Dielectric-barrier-discharge vortex generators: characterisation and optimisation for flow separation control

Jukes, Timothy; Choi, Kwing-So

doi:10.1007/s00348-011-1213-0

Cited by 78 publications

(49 citation statements)

References 46 publications

(55 reference statements)

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“…In order to introduce the desired flow disturbance to counteract the disturbance induced by the upstream roughness element, a single pair of spanwise forcing plasma actuators was used, as shown in figure 3(b), with the forcing from each actuator oriented toward the other. This arrangement results in a pair of counter-rotating streamwise vortices, as demonstrated schematically in figure 3(b) and shown in detail by Jukes & Choi (2012, 2013. The result is low-speed streaks between the actuators with high-speed streaks on the outside, which are similar in shape but opposite in sign to the streaks generated by the isolated roughness element.…”

Section: Roughness Elementmentioning

confidence: 91%

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: 91%

Reactive control of isolated unsteady streaks in a laminar boundary layer

et al. 2016

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“…Thus stronger vortices are created by long, stream wise-oriented DBD plasma VGs at high voltage and/or frequency. For practical use, however, DBD plasma VGs can be easily configured into VG arrays [5] [6]. Different types of array may be produced by simply changing the configuration of the lower electrode (see Figure 4).…”

Section: Plasma Vortex Generatorsmentioning

confidence: 99%

“…DBD plasma VGs with staggered lower electrodes produce wall jets only on one side of each upper electrode, forming arrays of co-rotating vortices. Generally counter-rotating DBD plasma VGs are more effective for flow separation control due to larger wall-ward velocity component, but care should be taken to choose the correct spacing to prevent unfavorable interactions between adjacent vortices whilst maintaining sufficient coverage for effective flow control [5] [6].…”

Section: Plasma Vortex Generatorsmentioning

confidence: 99%

See 1 more Smart Citation

Plasma Virtual Actuators for Flow Control

Choi¹,

Jukes²,

Whalley³

et al. 2015

JFCMV

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Dielectric-barrier-discharge (DBD) plasma actuators are all-electric devices with no moving parts. They are made of a simple construction, consisting only of a pair of electrodes sandwiching a dielectric sheet. When AC voltage is applied, air surrounding the upper electrode is ionized, which is attracted towards the charged dielectric surface to form a wall jet. Control of flow over land and air vehicles as well as rotational machinery can be carried out using this jet flow on demand. Here we review recent developments in plasma virtual actuators for flow control that can replace conventional actuators for better aerodynamic performance.

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“…Although numerous publications are available, they focus primarily on the topic of turbulent separation control (Jukes et al [1], Schatzman and Thomas [2], and Poggie et al [3]) and parametric studies (Jukes and Choi [4] and Wicks et al [5]). One publication that reports the use of plasma actuators for active vortex generation in laminar boundary layers concerns the damping of streaks produced by roughness elements (Hanson et al [6]).…”

mentioning

confidence: 99%