Non-Newtonian Power Law

The following equation describes the non-Newtonian Power Law property variation:

1. Cutoff Viscosity: This is the viscosity of the fluid as a Newtonian fluid.

2. Cutoff Strain Rate: The strain rate at which the fluid becomes Non-Newtonian.

3. Viscosity Coefficient: The viscosity of the fluid when the fluid becomes Non-Newtonian.

4. Power Law Exponent: Determines whether the fluid is shear thickening (P > 0) or shear thinning (P < 0). A Power Law Exponent of 0 is a Newtonian fluid. (The power law exponent is related to the power law index as p = n-1.)

If a viscosity cutoff is not applicable

1. Enter values for the Viscosity Coefficient and the Power Law Exponent
2. Leave the Cutoff Strain Rate at the default.
3. Make the Cutoff Viscosity = the Viscosity Coefficient.

Example:

• A non-Newtonian fluid has a viscosity = 0.0033 Pa-s.
• The Power Law index is known to be 0.62.
• This fluid does not have a cutoff viscosity, meaning that it behaves as a non-Newtonian fluid through its range of properties.

The material is defined by specifying the following properties:

To model a constant viscosity that starts to vary at a given strain rate:

• Enter this viscosity as the Cutoff Viscosity

• Enter the strain rate in the Cutoff Strain Rate

• Enter the constant k in the Viscosity Coefficient field.

For the mathematical background of non-Newtonian fluids