Phase-based control of periodic flows

Unsteady bluff-body flows exhibit dominant oscillatory behaviour owing to periodic vortex shedding. The ability to manipulate this vortex shedding is critical to improving the aerodynamic performance of bodies in a flow. This goal requires a precise understanding of how the perturbations affect the...

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Bibliographic Details
Published in:Journal of fluid mechanics 2021-11, Vol.927, Article A30
Main Authors: Nair, Aditya G., Taira, Kunihiko, Brunton, Bingni W., Brunton, Steven L.
Format: Article
Language:English
Subjects:
Actuation
Asymptotic properties
Boundary value problems
Circular cylinders
Cylinders
Dimensional measurement
Energy efficiency
Euler-Lagrange equation
Flow control
Fluid dynamics
Fluid flow
Incompressible flow
JFM Papers
Laminar flow
Oscillating flow
Oscillatory flow
Perturbation
Phase control
Reduced order models
Reynolds number
Sensitivity analysis
Stability
Time optimal control
Vortex shedding
Vortices
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Summary:Unsteady bluff-body flows exhibit dominant oscillatory behaviour owing to periodic vortex shedding. The ability to manipulate this vortex shedding is critical to improving the aerodynamic performance of bodies in a flow. This goal requires a precise understanding of how the perturbations affect the asymptotic behaviour of the oscillatory flow and of the ability to control transient dynamics. In this work, we develop an energy-efficient flow-control strategy to alter the oscillation phase of time-periodic fluid flows rapidly. First, we perform a phase-sensitivity analysis to construct a reduced-order model for the response of the flow oscillation to impulsive control inputs at various phases. Next, we introduce a real-time optimal phase-control strategy based on the phase-sensitivity function obtained by solving the associated Euler–Lagrange equations as a two-point boundary-value problem. Our approach is demonstrated for the incompressible laminar flow past a circular cylinder and an airfoil. We show the effectiveness of phase control with different actuation inputs, including blowing and rotary control. Moreover, our control approach is a sensor-based approach without the need for access to high-dimensional measurements of the entire flow field.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2021.735