Please use this identifier to cite or link to this item: https://libjncir.jncasr.ac.in/xmlui/handle/10572/1967
Title: Preferential concentration driven instability of sheared gas-solid suspensions
Authors: Kasbaoui, M. Houssem
Koch, Donald L.
Subramanian, Ganesh
Desjardins, Olivier
Keywords: Mechanics
Fluids & Plasmas Physics
instability
multiphase and particle-laden flows
particle/fluid flow
Homogeneous Isotropic Turbulence
Particle-Laden Flows
Settling Velocity
2-Way Interaction
Heavy-Particles
Stability
Evolution
Bed
Issue Date: 2015
Publisher: Cambridge University Press
Citation: Journal of Fluid Mechanics
770
Kasbaoui, M. H.; Koch, D. L.; Subramanian, G.; Desjardins, O., Preferential concentration driven instability of sheared gas-solid suspensions. Journal of Fluid Mechanics 2015, 770, 85-123.
Abstract: We examine the linear stability of a homogeneous gas solid suspension of small Stokes number particles, with a moderate mass loading, subject to a simple shear flow. The modulation of the gravitational force exerted on the suspension, due to preferential concentration of particles in regions of low vorticity, in response to an imposed velocity perturbation, can lead to an algebraic instability. Since the fastest growing modes have wavelengths small compared with the characteristic length scale (U-g/Gamma) and oscillate with frequencies large compared with Gamma, U-g being the settling velocity and Gamma the shear rate, we apply the WKB method, a multiple scale technique. This analysis reveals the existence of a number density mode which travels due to the settling of the particles and a momentum mode which travels due to the cross-streamline momentum transport caused by settling. These modes are coupled at a turning point which occurs when the wavevector is nearly horizontal and the most amplified perturbations are those in which a momentum wave upstream of the turning point creates a downstream number density wave. The particle number density perturbations reach a finite, but large amplitude that persists after the wave becomes aligned with the velocity gradient. The growth of the amplitude of particle concentration and fluid velocity disturbances is characterised as a function of the wavenumber and Reynolds number (Re = U-g(2)/Gamma nu) using both asymptotic theory and a numerical solution of the linearised equations.
Description: Restricted access
URI: https://libjncir.jncasr.ac.in/xmlui/10572/1967
ISSN: 0022-1120
Appears in Collections:Research Articles (Ganesh Subramanian)

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