A generalized k-epsilon model for turbulence modulation in fluid-particle flows

TL;DR

This paper introduces a generalized $k$-$psilon$ turbulence model that captures how particles of different sizes either augment or suppress turbulence in fluid flows, considering various particle types and flow conditions.

Contribution

A revised phenomenological $k$-$psilon$ model incorporating vortex shedding and particle-fluid interactions for diverse particle sizes and densities.

Findings

Large particles (>10% of turbulence scale) augment turbulence via vortex shedding.

Small particles suppress turbulence mainly through drag and dissipation.

Transition from suppression to augmentation occurs around D/l=0.1 across many conditions.

Abstract

A large amount of published data show that particles with diameter above 10\% of the turbulence integral length scale ($D/l >0.1$) tend to increase the turbulent kinetic energy of the carrier fluid above the single-phase value, and smaller particles tend to suppress it. A revised phenomenological model of the $k-\epsilon$ type was developed to reproduce these effects with the correct asymptotic limit of no turbulence modulation for small particles, and augmentation for larger diameter solids. Particle-kinetic theory was used to derive the work exchanged between the particles and the fluid due to both drag and added mass forces to accommodate any particle/fluid density ratios including bubbles, droplets and heavy solids. For the larger particles, we devised a new model for vortex shedding induced by the slip between the particles and the turbulent flow, due to particle inertia. Simple approximate formulae for the turbulence modulation were obtained through asymptotic analysis. The overall effect for solid particles is that augmentation for large diameter solids is due to vortex shedding, and turbulence suppression for small diameters is due to mainly to turbulent drag forces and extra fluid dissipation. The transition from suppression to augmentation around $D/l = 0.1$ is a robust feature for a wide range of particle Reynolds and Stokes numbers, but we could not prove this to be a general relation on a theoretical basis. Indeed, bubbles and droplets may not display turbulence augmentation at all for the larger diameters due to moderate turbulence levels needed to prevent breakup, and the velocity difference between particles and fluid may therefore be too low for vortex shedding to occur. On the basis of the model we find that some data for solids in vertical gas flow show very large turbulence augmentation that can only be due to gravitational settling.