Difference between revisions of "Mooney Material"

From OSUPDOCS
Jump to navigation Jump to search
Line 1: Line 1:
== Constitutive Law ==
== Constitutive Law ==


The Mooney-Rivlin material  [[Material Models|Mooney-Rivlin]] is an isotropic, elastic, hyperelastic material. The constitutive law derived from a strain energy function that is a function of the deformation gradient tensor F.  
The Mooney-Rivlin material  [[Material Models|Mooney-Rivlin]] is an isotropic, elastic material in large strains using the hyperelastic formulation. The constitutive law derived from a strain energy function that is a function of the deformation gradient tensor <math>\mathbf{F}</math>.  


Regarding to the objectivity conditions and using the representation theorem,strain energy is represented by the invariants of a strain tensor, such as the left Cauchy-Green strain tensor.  
Regarding to the objectivity conditions and using the representation theorem, the strain energy function is a function of the invariants of a strain tensor, such as the left Cauchy-Green strain tensor. In the following, it is represented by its representation to volumetric/deviatoric expression:


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>W ={G_{1} \over 2 } (\bar I_{1}-3)+{G_{2} \over 2 }(\bar I_{2}-3)+{K\over 2 }(J-1)^2 </math>
<math>W ={K\over 2 }(J-1)^2 + {G_{1} \over 2 } (\bar I_{1}-3) + {G_{2} \over 2 }(\bar I_{2}-3)</math>




Line 15: Line 15:
<math>\bar I_{2} ={1 \over 2} (\bar I_{1}^2-{{B_{xx}^2+B_{yy}^2+B_{zz}^2+2B_{xy}^2+2B_{xz}^2+2B_{yz}^2} \over J^{2/3}}) </math>
<math>\bar I_{2} ={1 \over 2} (\bar I_{1}^2-{{B_{xx}^2+B_{yy}^2+B_{zz}^2+2B_{xy}^2+2B_{xz}^2+2B_{yz}^2} \over J^{2/3}}) </math>


For low strains, this material is equivalent for a linear elastic, isotropic material with shear modulus G1 + G2 and bulk modulus K. If G2 = 0, the material is a neo-Hookean material. See below for an alternate compressibility terms. Some hyperelastic rubber models assume incompressible materials, which corresponds to K → ∞; such models do not work in dynamic code (because wave speed is infinite).
In low strains, this material is equivalent to a linear elastic, isotropic material with shear modulus G = G1 + G2 and bulk modulus K. If G2 = 0, the material is a neo-Hookean material. See below for an alternate compressibility terms. Some hyperelastic rubber models assume incompressible materials, which corresponds to K → ∞; such models do not work in dynamic code (because wave speed is infinite).


The Cauchy (or true stress) is found by differentiating the strain energy to get
The Cauchy (or true stress) stress tensor is determined by differentiating the strain energy function. It is represented here by the addition of the spheric (pressure) and the deviatoric stress tensors, <math> \mathbf{\sigma} = p \mathbf{I}  + \bar \mathbf{\sigma} </math> given by:


<math> \mathbf{\sigma} ={G_{1} \over J^{5/3} } (\mathbf{B}-{I_{1} \over3}\mathbf{I})+{G_{2} \over J^{7/3}} (I_{1}    \mathbf{B}-\mathbf{B^2}-{2I_{2} \over3}\mathbf{I})+K(J-1)\mathbf{I}</math>
<math> \mathbf{\sigma} =K(J-1)\mathbf{I} + {G_{1} \over J^{5/3} } (\mathbf{B}-{I_{1} \over3}\mathbf{I}) + {G_{2} \over J^{7/3}} (I_{1}    \mathbf{B}-\mathbf{B^2}-{2I_{2} \over3}\mathbf{I})</math>




where I = J 2/3 I ̄ and I = J 4/3 I ̄ . The stress components can be divided into pressure,
where <math>  I_{1} = J^{2/3} \bar I_{1} </math>  and <math>  I_{2} = J^{4/3} \bar I_{2} </math> .


