Pressure losses in the laminar flow of shear-thinning power-law fluids across a sudden axisymmetric expansion

A numerical investigation was carried out to study the laminar non-Newtonian flow through an axisymmetric sudden expansion having a diameter ratio of 1 to 2.6. The fluids were inelastic and shear thinning with a viscosity obeying the power law model. The recirculation length and strength and, most importantly, the local loss coefficient CI were quantified as a function of the inlet pipe Reynolds number and shear-thinning intensity. When using the generalised Reynolds number introduced by Metzner and Reed [AIChEJ 1 (1955) 434] (Regen), at low Reynolds numbers CI increased by more than 100% when n varied from 1.0 to 0.2, whereas CI decreased by more than 50% at high Reynolds numbers. However, this feature was shown to be related to the definition of the Reynolds number. A correlation between CI, Regen and n is presented at the end.

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