Steady-State Closed-Loop Control of Bypass Boundary Layer Transition Using Plasma Actuators

Hanson, Ronald; Lavoie, Philippe; Bade, Kyle M.; Naguib, Ahmed

doi:10.2514/6.2012-1140

Cited by 9 publications

(4 citation statements)

References 27 publications

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“…Plasma actuator SDBD plasma actuators (hereafter simply referred to as plasma actuators), provide a uniquely deployable, robust and adjustable amplitude flow forcing that is appropriate for the target control experiments (Hanson et al 2010(Hanson et al , 2012(Hanson et al , 2014Osmokrovic et al 2015). A comprehensive description of this type of a plasma actuator arrangement may be found in Corke, Post & Orlov (2009) or Benard & Moreau (2014).…”

Section: Roughness Elementmentioning

confidence: 99%

Reactive control of isolated unsteady streaks in a laminar boundary layer

et al. 2016

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This study is motivated by controlling transient growth and subsequent bypass transition of the laminar boundary layer to turbulence. In experiments employing a model problem, an active roughness element is used to introduce steady/unsteady streak disturbances in a Blasius boundary layer. This tractable arrangement enables a systematic investigation of the evolution of the disturbances and of potential methods to control them in real time. The control strategy utilizes wall-shear-stress sensors, upstream and downstream of a plasma actuator, as inputs to a model-based controller. The controller is designed using empirical input/output data to determine the parameters of simple models, approximating the boundary layer dynamics. The models are used to tune feedforward and feedback controllers. The control effect is examined over a range of roughness-element heights, free stream velocities, feedback sensor positions, unsteady disturbance frequencies and control strategies; and is found to nearly completely cancel the steady-state disturbance at the downstream sensor location. The control of unsteady disturbances exhibits a limited bandwidth of less than 1.3 Hz. However, concurrent modelling demonstrates that substantially higher bandwidth is achievable by improving the feedforward controller and/or optimizing the feedback sensor location. Moreover, the model analysis shows that the difference in the convective time delay of the roughness-and actuator-induced disturbances over the control domain must be known with high accuracy for effective feedforward control. This poses a limitation for control effectiveness in a stochastic environment, such as in bypass transition beneath a turbulent free stream; nonetheless, feedback can remedy some of this limitation.

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Section: Roughness Elementmentioning

confidence: 99%

Reactive control of isolated unsteady streaks in a laminar boundary layer

et al. 2016

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“…The plasma excitation's correction effect on the mean flow can be used to suppress the growth of the local 3D cross-flow component in the boundary layer of the swept-back wing model, thereby delaying the transition [7]. Based on the feedback from the wall shear stress test, adjusting the plasma actuator layout to generate the flow vortex structure suppresses the flow stripes in the bypass transition at the IOP Publishing doi:10.1088/1742-6596/2730/1/012055 2 incoming flow velocity of 5 m/s, thus delaying the transition [8][9]. To delay the transverse turning of a conical boundary layer at an incoming flow of 3.5 Ma [10], a plasma actuator is used to generate pairs of counter-rotating vortices that suppress high-harmonic energies and thus delay the transition in a supersonic boundary layer.…”

Section: Introductionmentioning

confidence: 99%

Experiments for control of boundary layer transition by plasma actuators

Song,

Zhang,

Shi

et al. 2024

J. Phys.: Conf. Ser.

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Plasma flow control technology is a new type of active flow control technology, and this paper carries out certain research on the basic principle of plasma flow control technology and its application on the wing model. The paper introduces the theory of plasma discharge and analyzes how plasma can control the flow field. A parallel dielectric barrier discharge plasma exciter is then designed and tested by using the Particle Image Velocimetry (PIV) technique to investigate the spatial flow field distributions of single-stage and three-stage actuators, and the mechanism of jet generation by the actuator is analyzed. Finally, the plasma actuator was utilized to control flow separation on a super-zero-boundary airfoil, and the oil droplet interferometric method was used to study the actuator’s role in controlling boundary layer transition. The experiment revealed that increasing the actuator discharge voltage can further reduce wall drag and more effectively delay the transition. Under the given conditions of a head-on angle of 6° and the incoming wind speed of 20 m/s, a two-stage actuator’s continuous discharge parameter was set to an output voltage of 12 kV and an output frequency of 4.7 kHz. The results showed that the transition position can be delayed by 13%, indicating the effectiveness of the actuator’s jet effect in enhancing the stability of the boundary layer flow.

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“…Among the other strategies, direct damping of the cross-flow vortices in the boundary layer was theoretically studied in [6]. Plasma actuators, designed as plasma vortex generators (VG), were also used to damp the streaks in the problem of algebraic instability control [12,13].…”

Section: Introductionmentioning

confidence: 99%

Damping of the longitudinal streak in the boundary layer by ‘plasma panel’ actuator

Moralev¹,

Selivonin²,

Tatarenkova³

et al. 2019

J. Phys. D: Appl. Phys.

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The group of microdischarges in surface DBD can be used as a virtual roughness element. Localization of the discharge along the electrode span can be performed on the ‘plasma panel’ principle by sectioning the buried electrode and individually controlling sections potential. The paper describes the study of the details of such actuator operation. Data presented include the flowfield induced by discharge and the analysis of the controllability of the created disturbances in a subsonic boundary layer. In the final part of the paper, the control of the low-velocity streak, an object widely present in transitionary and turbulent flows, by an adaptive plasma actuator, is demonstrated.

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Steady-State Closed-Loop Control of Bypass Boundary Layer Transition Using Plasma Actuators

Cited by 9 publications

References 27 publications

Reactive control of isolated unsteady streaks in a laminar boundary layer

Reactive control of isolated unsteady streaks in a laminar boundary layer

Experiments for control of boundary layer transition by plasma actuators

Damping of the longitudinal streak in the boundary layer by ‘plasma panel’ actuator

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