Dynamics of an Elongated Bubble During Collapse

A. Crespo; J. Hernández; F. Castro; F. Manuel

Source: Journal of Fluids Engineering:;1990:;volume( 112 ):;issue: 002::page 232

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DOI: 10.1115/1.2909393

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: An analytical model is presented to describe the collapse of an elongated bubble, which appears in the core of a cavitating vortex. The flow field is assumed to be irrotational, due to a sink line. The kinematic and dynamic conditions are applied only at the tip and in the middle of the bubble surface. This simplified theory must retain losses of mechanical energy near the tips of the bubble, which are due to a microjet. In order to check the validity of this model, the irrotational flow equations have been solved numerically by using a panel method; the numerical results agree with the analytical ones and confirm the existence of the microjet at the tip. The agreement with experimental results is also good. For very slender bubbles the speed near the tips becomes very large, and this may be cause of cavitation damage. A simplified approach is proposed to explain the flow in the microjet.

keyword(s): Dynamics (Mechanics) , Bubbles , Collapse , Flow (Dynamics) , Cavitation , Vortices AND Equations ,

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Dynamics of an Elongated Bubble During Collapse

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contributor author	A. Crespo
contributor author	J. Hernández
contributor author	F. Castro
contributor author	F. Manuel
date accessioned	2017-05-08T23:32:59Z
date available	2017-05-08T23:32:59Z
date copyright	June, 1990
date issued	1990
identifier issn	0098-2202
identifier other	JFEGA4-27050#232_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/107110
description abstract	An analytical model is presented to describe the collapse of an elongated bubble, which appears in the core of a cavitating vortex. The flow field is assumed to be irrotational, due to a sink line. The kinematic and dynamic conditions are applied only at the tip and in the middle of the bubble surface. This simplified theory must retain losses of mechanical energy near the tips of the bubble, which are due to a microjet. In order to check the validity of this model, the irrotational flow equations have been solved numerically by using a panel method; the numerical results agree with the analytical ones and confirm the existence of the microjet at the tip. The agreement with experimental results is also good. For very slender bubbles the speed near the tips becomes very large, and this may be cause of cavitation damage. A simplified approach is proposed to explain the flow in the microjet.
publisher	The American Society of Mechanical Engineers (ASME)
title	Dynamics of an Elongated Bubble During Collapse
type	Journal Paper
journal volume	112
journal issue	2
journal title	Journal of Fluids Engineering
identifier doi	10.1115/1.2909393
journal fristpage	232
journal lastpage	237
identifier eissn	1528-901X
keywords	Dynamics (Mechanics)
keywords	Bubbles
keywords	Collapse
keywords	Flow (Dynamics)
keywords	Cavitation
keywords	Vortices AND Equations
tree	Journal of Fluids Engineering:;1990:;volume( 112 ):;issue: 002
contenttype	Fulltext

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