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Stress-induced cavitation for the streaming motion of a viscous liquid past a sphere

Stress-induced cavitation for the streaming motion of a viscous liquid past a sphere
Stress-induced cavitation for the streaming motion of a viscous liquid past a sphere

The theory of stress-induced cavitation is applied here to the problem of cavitation of a viscous liquid in the streaming flow past a stationary sphere. This theory is a revision of the pressure theory which states that a flowing liquid will cavitate when and where the pressure drops below a cavitation threshold, or breaking strength, of the liquid. In the theory of stress-induced cavitation the liquid will cavitate when and where the maximum tensile stress exceeds the breaking strength of the liquid. For example, liquids at atmospheric pressure which cannot withstand tension will cavitate when and where additive tensile stresses due to motion exceed one atmosphere. A cavity will open in the direction of the maximum tensile stress, which is 45° from the plane of shearing in pure shear of a Newtonian fluid. This maximum tension criterion is applied here to analyse the onset of cavitation for the irrotational motion of a viscous fluid, the special case imposed by the limit of very low Reynolds numbers and the fluid flow obtained from the numerical solution of the Navier-Stokes equations. The analysis leads to a dimensionless expression for the maximum tensile stress as a function of position which depends on the cavitation and Reynolds numbers. The main conclusion is that at a fixed cavitation number the extent of the region of flow at risk to cavitation increases as the Reynolds number decreases. This prediction that more viscous liquids at a fixed cavitation number are at greater risk of cavitation seems not to be addressed, affirmed nor denied, in the cavitation literature known to us.

0022-1120
381-411
Padrino, J.C.
961f9d2a-ee9d-4619-a267-2bf098612978
Joseph, D.D.
fda3580e-d34a-488d-b4fb-ba1f10de1020
Funada, T.
010aba83-2810-4b94-b1a9-bb87431b9a89
Wang, J.
a43da73a-4363-4f33-8310-08913e7f6648
Sirignano, W.A.
79000a2e-12f7-4aba-b718-07c0c259b203
Padrino, J.C.
961f9d2a-ee9d-4619-a267-2bf098612978
Joseph, D.D.
fda3580e-d34a-488d-b4fb-ba1f10de1020
Funada, T.
010aba83-2810-4b94-b1a9-bb87431b9a89
Wang, J.
a43da73a-4363-4f33-8310-08913e7f6648
Sirignano, W.A.
79000a2e-12f7-4aba-b718-07c0c259b203

Padrino, J.C., Joseph, D.D., Funada, T., Wang, J. and Sirignano, W.A. (2007) Stress-induced cavitation for the streaming motion of a viscous liquid past a sphere. Journal of Fluid Mechanics, 578, 381-411. (doi:10.1017/S002211200700506X).

Record type: Article

Abstract

The theory of stress-induced cavitation is applied here to the problem of cavitation of a viscous liquid in the streaming flow past a stationary sphere. This theory is a revision of the pressure theory which states that a flowing liquid will cavitate when and where the pressure drops below a cavitation threshold, or breaking strength, of the liquid. In the theory of stress-induced cavitation the liquid will cavitate when and where the maximum tensile stress exceeds the breaking strength of the liquid. For example, liquids at atmospheric pressure which cannot withstand tension will cavitate when and where additive tensile stresses due to motion exceed one atmosphere. A cavity will open in the direction of the maximum tensile stress, which is 45° from the plane of shearing in pure shear of a Newtonian fluid. This maximum tension criterion is applied here to analyse the onset of cavitation for the irrotational motion of a viscous fluid, the special case imposed by the limit of very low Reynolds numbers and the fluid flow obtained from the numerical solution of the Navier-Stokes equations. The analysis leads to a dimensionless expression for the maximum tensile stress as a function of position which depends on the cavitation and Reynolds numbers. The main conclusion is that at a fixed cavitation number the extent of the region of flow at risk to cavitation increases as the Reynolds number decreases. This prediction that more viscous liquids at a fixed cavitation number are at greater risk of cavitation seems not to be addressed, affirmed nor denied, in the cavitation literature known to us.

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e-pub ahead of print date: 26 April 2007
Published date: 10 May 2007
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Identifiers

Local EPrints ID: 510675
URI: http://eprints.soton.ac.uk/id/eprint/510675
DOI: doi:10.1017/S002211200700506X
ISSN: 0022-1120
PURE UUID: 1fdc5194-1160-44a9-933d-101cb6efaa12
ORCID for J.C. Padrino: ORCID iD orcid.org/0000-0002-6373-3469

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Date deposited: 16 Apr 2026 16:39
Last modified: 17 Apr 2026 02:11

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Contributors

Author: J.C. Padrino ORCID iD
Author: D.D. Joseph
Author: T. Funada
Author: J. Wang
Author: W.A. Sirignano

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