A numerical investigation of impulsively generated vortical structures in deep and shallow fluid layers
A numerical investigation of impulsively generated vortical structures in deep and shallow fluid layers
The evolution and formation of large-scale turbulent coherent structures induced by an impulsive jet between non-deformable stress-free layers are investigated via direct numerical simulation at a jet Reynolds number of 1250. The ratio of the initial size of the vortex to the domain depth is varied to study the influence of the bounding surface confinement. A non-conservative body force is applied to the governing equations to represent the momentum source. During the forcing period, the coherent structure appears in the form of a leading vortex ring together with a trailing jet, and breaks down to turbulence due to an instability very similar to the Widnall instability before interacting with the free surface. The input parameters (the momentum flux J, the forcing period ?t f , and the domain depth h) can be grouped together as the confinement number C = J 1/2?t f /h 2 to parameterise the intensity and strength of the eddy signature at the free surface. Increasing the confinement number corresponds to reducing the ratio of the domain depth to the initial size of the vortex, which leads to a linear increase in the maximum amplitude of the surface signature in terms of the surface eddy strength. A dipole forms for values of C greater than about unity, even though the eddy signature appears at the free surface for all the confinement numbers considered
Rojanaratanangkule, Watchapon
f6c3ad99-4077-4429-848e-bb317df26d9a
Thomas, T. Glyn
bccfa8da-6c8b-4eec-b593-00587d3ce3cc
Coleman, Gary
ea3639b9-c533-40d7-9edc-3c61246b06e0
2014
Rojanaratanangkule, Watchapon
f6c3ad99-4077-4429-848e-bb317df26d9a
Thomas, T. Glyn
bccfa8da-6c8b-4eec-b593-00587d3ce3cc
Coleman, Gary
ea3639b9-c533-40d7-9edc-3c61246b06e0
Rojanaratanangkule, Watchapon, Thomas, T. Glyn and Coleman, Gary
(2014)
A numerical investigation of impulsively generated vortical structures in deep and shallow fluid layers.
Physics of Fluids, 26 (2), [25108].
(doi:10.1063/1.4864443).
Abstract
The evolution and formation of large-scale turbulent coherent structures induced by an impulsive jet between non-deformable stress-free layers are investigated via direct numerical simulation at a jet Reynolds number of 1250. The ratio of the initial size of the vortex to the domain depth is varied to study the influence of the bounding surface confinement. A non-conservative body force is applied to the governing equations to represent the momentum source. During the forcing period, the coherent structure appears in the form of a leading vortex ring together with a trailing jet, and breaks down to turbulence due to an instability very similar to the Widnall instability before interacting with the free surface. The input parameters (the momentum flux J, the forcing period ?t f , and the domain depth h) can be grouped together as the confinement number C = J 1/2?t f /h 2 to parameterise the intensity and strength of the eddy signature at the free surface. Increasing the confinement number corresponds to reducing the ratio of the domain depth to the initial size of the vortex, which leads to a linear increase in the maximum amplitude of the surface signature in terms of the surface eddy strength. A dipole forms for values of C greater than about unity, even though the eddy signature appears at the free surface for all the confinement numbers considered
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Accepted/In Press date: January 2014
e-pub ahead of print date: 13 February 2014
Published date: 2014
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 371753
URI: http://eprints.soton.ac.uk/id/eprint/371753
ISSN: 1070-6631
PURE UUID: c5b697f9-8d92-4cca-8e15-008c0b21b4b0
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Date deposited: 14 Nov 2014 11:30
Last modified: 14 Mar 2024 18:25
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Author:
Watchapon Rojanaratanangkule
Author:
T. Glyn Thomas
Author:
Gary Coleman
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