Recovery of a supersonic turbulent boundary layer after an expansion corner
Recovery of a supersonic turbulent boundary layer after an expansion corner
Supersonic turbulent flows at Mach 2.7 over expansion corners with deflection angles of 0° (flat plate), 2° and 4° have been studied using direct numerical simulation. Distribution of the skin friction, pressure, velocity and the boundary layer growth show that the turbulent boundary layer experiences a recovery from a non-equilibrium to an equilibrium state downstream of the expansion corner. Analysis of velocity profiles indicates that the streamwise velocity undergoes a reduction in the near-wall region even though the velocity in the core part of the boundary layer is accelerated after the expansion corner. Growth of the boundary layer was evaluated and a higher shape factor was found in the expansion cases. Turbulence was found to be suppressed downstream of the corner, and throughout the recovery region, even though turbulence is regenerated in the near-wall region. The expansion ramp increases the near wall streak spacing compared to a flat plate and turbulent kinetic energy profiles and budgets exhibit a characteristic two-layer structure. Near-wall turbulence recovers to the equilibrium more quickly in the inner layer than in the outer layer due to a balance between the local production and dissipation. The two-layer structure is due to the history effect of the turbulence decay in the outer part of the boundary layer in the vicinity downstream of the expansion corner, which blocks the momentum and energy exchange between the inner layer and the main stream.
supersonic flow, turbulent boundary layer, expansion
Sun, Ming-bo
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Hu, Zhiwei
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Sandham, Neil
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Sun, Ming-bo
8bd9b8fe-791b-420d-9f6c-a5cf9a1e1f6a
Hu, Zhiwei
dd985844-1e6b-44ba-9e1d-fa57c6c88d65
Sandham, Neil
0024d8cd-c788-4811-a470-57934fbdcf97
Sun, Ming-bo, Hu, Zhiwei and Sandham, Neil
(2017)
Recovery of a supersonic turbulent boundary layer after an expansion corner.
Physics of Fluids, 29 (7), [076103].
(doi:10.1063/1.4995293).
Abstract
Supersonic turbulent flows at Mach 2.7 over expansion corners with deflection angles of 0° (flat plate), 2° and 4° have been studied using direct numerical simulation. Distribution of the skin friction, pressure, velocity and the boundary layer growth show that the turbulent boundary layer experiences a recovery from a non-equilibrium to an equilibrium state downstream of the expansion corner. Analysis of velocity profiles indicates that the streamwise velocity undergoes a reduction in the near-wall region even though the velocity in the core part of the boundary layer is accelerated after the expansion corner. Growth of the boundary layer was evaluated and a higher shape factor was found in the expansion cases. Turbulence was found to be suppressed downstream of the corner, and throughout the recovery region, even though turbulence is regenerated in the near-wall region. The expansion ramp increases the near wall streak spacing compared to a flat plate and turbulent kinetic energy profiles and budgets exhibit a characteristic two-layer structure. Near-wall turbulence recovers to the equilibrium more quickly in the inner layer than in the outer layer due to a balance between the local production and dissipation. The two-layer structure is due to the history effect of the turbulence decay in the outer part of the boundary layer in the vicinity downstream of the expansion corner, which blocks the momentum and energy exchange between the inner layer and the main stream.
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Expansion Paper
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Accepted/In Press date: 4 July 2017
e-pub ahead of print date: 28 July 2017
Keywords:
supersonic flow, turbulent boundary layer, expansion
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Local EPrints ID: 413320
URI: http://eprints.soton.ac.uk/id/eprint/413320
ISSN: 1070-6631
PURE UUID: bcfaa8dc-d0ec-44a3-bca6-66a8418410d3
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Date deposited: 21 Aug 2017 16:31
Last modified: 16 Mar 2024 03:03
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Author:
Ming-bo Sun
Author:
Neil Sandham
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