Dynamics and control of the vortex flow behind a slender conical forebody by a pair of plasma actuators

Detailed particle-image-velocimetry (PIV) and surface pressure measurements are presented to study the vortex flow behind a slender conical forebody at high angles of attack. The results confirm the existence of two randomly appearing mirror imaged asymmetric bi-stable states of the separation vorti...

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Bibliographic Details
Published in:Physics of fluids (1994) 2018-02, Vol.30 (2)
Main Authors: Meng, Xuanshi, Long, Yuexiao, Wang, Jianlei, Liu, Feng, Luo, Shijun
Format: Article
Language:English
Subjects:
Actuation
Angle of attack
Conical bodies
Conical flow
Cycle ratio
Dielectric barrier discharge
Flaps
Flow control
Fluid dynamics
Fluid flow
Noise control
Plasma
Plasma actuators
Pressure
Proportional control
Velocimetry
Velocity measurement
Vortices
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Summary:Detailed particle-image-velocimetry (PIV) and surface pressure measurements are presented to study the vortex flow behind a slender conical forebody at high angles of attack. The results confirm the existence of two randomly appearing mirror imaged asymmetric bi-stable states of the separation vortices, giving rise to large side force and moment. A pair of carefully designed dielectric barrier discharge plasma actuators mounted near the apex and on both sides of the conical body are used to manipulate the vortex flow and thus provide control of the side forces on the body without using flaps. By making use of a duty-cycle actuation scheme that alternately actuates the port and starboard plasma actuators and optimizing the duty-cycle frequency, the present work demonstrates the feasibility of achieving a nearly perfect linear proportional control of the side force and moment in response to the duty-cycle ratio. Phase-locked PIV and surface pressure measurements are used to study the unsteady dynamic evolution of the flow within one duty-cycle actuation to reveal the flow control mechanism. It is found that under the duty-cycle actuation with the optimized frequency, the vortex flow essentially follows the plasma actuation by alternating between the two bi-stable states controlled directly by the duty-cycle ratio.
ISSN:1070-6631
1089-7666
DOI:10.1063/1.5005514