Exploring separation and reattachment in shear-thinning suspensions through pipe-wall ultrasound measurements
Giuseppe Rosi, Moira Barnes, Frieder Kaiser, David Rival

TL;DR
This study explores how shear-thinning suspensions behave in turbulent flow using ultrasound and pressure measurements.
Contribution
The paper introduces new insights into how suspended particles affect shear-layer reattachment in non-Newtonian fluids.
Findings
Shear-thinning suspensions show consistently short reattachment lengths regardless of Reynolds number.
Suspended particles in the fluid promote rapid momentum transfer toward the wall.
Pressure and velocity profiles differ significantly between single-phase and suspension flows.
Abstract
To better understand how turbulent flow structures develop within shear-thinning suspensions (STSs), we investigate the behavior of a shear layer forming within an STS downstream of a sudden expansion with an expansion ratio of 0.5. Specifically, the shear-layer reattachment behavior downstream of an axisymmetric expansion is characterized through ultrasound imaging velocimetry (UIV) and through pressure measurements, and the observed behavior is used to surmise how the shear layer is modified within the STS. Four fluids are investigated, which include pure water, as well as three 1750 ppm xanthan-gum-in-water solutions mixed with non-reactive mineral microspheres at volume fractions of 0%, 15%, and 30%. Wall-pressure measurements were collected through pressure taps located at 0h to 25.8h downstream of the expansion with subsequent UIV measurements collected from 1h to 9h downstream of…
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Taxonomy
TopicsRheology and Fluid Dynamics Studies · Granular flow and fluidized beds · Drilling and Well Engineering
