Relaxation Models for Wave Phenomena in Liquid-Vapor Bubble Flow in Channels

Z. Bilicki; E. E. Michaelides; D. Kardas

Source: Journal of Fluids Engineering:;1998:;volume( 120 ):;issue: 002::page 369

Author:

Z. Bilicki

E. E. Michaelides

D. Kardas

DOI: 10.1115/1.2820657

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: We examine wave characteristics of a liquid-vapor mixture in order to investigate certain features of the homogeneous relaxation model. The model is described by one-dimensional averaged mass, momentum, energy equations, and a rate equation. Since the homogeneous relaxation model delivers a qualitative incompatibility of numerical and experiment results of large wave propagation, it is extended so as to take into account the heat conduction in the liquid surrounding vapor bubbles. With this extension, the effects of spreading and damping of the waves in the numerical solutions are similar to those observed in the experiment. Thus, a new model is created, the homogeneous relaxation-diffusion model which contains two physical quantities—the relaxation time and macroscopic heat conduction coefficient. Both quantities are determined based on experimental data. It seems that the results obtained from the new model agree well qualitatively with the experiments.

keyword(s): Vapors , Channels (Hydraulic engineering) , Relaxation (Physics) , Bubbly flow , Wave phenomena , Equations , Heat conduction , Waves , Bubbles , Damping , Kinetic energy , Diffusion (Physics) , Wave propagation AND Mixtures ,

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Relaxation Models for Wave Phenomena in Liquid-Vapor Bubble Flow in Channels

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contributor author	Z. Bilicki
contributor author	E. E. Michaelides
contributor author	D. Kardas
date accessioned	2017-05-08T23:56:59Z
date available	2017-05-08T23:56:59Z
date copyright	June, 1998
date issued	1998
identifier issn	0098-2202
identifier other	JFEGA4-27129#369_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/120653
description abstract	We examine wave characteristics of a liquid-vapor mixture in order to investigate certain features of the homogeneous relaxation model. The model is described by one-dimensional averaged mass, momentum, energy equations, and a rate equation. Since the homogeneous relaxation model delivers a qualitative incompatibility of numerical and experiment results of large wave propagation, it is extended so as to take into account the heat conduction in the liquid surrounding vapor bubbles. With this extension, the effects of spreading and damping of the waves in the numerical solutions are similar to those observed in the experiment. Thus, a new model is created, the homogeneous relaxation-diffusion model which contains two physical quantities—the relaxation time and macroscopic heat conduction coefficient. Both quantities are determined based on experimental data. It seems that the results obtained from the new model agree well qualitatively with the experiments.
publisher	The American Society of Mechanical Engineers (ASME)
title	Relaxation Models for Wave Phenomena in Liquid-Vapor Bubble Flow in Channels
type	Journal Paper
journal volume	120
journal issue	2
journal title	Journal of Fluids Engineering
identifier doi	10.1115/1.2820657
journal fristpage	369
journal lastpage	377
identifier eissn	1528-901X
keywords	Vapors
keywords	Channels (Hydraulic engineering)
keywords	Relaxation (Physics)
keywords	Bubbly flow
keywords	Wave phenomena
keywords	Equations
keywords	Heat conduction
keywords	Waves
keywords	Bubbles
keywords	Damping
keywords	Kinetic energy
keywords	Diffusion (Physics)
keywords	Wave propagation AND Mixtures
tree	Journal of Fluids Engineering:;1998:;volume( 120 ):;issue: 002
contenttype	Fulltext

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