Generalized stability theory of polydisperse particle-laden flows. Part1. Channel flow

We present a generalized hydrodynamic stability theory for interacting particles in polydisperse particle-laden flows. The addition of dispersed particulate matter to a clean flow can either stabilize or destabilize the flow, depending on the particles' relaxation time-scale relative to the carrier flow time scales and the particle loading. To study the effects of polydispersity and particle interactions on the hydrodynamic stability of shear flows, we propose a new mathematical framework by combining a linear stability analysis and a discrete Eulerian sectional formulation to describe the flow and the dispersed particulate matter. In this formulation, multiple momentum and transport equations are written for each size-section of the dispersed phase, where interphase and inter-particle mass and momentum transfer are modelled as source terms in the governing equations. A new modal linear stability framework is derived by linearizing the coupled equations. Using this approach, particle-flow interactions, such as polydispersity, droplet vaporization, condensation, and coalescence, may be modelled. The method is validated with linear stability analyses of clean and monodisperse particle-laden flows. We show that the stability characteristics of a channel flow laden with particles drastically change due to polydispersity. While relatively large monodisperse particles tend to stabilize the flow, adding a second size section of a very small mass fraction of low-to-moderate Stokes number particles may significantly increase the growth rates, and for high-Reynolds numbers may destabilize flows that might have been regarded as linearly stable in the monodisperse case. These findings may apply to a vast number of fluid mechanics applications involving particle-laden flows such as atmospheric flows, environmental flows, medical applications, propulsion, and energy systems.