Pressure plateau of separation induced by shock impingement in a Mach 5 flow

Xue, Longsheng; Jiao, Yun; Wang, Chengpeng; Cheng, Keming

doi:10.1017/jfm.2023.725

J. Fluid Mech.

2023

DOI: 10.1017/jfm.2023.725

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Pressure plateau of separation induced by shock impingement in a Mach 5 flow

Longsheng Xue,

Yun Jiao,

Chengpeng Wang

et al.

Abstract: Separation induced by impinging shock is a fundamental feature in supersonic and hypersonic flows; however, it is difficult to predict the pressure plateau due to a limited theoretical understanding of the effect of impinging shock strength. In this study, the evolution of the separation configuration and pressure distribution with changes in impinging shock angle is examined, and a theoretical equation for predicting the pressure plateau based on minimum entropy production is proposed. For validation, an expe… Show more

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2024

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Cited by 2 publications

References 22 publications

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Synchronized shock wave and compliant wall interactions: Experimental characterization and aeroelastic modeling

Moreno,

Couliou,

Fabbiane

et al. 2024

Journal of Fluids and Structures

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Synchronized shock wave and compliant wall interactions: Experimental characterization and aeroelastic modeling

Moreno,

Couliou,

Fabbiane

et al. 2024

Journal of Fluids and Structures

View full text Add to dashboard Cite

On the mean structure and unsteadiness of dual shock wave–turbulent boundary layer interactions

Li,

et al. 2024

J. Fluid Mech.

View full text Add to dashboard Cite

Supersonic internal flows often exhibit multiple reflected shocks within a limited distance. These shocks can interact with each other in a complex manner due to the characteristics of the shock wave–turbulent boundary layer interaction (STBLI), including flow distortion and the relaxing boundary layer. This study aims to characterise this type of interaction and to clarify its fluid physics. A separated STBLI zone was established either upstream or downstream, and another weaker STBLI was established in the opposing position to serve as a perturbation. Time-resolved measurements were employed to characterise the mean separation and unsteadiness as the two regions approached each other, as well as their relationship. The experimental results indicated that the STBLI could affect the separation and reattachment of the other STBLI through either the decelerated or relaxing boundary layer. Despite a small deflection angle, the incident shock can amplify the low-frequency oscillations in the downstream STBLI region. Additionally, the interaction in the downstream region can be influenced by both low- and high-frequency oscillations associated with the upstream STBLI through a relaxing boundary layer. Despite the limited correlation observed between the low-frequency fluctuations in the downstream region and the boundary layer flow not far upstream, there still exists some degree of correlation between the low-frequency shock motions even when they are widely separated. Both the ‘upstream mechanism’ and ‘downstream mechanism’ have been observed, and the significance of low-frequency dynamics in the separated flow, relative to that of the upstream flow, is closely associated with interaction intensity.

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Pressure plateau of separation induced by shock impingement in a Mach 5 flow

Cited by 2 publications

References 22 publications

Synchronized shock wave and compliant wall interactions: Experimental characterization and aeroelastic modeling

Synchronized shock wave and compliant wall interactions: Experimental characterization and aeroelastic modeling

On the mean structure and unsteadiness of dual shock wave–turbulent boundary layer interactions

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