Compressible Invariant Solutions In Open Cavity Flows

TL;DR

This paper reports the discovery of compressible exact periodic solutions in open cavity flows using a novel computational framework, revealing how flow-acoustic interactions and Mach number influence stability and dynamics.

Contribution

It introduces a new method to compute exact periodic solutions in complex geometries and analyzes the impact of compressibility on cavity flow stability and dynamics.

Findings

Periodic solutions arise from flow-acoustic interactions dependent on Mach number.

Compressibility destabilizes cavity flows, leading to a Hopf bifurcation.

Eigenvalue merge at Mach 0.35-0.4 increases receptivity and instability.

Abstract

A family of compressible exact periodic solutions is reported for the first time in an open cavity flow setup. These are found using a novel framework which permits the computation of such solutions in an arbitrary complex geometry. The periodic orbits arise from a synchronised concatenation of convective and acoustic events which strongly depend on the Mach number. This flow-acoustic interaction furnishes the periodic solutions with a remarkable stability and it is found to completely dominate the system's dynamics and the sound directivity. The periodic orbits, which could be called `exact Rossiter modes', collapse with a family of equilibrium solutions at a subcritical Hopf bifurcation, occurring in the quasi-incompressible regime. This shows compressibility has a destabilising effect in cavity flows, which we analyse in detail. By establishing a connection with previous 2D and 3D stability studies of cavity flows, we are able to isolate the effect of purely compressible two-dimensional flow phenomena across Mach number. A linear stability analysis of the equilibria provides insight into the compressible flow mechanisms responsible for the instability. A close look at the adjoint modes suggests that an eigenvalue merge occurs at a Mach number between 0.35 and 0.4, which boosts the receptivity of the leading mode and determines the onset of the unstable character of the system. The effect of the choice of base flow over the transition dynamics is also discussed, where in the present case, the frequencies associated to the leading eigenmodes show a strong connection with the frequencies of the periodic orbits at the same Mach numbers.