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Hyperelastic Blatz - Ko Model

The Blatz-Ko strain energy density function is useful for modeling compressible polyurethane foam type rubbers and can be expressed as:

where G is the shear modulus under infinitesimal deformations = E/2(1+ n ), E is Young's modulus of elasticity, n is Poisson's ratio, I k is the invariants of C =I k ( C ), C is the Cauchy-Green deformation tensor = 2 e + I, e is the Lagrangian strain tensor, and I is the Identity matrix.

 

The above expression, contains only one material constant G. Since n = 0.25 for the Blatz-Ko model, the only material property which is considered is the Young's modulus. Thus,

The Blatz-Ko model is currently supported by solid elements only (draft and high quality) elements.

The selected Blatz-Ko model is a simplified form of the expression obtained by Blatz and Ko (1962) to model the deformation of a highly compressible polyurethane foam rubber. The strain energy was approximated by the following expression:

where

A specific form of this three-parameter family of elastic potential was later proposed in which the following values of the constants a, b, and n were assumed: b = 0, n = 0.25, and a = 0.5.



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