Hypersonic oscillating shock-wave/boundary-layer interaction on a flat plate
Article
Article Title | Hypersonic oscillating shock-wave/boundary-layer interaction on a flat plate |
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ERA Journal ID | 3575 |
Article Category | Article |
Authors | Currao, Gaetano M. D. (Author), McQuellin, Liam P. (Author), Neely, Andrew J. (Author), Gai, Sudhir L. (Author), O'Byrne, Sean (Author), Zander, Fabian (Author), Buttsworth, David R. (Author), McNamara, Jack J. (Author) and Jahn, Ingo (Author) |
Journal Title | AIAA Journal: devoted to aerospace research and development |
Journal Citation | 59 (3), pp. 940-959 |
Number of Pages | 20 |
Year | 2021 |
Publisher | American Institute of Aeronautics and Astronautics |
Place of Publication | United States |
ISSN | 0001-1452 |
1533-385X | |
Digital Object Identifier (DOI) | https://doi.org/10.2514/1.J059590 |
Web Address (URL) | https://arc.aiaa.org/doi/10.2514/1.J059590 |
Abstract | This work discusses the design, measurement, and simulation of an oscillating shock-wave/boundary-layer interaction on a flat plate at Mach 5.8 and Re ∞ =7×10 6 m −1 Re∞=7×106 m−1. The shock generator is free to pitch and oscillates with a frequency of 42 Hz, resulting in a shock that varies in intensity and impingement point, with a maximum flow-deflection angle of approximately 10 deg. Transition appears to take place downstream of the separated region for both static (with a fixed flow-deflection angle) and dynamic experiments; however, heat-flux values are typically between laminar and turbulent solutions, thus suggesting that a complete transition to a fully turbulent boundary layer is delayed because of the favorable pressure gradient induced by the impinging expansion wave originating from trailing edge of the shock generator. Peak pressure is typically overpredicted by laminar simulations for large deflection angles. Starting from the reattachment point, heat-flux measurements show that the boundary layer gradually deviates from the laminar solution towards a fully turbulent boundary layer. Vortices are observed in the reattachment region, and their distribution is solely a function of the boundary-layer properties at the separation point. Transient effects induced by the shock motion result in a maximum bubble length variation of 30%. For the static cases, the separated region amplified disturbances with a frequency of approximately 200 Hz. In the dynamic experiment, harmonics induced by the pseudosinusoidal motion of the shock generator were measured everywhere on the plate. |
Contains Sensitive Content | Does not contain sensitive content |
ANZSRC Field of Research 2020 | 400106. Hypersonic propulsion and hypersonic aerothermodynamics |
Public Notes | Files associated with this item cannot be displayed due to copyright restrictions. |
Byline Affiliations | National Cheng Kung University, Taiwan |
University of New South Wales | |
Department of Mechanical and Electrical Engineering | |
School of Mechanical and Electrical Engineering | |
Ohio State University, United States | |
University of Queensland | |
Institution of Origin | University of Southern Queensland |
https://research.usq.edu.au/item/q6v45/hypersonic-oscillating-shock-wave-boundary-layer-interaction-on-a-flat-plate
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