Carreau fluid explained

In fluid dynamics, a Carreau fluid is a type of generalized Newtonian fluid (named after Pierre Carreau) where viscosity,

\mu_{\operatorname{eff}

}, depends upon the shear rate,

•

\gamma

, by the following equation:

\mu_{\operatorname{eff}

}(\dot \gamma) = \mu_ + (\mu_0 - \mu_) \left(1+\left(\lambda \dot \gamma\right) ^2 \right) ^

Where:

\mu₀

\mu_{\operatorname{inf}

and

are material coefficients:

\mu₀

is the viscosity at zero shear rate (Pa.s),

\mu_{\operatorname{inf}

} is the viscosity at infinite shear rate (Pa.s),

is the characteristic time (s) and

power index.

The dynamics of fluid motions is an important area of physics, with many important and commercially significant applications.

Computers are often used to calculate the motions of fluids, especially when the applications are of a safety critical nature.

Shear rates

•

\gamma

\ll1/λ

) a Carreau fluid behaves as a Newtonian fluid with viscosity

\mu₀

•

\gamma

\gtrsim1/λ

), a Carreau fluid behaves as a Power-law fluid.

and the infinite shear-rate viscosity

\mu_{\operatorname{inf}

} , a Carreau fluid behaves as a Newtonian fluid again with viscosity

\mu_{\operatorname{inf}

} .