== Material Properties ==


deviatoric stress, s = σ + P, whichexplicitly evaluate to:
Although deformation properties of an isotropic [[Material Models|MPM material]] (or [[FEA Material Models|FEA material]]) can be defined by any two of &lambda;, K, G, E, and &nu;, this material's properties can only be defined by specifying any two (and exactly two) of E, G, and &nu;. Those three and other properties for isotropic [[Material Models|MPM material]] (or [[FEA Material Models|FEA material]]) are:
 
{| class="wikitable"
|-
! Property !! Description !! Units !! Default
|-
| K || Bulk modulus || MPa || none
|-
| <math>G_{1}</math>, <math>G_{2}</math> || Shear modulus || MPa || none
|-
| alpha || Thermal expansion coefficient || ppm/M || 40
|}

Revision as of 16:07, 15 September 2013

Constitutive Law

The Mooney-Rivlin material Mooney-Rivlin is an isotropic, elastic material in large strains using the hyperelastic formulation. The constitutive law derived from a strain energy function that is a function of the deformation gradient tensor [math]\displaystyle{ \mathbf{F} }[/math].

Regarding to the objectivity conditions and using the representation theorem, the strain energy function is a function of the invariants of a strain tensor, such as the left Cauchy-Green strain tensor. In the following, it is represented by its representation to volumetric/deviatoric expression:

      [math]\displaystyle{ W ={K\over 2 }(J-1)^2 + {G_{1} \over 2 } (\bar I_{1}-3) + {G_{2} \over 2 }(\bar I_{2}-3) }[/math]


where [math]\displaystyle{ G_{1} }[/math], [math]\displaystyle{ G_{2} }[/math] and K are material properties, [math]\displaystyle{ \bar I_{1} }[/math], [math]\displaystyle{ \bar I_{2} }[/math] and J are the invariant of the chosen strain tensor, with J=det F and

[math]\displaystyle{ \bar I_{1} ={B_{xx}+B_{yy}+B_{zz} \over J^{2/3}} }[/math]

[math]\displaystyle{ \bar I_{2} ={1 \over 2} (\bar I_{1}^2-{{B_{xx}^2+B_{yy}^2+B_{zz}^2+2B_{xy}^2+2B_{xz}^2+2B_{yz}^2} \over J^{2/3}}) }[/math]

In low strains, this material is equivalent to a linear elastic, isotropic material with shear modulus G = G1 + G2 and bulk modulus K. If G2 = 0, the material is a neo-Hookean material. See below for an alternate compressibility terms. Some hyperelastic rubber models assume incompressible materials, which corresponds to K → ∞; such models do not work in dynamic code (because wave speed is infinite).  The Cauchy (or true stress) stress tensor is determined by differentiating the strain energy function. It is represented here by the addition of the spheric (pressure) and the deviatoric stress tensors, [math]\displaystyle{ \mathbf{\sigma} = p \mathbf{I} + \bar \mathbf{\sigma} }[/math] given by:

[math]\displaystyle{ \mathbf{\sigma} =K(J-1)\mathbf{I} + {G_{1} \over J^{5/3} } (\mathbf{B}-{I_{1} \over3}\mathbf{I}) + {G_{2} \over J^{7/3}} (I_{1} \mathbf{B}-\mathbf{B^2}-{2I_{2} \over3}\mathbf{I}) }[/math]


where [math]\displaystyle{ I_{1} = J^{2/3} \bar I_{1} }[/math] and [math]\displaystyle{ I_{2} = J^{4/3} \bar I_{2} }[/math] .

Material Properties

Although deformation properties of an isotropic MPM material (or FEA material) can be defined by any two of λ, K, G, E, and ν, this material's properties can only be defined by specifying any two (and exactly two) of E, G, and ν. Those three and other properties for isotropic MPM material (or FEA material) are:

Property Description Units Default
K Bulk modulus MPa none
[math]\displaystyle{ G_{1} }[/math], [math]\displaystyle{ G_{2} }[/math] Shear modulus MPa none
alpha Thermal expansion coefficient ppm/M 40