Influence of instability modes on cooling performance in hypersonic boundary layer with slot injection
Influence of instability modes on cooling performance in hypersonic boundary layer with slot injection
A combined numerical-experimental investigation is presented with focus on the effects of boundary-layer instabilities and transition on the wall cooling performance in a Mach 5 low-enthalpy flow over a flat plate, with coolant injection achieved through a row of slots. The numerical study has been performed through direct numerical simulation (DNS) of the compressible Navier-Stokes equations, and is supported by results from linear stability analysis (LST) for the considered boundary layer. The experiments have been conducted in the High Density Tunnel (HDT) of the Oxford Thermofluids Institute, and include several blowing ratio conditions of injected air for the same freestream conditions. Surface heat transfer and pressure measurements, film effectiveness measurements, and Schlieren images are presented. The analysis links the wall cooling performance to the growth of imposed unstable boundary layer modes. Results indicate that 2D and 3D unstable modes, pertaining to the class of first instability modes, exist in the laminar boundary layer, and that imposition of these modes at different amplitudes leads to different states of the boundary layer, which we refer to as a perturbed state and a transitional state for medium and high amplitude respectively. As confirmed by comparison with experimental data, the perturbed and transitional states of the boundary layer significantly affect the wall cooling performance, providing an increase of the wall heat flux that results in a reduction of the beneficial effects of cooling.
Boundary-layer stability, Hypersonic flow, Wall cooling
Cerminara, Adriano
6fd11181-c852-4558-82b5-5f7eac291a3f
Hermann, Tobias
34949e9f-53b2-487a-96e6-b26a7747ac14
Saad Ifti, Hassan
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Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Sandham, Neil
0024d8cd-c788-4811-a470-57934fbdcf97
McGilvray, Matthew
84a8661b-03b2-43a1-9811-86b63bcb2a15
1 February 2021
Cerminara, Adriano
6fd11181-c852-4558-82b5-5f7eac291a3f
Hermann, Tobias
34949e9f-53b2-487a-96e6-b26a7747ac14
Saad Ifti, Hassan
7b905f13-e71d-4367-936d-67412dc20dd5
Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Sandham, Neil
0024d8cd-c788-4811-a470-57934fbdcf97
McGilvray, Matthew
84a8661b-03b2-43a1-9811-86b63bcb2a15
Cerminara, Adriano, Hermann, Tobias, Saad Ifti, Hassan, Deiterding, Ralf, Sandham, Neil and McGilvray, Matthew
(2021)
Influence of instability modes on cooling performance in hypersonic boundary layer with slot injection.
Aerospace Science and Technology, 109, [106409].
(doi:10.1016/j.ast.2020.106409).
Abstract
A combined numerical-experimental investigation is presented with focus on the effects of boundary-layer instabilities and transition on the wall cooling performance in a Mach 5 low-enthalpy flow over a flat plate, with coolant injection achieved through a row of slots. The numerical study has been performed through direct numerical simulation (DNS) of the compressible Navier-Stokes equations, and is supported by results from linear stability analysis (LST) for the considered boundary layer. The experiments have been conducted in the High Density Tunnel (HDT) of the Oxford Thermofluids Institute, and include several blowing ratio conditions of injected air for the same freestream conditions. Surface heat transfer and pressure measurements, film effectiveness measurements, and Schlieren images are presented. The analysis links the wall cooling performance to the growth of imposed unstable boundary layer modes. Results indicate that 2D and 3D unstable modes, pertaining to the class of first instability modes, exist in the laminar boundary layer, and that imposition of these modes at different amplitudes leads to different states of the boundary layer, which we refer to as a perturbed state and a transitional state for medium and high amplitude respectively. As confirmed by comparison with experimental data, the perturbed and transitional states of the boundary layer significantly affect the wall cooling performance, providing an increase of the wall heat flux that results in a reduction of the beneficial effects of cooling.
Text
AESCTE-revised
- Accepted Manuscript
More information
Accepted/In Press date: 30 November 2020
e-pub ahead of print date: 14 December 2020
Published date: 1 February 2021
Keywords:
Boundary-layer stability, Hypersonic flow, Wall cooling
Identifiers
Local EPrints ID: 445531
URI: http://eprints.soton.ac.uk/id/eprint/445531
ISSN: 1270-9638
PURE UUID: 6f63a7e1-4e83-4d3f-8be6-51da7b869f9b
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Date deposited: 14 Dec 2020 17:32
Last modified: 17 Mar 2024 06:08
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Contributors
Author:
Adriano Cerminara
Author:
Tobias Hermann
Author:
Hassan Saad Ifti
Author:
Neil Sandham
Author:
Matthew McGilvray
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