Turbulence decay in a supersonic boundary layer subjected to a transverse sonic jet
Turbulence decay in a supersonic boundary layer subjected to a transverse sonic jet
The turbulence state in a supersonic boundary layer subjected to a transverse sonic jet is studied by conducting direct numerical simulations. Turbulence statistics for two jet-to-cross-flow momentum flux ratios of 2.3 and 5.5 based on the previous simulation (Sun & Hu, J. Fluid Mech., vol. 850, 2018, pp. 551-583) are given and compared with a flat-plate boundary layer without a jet. The instantaneous and time-averaged flow features around the transverse jet in the supersonic boundary layer are analysed. It is found that, in the near-wall region, turbulence is suppressed significantly with increasing in the lateral boundary layer around the jet and the turbulence decay is retained in the downstream recovery region. The local boundary-layer thickness decreases noticeably in the lateral downstream of the jet. Analysis of the cross-flow streamlines reveals a double-expansion character in the vicinity of the jet, which involves the reattachment expansion related to the flow over the jet windward separation bubble and the jet lateral expansion related to the flow around the jet barrel shock. The double expansion leads to the turbulence decay in the jet lateral boundary layer and causes a slow recovery of the outer layer in the far-field boundary layer. A preliminary experiment based on the nanoparticle laser scattering technique is conducted and confirms the existence of the turbulence decay phenomenon.
compressible boundary layers, high-speed flow, jets
216-249
Sun, Mingbo
2df9eb75-e5d8-48cf-b8e1-00b0b77b3a90
Liu, Yuan
19d77bdc-5809-412a-a706-77334534f480
Hu, Zhiwei
dd985844-1e6b-44ba-9e1d-fa57c6c88d65
25 May 2019
Sun, Mingbo
2df9eb75-e5d8-48cf-b8e1-00b0b77b3a90
Liu, Yuan
19d77bdc-5809-412a-a706-77334534f480
Hu, Zhiwei
dd985844-1e6b-44ba-9e1d-fa57c6c88d65
Sun, Mingbo, Liu, Yuan and Hu, Zhiwei
(2019)
Turbulence decay in a supersonic boundary layer subjected to a transverse sonic jet.
Journal of Fluid Mechanics, 867, .
(doi:10.1017/jfm.2019.158).
Abstract
The turbulence state in a supersonic boundary layer subjected to a transverse sonic jet is studied by conducting direct numerical simulations. Turbulence statistics for two jet-to-cross-flow momentum flux ratios of 2.3 and 5.5 based on the previous simulation (Sun & Hu, J. Fluid Mech., vol. 850, 2018, pp. 551-583) are given and compared with a flat-plate boundary layer without a jet. The instantaneous and time-averaged flow features around the transverse jet in the supersonic boundary layer are analysed. It is found that, in the near-wall region, turbulence is suppressed significantly with increasing in the lateral boundary layer around the jet and the turbulence decay is retained in the downstream recovery region. The local boundary-layer thickness decreases noticeably in the lateral downstream of the jet. Analysis of the cross-flow streamlines reveals a double-expansion character in the vicinity of the jet, which involves the reattachment expansion related to the flow over the jet windward separation bubble and the jet lateral expansion related to the flow around the jet barrel shock. The double expansion leads to the turbulence decay in the jet lateral boundary layer and causes a slow recovery of the outer layer in the far-field boundary layer. A preliminary experiment based on the nanoparticle laser scattering technique is conducted and confirms the existence of the turbulence decay phenomenon.
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JFM_jet_turbulence_decay
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JFM jet turbulence decay
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Accepted/In Press date: 15 February 2019
e-pub ahead of print date: 21 March 2019
Published date: 25 May 2019
Keywords:
compressible boundary layers, high-speed flow, jets
Identifiers
Local EPrints ID: 432828
URI: http://eprints.soton.ac.uk/id/eprint/432828
ISSN: 0022-1120
PURE UUID: 3d7518cc-1359-4e32-9ade-025b7c6497d7
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Date deposited: 26 Jul 2019 16:30
Last modified: 16 Mar 2024 07:46
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Author:
Mingbo Sun
Author:
Yuan Liu
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