Semi-span wind tunnel testing without conventional peniche
Semi-span wind tunnel testing without conventional peniche
Low-speed wind tunnel tests of a flexible wing semi-span model have been implemented in the 9 x 7ft de Havilland wind tunnel at the University of Glasgow. The main objective of this investigation is to quantify the effect of removing the traditional peniche boundary layer spacer utilised in this type of testing. Removal of the peniche results in a stand-off gap between the wind tunnel wall and the model’s symmetry plane. This offers the advantage of preventing the development of a horseshoe vortex in front of the model, at the peniche/wall juncture. The formation of the horseshoe vortex is known to influence the flow structures around the entire model and thus alters the model’s aerodynamic behaviours. To determine the influence of the stand-off gap, several gap heights have been tested for a range of angles of attack at Re = 1.5 x 106, based on the wing mean aerodynamic chord (MAC). Force platform data have been used to evaluate aerodynamic coefficients, and how they vary with stand-off heights. Stereoscopic Particle Imaging Velocimetry (sPIV) was used to examine the interaction between the tunnel boundary layer and model’s respective stand-off gap. In addition, clay and tuft surface visualisation enhanced the understanding of how local flow structures over the length of the fuselage vary with stand-off height and angle of attack. The presented results show that a stand-off gap of four-to-five times the displacement thickness of the tunnel wall boundary layer is capable of achieving a flow field around the model fuselage that is representative of what would be expected for an equivalent full-span model in free-air—this cannot be achieved with the application of a peniche.
Skinner, S.N.
f46cee63-5205-4d08-9d7c-cdeb91c23ac1
Zare-Behtash, H.
74be9b97-cb09-49c6-9f75-7ec58c0dd16c
8 November 2017
Skinner, S.N.
f46cee63-5205-4d08-9d7c-cdeb91c23ac1
Zare-Behtash, H.
74be9b97-cb09-49c6-9f75-7ec58c0dd16c
Skinner, S.N. and Zare-Behtash, H.
(2017)
Semi-span wind tunnel testing without conventional peniche.
Experiments in Fluids, 58, [163].
(doi:10.1007/s00348-017-2442-7).
Abstract
Low-speed wind tunnel tests of a flexible wing semi-span model have been implemented in the 9 x 7ft de Havilland wind tunnel at the University of Glasgow. The main objective of this investigation is to quantify the effect of removing the traditional peniche boundary layer spacer utilised in this type of testing. Removal of the peniche results in a stand-off gap between the wind tunnel wall and the model’s symmetry plane. This offers the advantage of preventing the development of a horseshoe vortex in front of the model, at the peniche/wall juncture. The formation of the horseshoe vortex is known to influence the flow structures around the entire model and thus alters the model’s aerodynamic behaviours. To determine the influence of the stand-off gap, several gap heights have been tested for a range of angles of attack at Re = 1.5 x 106, based on the wing mean aerodynamic chord (MAC). Force platform data have been used to evaluate aerodynamic coefficients, and how they vary with stand-off heights. Stereoscopic Particle Imaging Velocimetry (sPIV) was used to examine the interaction between the tunnel boundary layer and model’s respective stand-off gap. In addition, clay and tuft surface visualisation enhanced the understanding of how local flow structures over the length of the fuselage vary with stand-off height and angle of attack. The presented results show that a stand-off gap of four-to-five times the displacement thickness of the tunnel wall boundary layer is capable of achieving a flow field around the model fuselage that is representative of what would be expected for an equivalent full-span model in free-air—this cannot be achieved with the application of a peniche.
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s00348-017-2442-7
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Accepted/In Press date: 30 September 2017
Published date: 8 November 2017
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Local EPrints ID: 490945
URI: http://eprints.soton.ac.uk/id/eprint/490945
ISSN: 0723-4864
PURE UUID: b718936e-59ad-4e57-bf20-57dce2a7f29c
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Date deposited: 10 Jun 2024 16:37
Last modified: 11 Jun 2024 02:09
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Author:
S.N. Skinner
Author:
H. Zare-Behtash
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