Transient flows and migration in granular suspensions: key role of Reynolds-like dilatancy

We investigate the transient dynamics of a sheared suspension of neutrally buoyant particles in pressure-imposed rheology configuration, subject to a sudden change in shear rate or external pressure. Discrete element method simulations show that, depending on the flow parameters (particle and system...

Full description

Saved in:
Bibliographic Details
Published inJournal of fluid mechanics Vol. 949
Main Authors Athani, S., Metzger, B., Forterre, Y., Mari, R.
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 25.10.2022
Cambridge University Press (CUP)
Subjects
Avalanches
Compaction
Condensed Matter
Dilatancy
Dilation
Dimensional analysis
Discrete element method
Engineering Sciences
External pressure
Fluid pressure
Fluids mechanics
Jamming
JFM Papers
Landslides
Mathematical models
Mechanics
Parameters
Physics
Pore pressure
Pressure
Pressure gradients
Rheological properties
Rheology
Shear
Shear rate
Shear thickening (liquids)
Soft Condensed Matter
Steady state
Thickening
Unsteady flow
particle/fluid flow
Stokesian dynamics
suspensions
Online AccessGet full text

Cover

More Information
Summary:We investigate the transient dynamics of a sheared suspension of neutrally buoyant particles in pressure-imposed rheology configuration, subject to a sudden change in shear rate or external pressure. Discrete element method simulations show that, depending on the flow parameters (particle and system size, initial volume fraction), the early stress response of the suspension may differ strongly from the prediction of the suspension balance model based on the steady-state rheology. We show that a two-phase model incorporating the Reynolds-like dilatancy law of Pailha & Pouliquen (J. Fluid Mech., vol. 633, 2009, pp. 115–135), which prescribes the dilation rate of the suspension over a strain scale $\gamma _0$, captures quantitatively the suspension dilation/compaction over the whole range of parameters investigated. Together with the Darcy flow induced by the pore pressure gradient during dilation or compaction, this Reynolds-like dilatancy implies that the early stress response of the suspension is non-local, with a non-local length scale $\ell$ that scales with the particle size and diverges algebraically at jamming. In regions affected by $\ell$, the stress level is fixed, not by the steady-state rheology, but by the Darcy fluid pressure gradient resulting from the dilation/compaction rate. Our results extend the validity of the Reynolds-like dilatancy flow rule, initially proposed for jammed suspensions, to flowing suspension below the critical volume fraction at which the suspension jams, thereby providing a unified framework to describe dilation and shear-induced migration. They pave the way for understanding more complex unsteady flows of dense suspensions, such as impacts, transient avalanches or the impulsive response of shear-thickening suspensions.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2022.741