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Sound waves in monodisperse gas-particle or vapour-droplet mixtures

Published online by Cambridge University Press:  21 April 2006

N. A. Gumerov ,
A.I. Ivandaev  and
R. I. Nigmatulin
N. A. Gumerov
Affiliation:
Department of Mechanics and Mathematics of M. V. Lomonosov Moscow University, Moscow, 117234, USSR
A.I. Ivandaev
Affiliation:
Institute of North Problem Development of the USSR Academy Siberian Branch, Tumen, Post Box 2774, 625003, USSR
R. I. Nigmatulin
Affiliation:
Institute of North Problem Development of the USSR Academy Siberian Branch, Tumen, Post Box 2774, 625003, USSR
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Abstract

A brief review of the relevant papers and an examination of the current status of research in the field of the acoustics of gas-particle suspensions are given. Non-stationary momentum, mass and energy transfer processes between a gas (vapour) and dispersed particles (droplets) under high-frequency acoustic perturbations are considered. A comparative evaluation of characteristic times and temperature differences for gas-particle and vapour-droplet mixtures subjected to acoustic perturbation is given. General dispersion equations to describe the propagation of weak monochromatic waves for a wide range of frequencies complying with the requirements of the acoustic homogeneity of the medium are derived. Frequency dependences of propagation velocity and attenuation coefficient of weak waves in water vapour-droplet mixtures are investigated. Frequency ranges are indicated over which different types of approximate theories are valid.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 193 , August 1988 , pp. 53 - 74
Copyright
© 1988 Cambridge University Press

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