to large strains, up to 90% strain in compressionRequires geometric nonlinearity be accounted in analysis step
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Elastic Behavior
Porous elasticity
Small elastic strains (normally less then 5%)
Nonlinear, isotropic elasticity Isotropic, orthotropic, or fully anisotropicCan have property depend on temperature and/or other field variables
Viscoelasticity
“viscous” (internal damping) effect, time dependentLarge-strain problem
Hyperealsticity
For rubberlikematerial at finite strain the hyperelastic model provides a general strain energy potential to describe the material behavior for nearly incompressible elastomers. This nonlinear elasticity model is valid for large elastic strains.
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Elastic Behavior
The Hyperelastic material model:
Is isotropic and nonlinear
Is valid for materials that exhibit instantaneous elastic response up to large strains (such as rubber, solid propellant, or other elastomeric materials)
Requires that geometric nonlinearity be accounted for during the analysis step, since it is intended for finite-strain applications.
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Compressibility (Hyperelasticity)
Most elastomers (solid, rubberlike materials) have very little compressibility compared to their shear flexibility. In ABAQUS/Standard to assume that the material is fully incompressible.Another class of rubberlike materials is elastomeric foam, which is elastic but very compressible.In ABAQUS/Standard the use of hybird (mixed formulation) elements is recommended in both incompressible and almost incompressible cases.
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Compressibility (Hyperelasticity)
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Strain energy potentials (Hyperelasticity)
Hyperelastic materials are described in terms of a
“strain energy potential”, which defines the strain energy stored in the material per unit of reference volume (volume in the initial configuration) as a function of the strain at that point in the material
Arruda-Boyce formMarlow form
Mooney-Rivlin formNeo-Hookean formOgden form
Polynomial form
Reduced Polynomial formVan der Waals formYeoh form
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Strain energy potentials (Hyperelasticity)
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Strain energy potentials (Hyperelasticity)
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Strain energy potentials (Hyperelasticity)
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Strain energy potentials (Hyperelasticity)
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Strain energy potentials (Hyperelasticity)
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