Experimental study of hypersonic traveling crossflow instability over a yawed cone

Boundary layer transition is an important factor in the design process of hypersonic vehicles, and crossflow instability is a critical mode. In this paper, the traveling crossflow instability in a laminar boundary layer at Mach 6 is experimentally investigated. Experiments were performed over a 7∘ h...

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Bibliographic Details
Published inActa astronautica Vol. 193; pp. 173 - 181
Main Authors Niu, Haibo, Yi, Shihe, Liu, Xiaolin, Huo, Junjie, Zheng, Wenpeng
Format Journal Article
LanguageEnglish
Published Elmsford Elsevier Ltd 01.04.2022
Elsevier BV
Subjects
Amplitudes
Angle of attack
Boundary layer stability
Boundary layer transition
Boundary layers
Cross flow
Crossflow instability
Design factors
Fluid flow
Frequency stability
Hypersonic flow
Hypersonic vehicles
Instability
Laminar boundary layer
Reynolds number
Temperature-sensitive paints
Transducers
Wind tunnel experiments
Boundary layer transition
Hypersonic flow
Crossflow instability
Wind tunnel experiments
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Summary:Boundary layer transition is an important factor in the design process of hypersonic vehicles, and crossflow instability is a critical mode. In this paper, the traveling crossflow instability in a laminar boundary layer at Mach 6 is experimentally investigated. Experiments were performed over a 7∘ half-angle cone at 6∘ angle of attack, with the unit Reynolds number of Re∞=5.75×106 m−1. Flush-mounted fast-response pressure transducers and time-averaging temperature-sensitive paint were used to capture the traveling crossflow instability and the stationary crossflow instability, respectively. The traveling crossflow waves with characteristic frequencies between 10 and 25 kHz are detected in the planes with the azimuthal angle between 23∘ and 143∘ away from the leeward ray. The three-dimensional amplitude growth was obtained. In general, the amplitude growth of the traveling crossflow instability is roughly leeside-forward and windside-aft. Although the traveling crossflow instability grows earlier on the leeward side, it has a larger amplitude on the windward side. Compared with the stationary mode, the traveling mode grows faster and reaches the highest amplitude earlier. In addition, a high-frequency instability with characteristic frequencies between 100 and 200 kHz is observed. It may be the secondary instability of the traveling crossflow waves, but whether it is true or not needs further experimental and numerical studies. •In a hypersonic flow, the three-dimensional growth of the traveling crossflow instability on a yawed cone was measured.•Compared with the stationary crossflow instability, the traveling crossflow instability grows faster and reaches the highest amplitude earlier.•A high-frequency instability with f= 100–200 kHz was found, and it may be the secondary instability of the traveling crossflow waves.
ISSN:0094-5765
1879-2030
DOI:10.1016/j.actaastro.2021.12.016