An experimental-computational investigation of the response of a compliant panel to turbulent and transitional shock-wave-boundary-layer interactions in hypersonic flow

Abstract

We propose a combined experimental-numerical study of the fluid-structure interaction (FSI) induced by a flexible panel exposed to a two-dimensional hypersonic shock-wave-boundary-layer interaction (SWBLI), under both turbulent and transitional upstream boundary-layer conditions. The proposed investigation will take advantage of hypersonic facilities at NASA Langley through an agreement with UMD, and a state-of-the-art computational infrastructure at the University of Illinois, Urbana-Champaign (UIUC). Experiments will be performed on a flat-plate-ramp configuration to produce a planar SWBLI, with both transitional and fully turbulent incoming boundary layers (achieved by varying the unit Reynolds number), with the compliant panel located downstream of the plate-ramp junction. The ramp angle will be varied to produce a range of interaction strengths at both Mach 6 (Langley 20 Mach-6tunnel) and Mach 10 (Langley 31 Mach-10 tunnel). Various measurement techniques will be implemented, including fast-response pressure transducers, high-speed Schlieren and IR thermography, and marker-tracking photogrammetry for panel deformation measurements. Measurements of the turbulent SWBLI-FSI will be compared with results from high-fidelity coupled fluid-structure simulations, accurately representing experimental conditions, which will provide a detailed picture of the interaction dynamics. Finally, a global mode-based analysis will be performed to provide a physics-based reduced-order model of the coupled fluid-structure system.

Document Details

Document Type

DoD Grant Award

Publication Date

Mar 07, 2023

Source ID

FA95502110249

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