Creep Models

Creep is a time dependent strain produced under a state of constant stress. Creep is observed in most engineering materials especially metals at elevated temperatures, high polymer plastics, concrete, and solid propellant in rocket motors. Since creep effects take long time to develop, they are usually neglected in dynamic analysis.

Creep curve is a graph between strain versus time. Three different regimes can be distinguished in a creep curve; primary, secondary, and tertiary (see the following figure). Usually primary and secondary regimes are of interest.

Two creep laws based on an “Equation of State” approach are implemented. Each law defines an expression for the uniaxial creep strain in terms of the uniaxial stress and time.

Classical Power Law for Creep (Bailey-Norton law)

where:

T = Temperature (Kelvin) (= input temperature + reference temperature + offset temperature)

CT = A material constant defining the creep temperature-dependency

The classical power law for creep represents primary and secondary creep regimes in one formula. Tertiary creep regime is not considered. “t” is the current real (not pseudo) time and s is the total uniaxial stress at time t.

To extend these laws to multiaxial creep behavior, the following assumptions are made:

• The uniaxial creep law remains valid if the uniaxial creep strain and the uniaxial stress are replaced by their effective values.

• Material is isotropic

• The creep strains are incompressible

For a numerical creep analysis, where cyclic loading may be applied, based on the strain hardening rule, the current creep strain rates are expressed as a function of the current stress and the total creep strain:

where: