Phase-based analysis and control of supersonic turbulent cavity flows

TL;DR

This paper introduces a phase-based control framework for suppressing pressure fluctuations in supersonic turbulent cavity flows by disrupting vortex feedback loops through optimized unsteady blowing.

Contribution

It develops a phase-reduction approach using dynamic mode decomposition to design effective flow control strategies for supersonic cavity flows.

Findings

Achieved up to 46% reduction in pressure fluctuations within five convective times.

Phase-sensitive actuation outperforms sinusoidal waveforms at certain spanwise wavenumbers.

Demonstrated the potential of phase-based analysis for timing-based flow control in turbulent flows.

Abstract

We present a phase-based framework for reducing the pressure fluctuations within a spanwise-periodic supersonic turbulent cavity flow with an incoming free-stream Mach number of 1.4 and a depth-based Reynolds number of 10,000. Open cavity flows exhibit large fluctuations due to the feedback between the shear layer instabilities and the acoustic field. The dominant flow physics includes the formation, convection, and impingement of large-scale spanwise-oriented vortical structures. We formulate a flow control strategy to effectively modify the vortex convection frequency, thereby disrupting the feedback loop and suppressing pressure fluctuations within the cavity. We implement a phase-reduction approach to identify the flow response about the time-varying convective process by defining a phase variable using dynamic mode decomposition. Three-dimensional impulse perturbations are introduced from the cavity leading edge to characterize phase response in terms of advancement or delay of convection. We perform open-loop flow control through unsteady blowing using actuation frequencies slightly different from the vortex convection frequency to disrupt the feedback loop. After designing a phase-sensitivity-based actuation waveform optimized for quick flow modification, we investigate the speed of fluctuation reduction and compare it to a sinusoidal waveform. At a spanwise actuation wavenumber of $\beta=2\pi$, both perform similarly, achieving a 46% reduction of pressure fluctuations within five convective times. At $\beta=\pi$, the phase-sensitivity-based actuation performs better by achieving a 40% reduction compared to the 30% with a sinusoidal waveform within six convective times. This study shows the potential of phase-based analysis for timing-based flow control of unsteady turbulent flows.