Prediction of shock wave configurations in compression ramp flows

Abstract

Here, we provide a theoretical framework revealing that a steady compression ramp flow must have the minimal dissipation of kinetic energy, and can be demonstrated using the least action principle. For a given inflow Mach number M0 and ramp angle α, the separation angle θs manifesting flow system states can be determined based on this theory. Thus, both the shapes of shock wave configurations and pressure peak ppeak behind reattachment shock waves are predictable. These theoretical predictions agree excellently with both experimental data and numerical simulations, covering a wide range of M0 and α. In addition, for a large separation, the theory indicates that θs only depends on M0 and α, but is independent of the Reynolds number Re and wall temperature Tw. These facts suggest that the proposed theoretical framework can be applied to other flow systems dominated by shock waves, which are ubiquitous in aerospace engineering.