Viscoelastic Model

Elastic materials having the capacity to dissipate the mechanical energy due to viscous effects are characterized as viscoelastic materials. For multi-axial stress state, the constitutive relation can be written as:

where e and f are the deviatoric and volumetric strains; G(t - t ) and K(t - t ) are shear and bulk relaxation functions. The relaxation functions can then be represented by the mechanical model, (shown in this figure ) which is usually referred to as a Generalized Maxwell Model having the expressions as the following:

where G 0 and K 0 are the initial shear and bulk moduli (t = 0) given by: G 0   = E/2(1+v) and K 0   = E/3(1-2v).

g i, k i, t i G, and t i K are the i-th shear and bulk moduli and corresponding times.

The effect of temperature on the material behavior is introduced through the time-temperature correspondence principle. The mathematical form of the principle is:

where g t is the reduced time and g is the shift function. The WLF (Williams-Landel-Ferry) equation is used to approximate the function:

where TO is the reference temperature which is usually picked as the Glass transition temperature; C1 and C2 are material dependent constants.

The required parameters include the following:

When defining a shear or bulk relaxation curve under the Tables & Curves tab, the first point of the curve is the G 1   or K 1   moduli at time t 1. At time t = 0, the program automatically computes G 0   or K 0 from the Elastic modulus and Poisson's ratio.

The viscoelastic material model can be used with the draft and high quality solid and thick shell elements.