Development of a large-eddy simulation open channel code
Development of a large-eddy simulation open channel code
Describes further development of a 3D finite difference code written to model turbulent flows in an open channel with a moving free surface. The code has been developed so that the computational domain can have side-walls and/or periodic directions and that the flow may also be buoyancy driven. Either a full simulation or large eddy simulation (LES) of the turbulence can be performed. Results are presented of a simulation of periodic streamwise flow in an open channel with parallel side-walls and also of a thermal jet into an open tank. Both simulations were carried out on a UNIX workstation using resolutions that enable the results to be viewed within an “engineering context”. The LES application demands numerical approximations which conserve mass, momentum and total energy with high precision, and which permit wave motion with very little numerical dispersion or dissipation. The free surface is tracked using a split-merge technique which combines the volume of fluid (VOF) and height function methods in a way that is conservative
6-17
Shi, J.
5143ffd8-6833-4ed0-b248-667c018bf98a
Thomas, T.G.
bccfa8da-6c8b-4eec-b593-00587d3ce3cc
Williams, J.J.R.
00bddc69-411c-4267-98d9-0503b837ccda
1999
Shi, J.
5143ffd8-6833-4ed0-b248-667c018bf98a
Thomas, T.G.
bccfa8da-6c8b-4eec-b593-00587d3ce3cc
Williams, J.J.R.
00bddc69-411c-4267-98d9-0503b837ccda
Shi, J., Thomas, T.G. and Williams, J.J.R.
(1999)
Development of a large-eddy simulation open channel code.
International Journal of Numerical Methods for Heat and Fluid Flow, 9 (1), .
(doi:10.1108/09615539910251077).
Abstract
Describes further development of a 3D finite difference code written to model turbulent flows in an open channel with a moving free surface. The code has been developed so that the computational domain can have side-walls and/or periodic directions and that the flow may also be buoyancy driven. Either a full simulation or large eddy simulation (LES) of the turbulence can be performed. Results are presented of a simulation of periodic streamwise flow in an open channel with parallel side-walls and also of a thermal jet into an open tank. Both simulations were carried out on a UNIX workstation using resolutions that enable the results to be viewed within an “engineering context”. The LES application demands numerical approximations which conserve mass, momentum and total energy with high precision, and which permit wave motion with very little numerical dispersion or dissipation. The free surface is tracked using a split-merge technique which combines the volume of fluid (VOF) and height function methods in a way that is conservative
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Published date: 1999
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Local EPrints ID: 72098
URI: http://eprints.soton.ac.uk/id/eprint/72098
ISSN: 0961-5539
PURE UUID: 7af51cf9-743c-494c-bb38-74ae50a32c83
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Date deposited: 21 Jan 2010
Last modified: 13 Mar 2024 20:59
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Author:
J. Shi
Author:
T.G. Thomas
Author:
J.J.R. Williams
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