Litcius/Paper detail

Hypersonic Slender-Cone Boundary-Layer Instability in the UMD HyperTERP Shock Tunnel

Ahsan Hameed, Nick J. Parziale, Laura A. Paquin, Cameron Butler, Stuart J. Laurence

2020AIAA Scitech 2020 Forum17 citationsDOI

Abstract

Results from a stability investigation using quad-focused laser differential interferometry (q-FLDI) and high-speed schlieren cinematography of hypersonic flow over a cooled and uncooled 5◦ half-angle cone are presented in this paper. The frequency and phase-speed of the largest-amplitude disturbance (largest N factor) as predicted by STABL and measured by FLDI or schlieren were in excellent agreement for the room-temperature cases and good agreement for the cooled-wall cases. A comparison between a cooled-wall and room- temperature shot at nominally the same Reynolds number shows the interesting result of the later transition to turbulence for the cooled-wall shot. Our hypothesis is: cooled-wall cases have higher growth rates and higher most-amplified frequencies. Because there is less wind-tunnel noise at higher frequency, transition will occur at a higher Reynolds number.

Topics & Concepts

SchlierenHypersonic speedWind tunnelReynolds numberOpticsBoundary layerMechanicsTurbulenceSupersonic wind tunnelInstabilityShock (circulatory)Expansion tunnelMach numberPhysicsShadowgraphFlow visualizationMaterials scienceShot (pellet)Hypersonic flowNoise (video)Flow (mathematics)Image (mathematics)MedicineArtificial intelligenceComputer scienceMetallurgyInternal medicineFluid Dynamics and Turbulent FlowsParticle Dynamics in Fluid FlowsMeteorological Phenomena and Simulations