Fast numerical evaluation of flow fields with vortex cells
Fast numerical evaluation of flow fields with vortex cells
A vortex cell (in this paper) is an aerodynamically shaped cavity in the surface of a body, for example a wing, designed specially to trap the separated vortex within it, thus preventing large-scale unsteady vortex shedding from the wing. Vortex stabilisation can be achieved either by the special geometry, as has already been done experimentally, or by a system of active control. In realistic conditions the boundary and mixing layers in the vortex cell are always turbulent. In the present study a model for calculating the flow in a vortex cell was obtained by replacing the laminar viscosity with the turbulent viscosity in the known high-Reynolds-number asymptotic theory of steady laminar flows in vortex cells. The model was implemented numerically and was shown to be faster than solving the Reynolds-aver- aged Navier–Stokes equations. An experimental facility with a vortex cell was built and experiments performed. Comparisons of the experimental results with the predictions of the model are reasonably satisfactory. The results also indicate that at least for flows in near-circular vortex cells it is sufficient to have accurate turbulence models only in thin viscous layers, while outside the viscosity should only be small enough to make the flow effectively inviscid
vortex cells, separation control, cyclic boundary layers, cavity flow
660-669
Hetsch, T.
3c399bce-3586-41e1-a93a-846b610c5ea6
Savelsberg, R.
664d2ee5-49b8-4dae-bc13-c360d57f849e
Chernyshenko, S.
5e696325-182c-49fd-be4c-622f868eec64
Castro, I.P.
66e6330d-d93a-439a-a69b-e061e660de61
September 2009
Hetsch, T.
3c399bce-3586-41e1-a93a-846b610c5ea6
Savelsberg, R.
664d2ee5-49b8-4dae-bc13-c360d57f849e
Chernyshenko, S.
5e696325-182c-49fd-be4c-622f868eec64
Castro, I.P.
66e6330d-d93a-439a-a69b-e061e660de61
Hetsch, T., Savelsberg, R., Chernyshenko, S. and Castro, I.P.
(2009)
Fast numerical evaluation of flow fields with vortex cells.
European Journal of Mechanics - B/Fluids, 28 (5), .
(doi:10.1016/j.euromechflu.2009.05.003).
Abstract
A vortex cell (in this paper) is an aerodynamically shaped cavity in the surface of a body, for example a wing, designed specially to trap the separated vortex within it, thus preventing large-scale unsteady vortex shedding from the wing. Vortex stabilisation can be achieved either by the special geometry, as has already been done experimentally, or by a system of active control. In realistic conditions the boundary and mixing layers in the vortex cell are always turbulent. In the present study a model for calculating the flow in a vortex cell was obtained by replacing the laminar viscosity with the turbulent viscosity in the known high-Reynolds-number asymptotic theory of steady laminar flows in vortex cells. The model was implemented numerically and was shown to be faster than solving the Reynolds-aver- aged Navier–Stokes equations. An experimental facility with a vortex cell was built and experiments performed. Comparisons of the experimental results with the predictions of the model are reasonably satisfactory. The results also indicate that at least for flows in near-circular vortex cells it is sufficient to have accurate turbulence models only in thin viscous layers, while outside the viscosity should only be small enough to make the flow effectively inviscid
Text
fast_numerical_evaluation_of_flow_fields_with_vortex_cells.pdf
- Accepted Manuscript
More information
Published date: September 2009
Keywords:
vortex cells, separation control, cyclic boundary layers, cavity flow
Organisations:
Aerodynamics & Flight Mechanics
Identifiers
Local EPrints ID: 71631
URI: http://eprints.soton.ac.uk/id/eprint/71631
ISSN: 0997-7546
PURE UUID: e12eb8ce-f5a6-4b0f-8243-be5ea8950248
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Date deposited: 16 Dec 2009
Last modified: 13 Mar 2024 20:37
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Contributors
Author:
T. Hetsch
Author:
R. Savelsberg
Author:
S. Chernyshenko
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