Structural Inhomogeneity and Effects of Separation by Size and Density in Gravity Flow of Granular Materials

Structural Inhomogeneity and Effects of Separation by Size and Density in Gravity Flow of Granular Materials

The authors have substantiated the expediency of representing the effect of separation of particles as a result of the conjugation of phenomena that are caused by the inhomogeneity of a granular medium and the spatial structural heterogeneity of a shear flow. With the general separation-dynamics mod...

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Bibliographic Details
Published in:Journal of engineering physics and thermophysics Vol. 95; no. 2; pp. 484 - 494
Main Authors: Dolgunin, V. N., Kudi, A. N., Tarakanov, A. G.
Format: Journal Article
Language:English
Published: New York Springer US 01-03-2022
Springer
Springer Nature B.V
Subjects:
Analysis
Classical Mechanics
Complex Systems
Conjugation
Density
Engineering
Engineering Thermodynamics
Fluid dynamics
Granular materials
Granular media
Heat and Mass Transfer
Heat and Mass Transfer in Dispersed and Porous Media
Heterogeneity
Industrial Chemistry/Chemical Engineering
Inhomogeneity
Separation
Shear flow
Thermodynamics
separation by size and density
rapid gravity flow
structural inhomogeneity
migration
granular material
segregation
quasi-diffusion
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Summary:The authors have substantiated the expediency of representing the effect of separation of particles as a result of the conjugation of phenomena that are caused by the inhomogeneity of a granular medium and the spatial structural heterogeneity of a shear flow. With the general separation-dynamics model taking account of separation, convection, and mixing flows, regions of relative values of particle size and density have been determined, in which the dominance of the separation flows due to the local and spatial inhomogeneity of the granular-medium’s rapid gravity flow is noted. It has been established that the boundary of the regions of dominance of separation flows with a fundamentally different physical nature which is determined by hydrodynamics and diffusion kinetics is near the equilibrium line of inhomogeneous-particle masses.
ISSN:1062-0125
1573-871X
DOI:10.1007/s10891-022-02505-y