Journal ArticleDOI
Kinetic theories for granular flow: inelastic particles in Couette flow and slightly inelastic particles in a general flowfield
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In this paper, the authors studied the flow of an idealized granular material consisting of uniform smooth, but nelastic, spherical particles using statistical methods analogous to those used in the kinetic theory of gases.Abstract:
The flow of an idealized granular material consisting of uniform smooth, but nelastic, spherical particles is studied using statistical methods analogous to those used in the kinetic theory of gases. Two theories are developed: one for the Couette flow of particles having arbitrary coefficients of restitution (inelastic particles) and a second for the general flow of particles with coefficients of restitution near 1 (slightly inelastic particles). The study of inelastic particles in Couette flow follows the method of Savage & Jeffrey (1981) and uses an ad hoc distribution function to describe the collisions between particles. The results of this first analysis are compared with other theories of granular flow, with the Chapman-Enskog dense-gas theory, and with experiments. The theory agrees moderately well with experimental data and it is found that the asymptotic analysis of Jenkins & Savage (1983), which was developed for slightly inelastic particles, surprisingly gives results similar to the first theory even for highly inelastic particles. Therefore the ‘nearly elastic’ approximation is pursued as a second theory using an approach that is closer to the established methods of Chapman-Enskog gas theory. The new approach which determines the collisional distribution functions by a rational approximation scheme, is applicable to general flowfields, not just simple shear. It incorporates kinetic as well as collisional contributions to the constitutive equations for stress and energy flux and is thus appropriate for dilute as well as dense concentrations of solids. When the collisional contributions are dominant, it predicts stresses similar to the first analysis for the simple shear case.read more
Citations
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Journal ArticleDOI
Slow dense granular flows as a self-induced process
TL;DR: A minimum model is derived and applied to different configurations of granular shear flow based on a stress fluctuation activated process that induces fluctuations in the media that may trigger a shear at some other position.
Journal ArticleDOI
Frictional–collisional equations of motion for granular materials and their application to flow in aerated chutes
Prabhu R. Nott,R. Jackson +1 more
TL;DR: In this paper, the authors extended the equations of motion and boundary conditions for a flowing granular material to allow for drag forces resulting from relative motion of the material and interstitial air.
Journal ArticleDOI
Euler–Euler anisotropic Gaussian mesoscale simulation of homogeneous cluster‐induced gas‐particle turbulence
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Position and velocity of a large particle in a gas/solid riser using the radioactive particle tracking technique
TL;DR: In this paper, the flow behavior of the solids phase in the fully developed region of a laboratory-scale circulating fluidized bed riser was studied using an assembly of sixteen NaI detectors to determine the position of a 500 μm radioactive particle, 100 times/s.
Journal ArticleDOI
Effect of Interstitial Fluid on Particle−Particle Interactions in Kinetic Theory Approach of Dilute Turbulent Fluid−Particle Flow
Kunn Hadinoto,Jennifer S. Curtis +1 more
TL;DR: In this paper, a two-fluid model for fluid−particle turbulent flow is developed, which employs kinetic theory of dense gas concepts in describing momentum and kinetic energy transfer between colliding particles, incorporating the influence of the interstitial fluid on the random motions of the particles by introducing two distinct particle coefficients of restitution, ef and es, to characterize the inelasticity of particles colliding in a fluid and in a vacuum.
References
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Journal ArticleDOI
Equation of State for Nonattracting Rigid Spheres
TL;DR: In this paper, a new equation of state for rigid spheres has been developed from an analysis of the reduced virial series, which possesses superior ability to describe rigid-sphere behavior compared with existing equations.
Journal ArticleDOI
Experiments on a Gravity-Free Dispersion of Large Solid Spheres in a Newtonian Fluid under Shear
TL;DR: In this article, a large number of spherical grains of diameter D = 0.13 cm were sheared in Newtonian fluids of varying viscosity (water and a glycerine-water-alcohol mixture) in the annular space between two concentric drums.
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