Analysis of Turbulent Gas-Solid Suspension Flow in a Pipe

Young Don Choi; Myung Kyoon Chung

Source: Journal of Fluids Engineering:;1983:;volume( 105 ):;issue: 003::page 329

Author:

Young Don Choi

Myung Kyoon Chung

DOI: 10.1115/1.3240999

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: The mixing length theory is extended to close the relevant momentum equations for two-phase turbulent flow at a first-order closure level. It is assumed that the mass fraction of the particles is on the order of unity, that the particle size is so small that the particles are fully suspended in the primary fluid, and that the relaxation time scale of the particles is sufficiently small compared with the time scale of the energy containing eddies so that the suspended particles are fully responsive to the fluctuating turbulent field. Bulk motion of the particles is treated as a secondary fluid flow with its own virtual viscosity. The proposed closure is applied to a fully developed gas-solid pipe flow in which the particles are assumed to be uniformly distributed across the pipe section. Predicted velocity profiles and the friction factors are in good agreement with available experimental data.

keyword(s): Flow (Dynamics) , Turbulence , Pipes , Particulate matter , Motion , Equations , Particle size , Eddies (Fluid dynamics) , Viscosity , Relaxation (Physics) , Pipe flow , Friction , Fluids , Momentum AND Fluid dynamics ,

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Analysis of Turbulent Gas-Solid Suspension Flow in a Pipe

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contributor author	Young Don Choi
contributor author	Myung Kyoon Chung
date accessioned	2017-05-08T23:15:46Z
date available	2017-05-08T23:15:46Z
date copyright	September, 1983
date issued	1983
identifier issn	0098-2202
identifier other	JFEGA4-26998#329_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/97253
description abstract	The mixing length theory is extended to close the relevant momentum equations for two-phase turbulent flow at a first-order closure level. It is assumed that the mass fraction of the particles is on the order of unity, that the particle size is so small that the particles are fully suspended in the primary fluid, and that the relaxation time scale of the particles is sufficiently small compared with the time scale of the energy containing eddies so that the suspended particles are fully responsive to the fluctuating turbulent field. Bulk motion of the particles is treated as a secondary fluid flow with its own virtual viscosity. The proposed closure is applied to a fully developed gas-solid pipe flow in which the particles are assumed to be uniformly distributed across the pipe section. Predicted velocity profiles and the friction factors are in good agreement with available experimental data.
publisher	The American Society of Mechanical Engineers (ASME)
title	Analysis of Turbulent Gas-Solid Suspension Flow in a Pipe
type	Journal Paper
journal volume	105
journal issue	3
journal title	Journal of Fluids Engineering
identifier doi	10.1115/1.3240999
journal fristpage	329
journal lastpage	334
identifier eissn	1528-901X
keywords	Flow (Dynamics)
keywords	Turbulence
keywords	Pipes
keywords	Particulate matter
keywords	Motion
keywords	Equations
keywords	Particle size
keywords	Eddies (Fluid dynamics)
keywords	Viscosity
keywords	Relaxation (Physics)
keywords	Pipe flow
keywords	Friction
keywords	Fluids
keywords	Momentum AND Fluid dynamics
tree	Journal of Fluids Engineering:;1983:;volume( 105 ):;issue: 003
contenttype	Fulltext

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