Unsteadiness boundaries in supersonic flow over double cones

A computational parameter study of the viscous axisymmetric supersonic flow over a double cone is made with a view to determining the boundary of the region in which such flows are unsteady. The study is restricted to the case when the boundary layer is laminar. The features of both the steady and unsteady flows in different characteristic regions of the parameter space are described. In particular, the phenomenon of pulsating flow typical of spiked blunt bodies (small first-cone angle, theta(1), and large second-cone angle, theta(2)), is shown to be inviscid in nature. In theta(1)-theta(2) space, the region of unsteady flow is enclosed in a loop with a lower and an upper theta(2) branch with a maximum theta(1) between. The location of the lower theta(2) branch is determined by the second-cone detachment angle theta(2d). For this reason, the gas model in one of the conditions is chosen to be thermally perfect carbon dioxide (at Mach number 8) for which theta(2d) is quite large. In the other cases, the gas model is perfect-gas nitrogen at Mach numbers 2, 4 and 7.7. In the hypersonic range, within the uncertainties, and in the parameter range covered, the unsteadiness boundary is shown to depend on only three dimensionless parameters.

Automated summary

This study focuses on the computational parameter study of the viscous axisymmetric supersonic flow over a double cone, aiming to determine the boundary of regions where such flows are unsteady. The research shows that the unsteadiness boundary is influenced by three dimensionless parameters within the uncertainties in the hypersonic range.