4.4 Article

Stochastic model for the residence time of solid particles in turbulent Rayleigh-Benard flow

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PHYSICAL REVIEW FLUIDS
卷 8, 期 2, 页码 -

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AMER PHYSICAL SOC
DOI: 10.1103/PhysRevFluids.8.024307

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This paper develops a simple stochastic model based on direct numerical simulation to accurately describe the residence times of particles in a particle-laden turbulent flow. The model takes into account the competition between gravity settling and particle-turbulence interaction. Despite its simplicity, the model provides quantitatively accurate predictions of the distribution of particle residence times in the flow. The independent roles of gravity and inertia in governing these residence times are also investigated by varying the Stokes numbers and settling velocities.
The Pi Chamber generates moist turbulent Rayleigh-Benard flow in order to replicate steady-state cloud conditions. We take inspiration from this setup and consider a particleladen, convectively driven turbulent flow using direct numerical simulation. The aim of our paper is to develop a simple stochastic model that can accurately describe the residence times of the particles in the flow, this time being determined by the complex competition between the gravitational settling of the particles, and the interaction of the particles with the turbulent structures in the flow. A simple conceptual picture underlies the stochastic model, namely that the particles take repeated trips between the top and bottom boundaries, driven by the convective cells that occur in Rayleigh-Benard turbulence, and that their residence times are determined by the time it takes to complete one of these trips, which varies from one trip to another, and the probability of falling out to the bottom boundary after each trip. Despite the simplicity of the model, it yields quantitatively accurate predictions of the distribution of the particle residence times in the flow. We independently vary the Stokes numbers and settling velocities in order to shed light on the independent roles that gravity and inertia play in governing these residence times.

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