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Main Authors: Li, Heng, Botto, Lorenzo
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.17392
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author Li, Heng
Botto, Lorenzo
author_facet Li, Heng
Botto, Lorenzo
contents Settling velocity statistics for dilute, non-Brownian suspensions of polydisperse spheres having a log-normal size distribution are analysed by Stokesian Dynamics, as a function of the total volume fraction and width of the size distribution. Several hundred instantaneous configurations are averaged to obtain reliable statistics. Average velocities for each particle class are compared to the models proposed by Batchelor, Richardson & Zaki, Davis & Gecol, and Masliyah-Lockett-Bassoon (MLB). Batchelor's model is shown to give reasonably accurate predictions when the volume fraction is within 5%. Because of its complexity, this model is however hardly used in practice, so lower-order models are needed. We found that while the other hindered settling models can give reasonably accurate predictions of the velocity of the largest particles, all of them overestimate - in certain cases by a large margin - the velocity of the smaller particles. By computing the fluid-particle velocity slip for each particle class and using Batchelor's model, we explain why predicting the lower tail of the particle size distribution is challenging, and propose possible avenues for model improvement. The analysis of velocity fluctuations suggest quantitative similarities between velocity fluctuations in monodisperse and polydisperse suspensions.
format Preprint
id arxiv_https___arxiv_org_abs_2404_17392
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hindered settling of log-normally distributed particulate suspensions: theoretical models vs. Stokesian simulations
Li, Heng
Botto, Lorenzo
Fluid Dynamics
Settling velocity statistics for dilute, non-Brownian suspensions of polydisperse spheres having a log-normal size distribution are analysed by Stokesian Dynamics, as a function of the total volume fraction and width of the size distribution. Several hundred instantaneous configurations are averaged to obtain reliable statistics. Average velocities for each particle class are compared to the models proposed by Batchelor, Richardson & Zaki, Davis & Gecol, and Masliyah-Lockett-Bassoon (MLB). Batchelor's model is shown to give reasonably accurate predictions when the volume fraction is within 5%. Because of its complexity, this model is however hardly used in practice, so lower-order models are needed. We found that while the other hindered settling models can give reasonably accurate predictions of the velocity of the largest particles, all of them overestimate - in certain cases by a large margin - the velocity of the smaller particles. By computing the fluid-particle velocity slip for each particle class and using Batchelor's model, we explain why predicting the lower tail of the particle size distribution is challenging, and propose possible avenues for model improvement. The analysis of velocity fluctuations suggest quantitative similarities between velocity fluctuations in monodisperse and polydisperse suspensions.
title Hindered settling of log-normally distributed particulate suspensions: theoretical models vs. Stokesian simulations
topic Fluid Dynamics
url https://arxiv.org/abs/2404.17392