Receptivity to freestream acoustic noise in hypersonic flow over a generic forebody
Receptivity to freestream acoustic noise in hypersonic flow over a generic forebody
Direct numerical simulations of the Navier–Stokes equations have been performed to investigate the receptivity and breakdown mechanisms in a Mach 6 flow over a generic forebody geometry with freestream acoustic disturbances. The simulations are based on transition experiments carried out in April 2015 in the Boeing/U.S. Air Force Office of Scientific Research Mach 6 facility at Purdue University. A three-dimensional model for both fast and slow freestream acoustic waves with multiple frequencies and spanwise wave numbers has been adopted in the numerical simulations, for which high-amplitude disturbances have been considered in order to simulate noisy wind-tunnel conditions. The numerical results revealed similarities in comparison to the experimental observations, especially when slow acoustic waves were considered as freestream disturbances. In particular, slow acoustic waves have been found to induce the breakdown process via crossflow instabilities located in the off-centerline region, with formation of streamwise streaks. Fast acoustic waves, in contrast, appeared more efficient in inducing earlier nonlinear growth through
destabilization of the boundary layer along the symmetry plane of the body.
hypersonics, numerical simulation, boundary layer receptivity, transition, acoustic waves
1-11
Cerminara, Adriano
6fd11181-c852-4558-82b5-5f7eac291a3f
Durant, Antoine
91a3863d-e525-4bd5-94ec-10a76aa0a55b
André, Thierry
a776e501-b185-4e46-9987-218ace7af88d
Sandham, Neil
0024d8cd-c788-4811-a470-57934fbdcf97
Taylor, Nigel
83a1254c-9d22-4ef6-be3d-cf8c4a0a89ab
November 2018
Cerminara, Adriano
6fd11181-c852-4558-82b5-5f7eac291a3f
Durant, Antoine
91a3863d-e525-4bd5-94ec-10a76aa0a55b
André, Thierry
a776e501-b185-4e46-9987-218ace7af88d
Sandham, Neil
0024d8cd-c788-4811-a470-57934fbdcf97
Taylor, Nigel
83a1254c-9d22-4ef6-be3d-cf8c4a0a89ab
Cerminara, Adriano, Durant, Antoine, André, Thierry, Sandham, Neil and Taylor, Nigel
(2018)
Receptivity to freestream acoustic noise in hypersonic flow over a generic forebody.
Journal of Spacecraft and Rockets, .
(doi:10.2514/1.A34283).
Abstract
Direct numerical simulations of the Navier–Stokes equations have been performed to investigate the receptivity and breakdown mechanisms in a Mach 6 flow over a generic forebody geometry with freestream acoustic disturbances. The simulations are based on transition experiments carried out in April 2015 in the Boeing/U.S. Air Force Office of Scientific Research Mach 6 facility at Purdue University. A three-dimensional model for both fast and slow freestream acoustic waves with multiple frequencies and spanwise wave numbers has been adopted in the numerical simulations, for which high-amplitude disturbances have been considered in order to simulate noisy wind-tunnel conditions. The numerical results revealed similarities in comparison to the experimental observations, especially when slow acoustic waves were considered as freestream disturbances. In particular, slow acoustic waves have been found to induce the breakdown process via crossflow instabilities located in the off-centerline region, with formation of streamwise streaks. Fast acoustic waves, in contrast, appeared more efficient in inducing earlier nonlinear growth through
destabilization of the boundary layer along the symmetry plane of the body.
Text
JSR
- Accepted Manuscript
More information
e-pub ahead of print date: 9 November 2018
Published date: November 2018
Keywords:
hypersonics, numerical simulation, boundary layer receptivity, transition, acoustic waves
Identifiers
Local EPrints ID: 428826
URI: http://eprints.soton.ac.uk/id/eprint/428826
ISSN: 0022-4650
PURE UUID: 94499c74-0cb4-4732-a367-d9bd505b7dc2
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Date deposited: 11 Mar 2019 17:30
Last modified: 16 Mar 2024 03:03
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Contributors
Author:
Adriano Cerminara
Author:
Antoine Durant
Author:
Thierry André
Author:
Neil Sandham
Author:
Nigel Taylor
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