Unsteady pulsating flowfield over spiked axisymmetric forebody at hypersonic flows

Abstract

The paper gives experimental observations on the hypersonic flow past an axisymmetric flat-face cylinder with a protruding sharp-tip spike at a freestream Mach number of M∞ = 8.16 at two different freestream Reynolds numbers based on the base body diameter (ReD = 0.76 × 106, and 3.05 × 106). Furthermore, modal analysis is done on schlieren images to understand the flow dynamics parallel with the unsteady pressure measurements. The protruding spike of length to base body diameter ratio of [l/D]=1 creates a familiar unsteady flowfield called 'pulsation.' Pressure loading and fluctuation intensity at two different ReD cases are calculated. A maximum drop of 98.24\% is observed in both parameters between the high and low ReD cases. Based on the analysis, a difference in the pulsation characteristics are noticed, which arise from two vortical zones, each from a system of two `λ' shocks formed during the `collapse' phase ahead of the base body. The interaction of shedding vortices from the λ-shocks' triple-points, along with the rotating stationary waves, contributes to the asymmetric high-pressure loading and the observation of shock pulsation on the flat-face cylinder. The vortical interactions form the second dominant spatial mode with a temporal mode carrying a dimensionless frequency (f2D/u∞ ≈ 0.34) almost twice that of the fundamental frequency (f1D/u∞ ≈ 0.17). The observed frequencies are invariant irrespective of the ReD cases. However, for the high-frequency range, the spectral pressure decay is observed to follow an inverse and -7/3 law for the low and high ReD cases, respectively.