Inelastic Strain Contributions
Many of the material models in COMSOL Multiphysics will compute a stress based on an elastic strain. The elastic strain tensor is obtained after removing any inelastic deformation contribution from the total deformation from the displacements. There are several possible inelastic strain contributions:
Additive Decomposition
In a geometrically linear analysis, the elastic strain is computed by a straightforward subtraction of the inelastic strain:
where
Additive decomposition of strains can also be used in a geometrically nonlinear analysis. In this case, it can however only be justified as long as the strains are small. In the case of large deformations, the different strain contributions may not even be commutative.
You can choose to use additive decomposition also for geometric nonlinearity by selecting the Additive strain decomposition check box in the settings for Linear Elastic Material or Nonlinear Elastic Material.
Multiplicative Decomposition
In the finite deformation case, the inelastic strain is instead removed using a multiplicative decomposition of the deformation gradient tensor. The elastic deformation gradient tensor is the basis for all strain energy formulations in hyperelastic materials, and also for the elastic strain in linear and nonlinear elasticity. It is derived by removing the inelastic deformation from the total deformation gradient tensor.
The total deformation gradient tensor is defined as the result of two successive operations, an inelastic deformation followed by an elastic deformation:
(3-4)
Since a deformation gradient tensor describes a mapping from one frame to another, there are actually three frames involved in this operation. The F tensor is defined by the displacements as usual and describes the mapping from the material frame to the spatial frame. The Finel tensor, however, describes a mapping from the material frame to an intermediate frame, and the Fel tensor describes a mapping from the intermediate frame to the spatial frame.
When the inelastic deformation gradient tensor is known, the elastic deformation gradient tensor is computed as
(3-5)
so the inelastic deformations are removed from the total deformation gradient tensor. The elastic right Cauchy–Green deformation tensor is then computed from Fel.
and the elastic Green–Lagrange strain tensor is computed as:
The inelastic deformation tensor Finel is derived from inelastic processes, such as thermal expansion or plasticity. When there are several inelastic contributions, they are applied sequentially to obtain the total inelastic deformation tensor Finel.
where Fi is the inelastic strain contribution from subnode i under a Linear Elastic Material, Nonlinear Elastic Material, or Hyperelastic Material.
The order is important when deformations are finite. The contributions are applied in the same order as the subnodes appear in the model tree. If a Thermal Expansion node appears before a Plasticity node, then the physical process can be viewed as a thermal expansion followed by a plastic deformation.
The internal variables for the elastic right Cauchy–Green deformation tensor in the local coordinate system are named solid.Cel11, solid.Cel12, and so on; and for the elastic Green–Lagrange tensor in local coordinates solid.eel11, solid.eel12, and so on.
The elastic, inelastic, and total volume ratios are related as
or
Large strain plasticity
In case of large strain plasticity, the plastic strains are primarily not represented as strains, but as the plastic deformation gradient tensor, Fpl.
The plastic Green–Lagrange strain tensor is computed from the plastic deformation gradient tensor as
As opposed to the small strain formulation, the total, plastic, and elastic Green–Lagrange strain tensors are related as