2008
DOI: 10.2514/1.33388
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Dielectric Barrier Discharge Flow Control at Very Low Flight Reynolds Numbers

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Cited by 116 publications
(43 citation statements)
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References 26 publications
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“…For their inclined flat plate, they employed a wavelet algorithm to detect large-scale vortices in time-resolved particle image velocimetry (PIV) data, which revealed an interesting coalescence of smaller vortices produced near the actuator into one large coherent vortex advecting down the plate per cycle of actuation, in the case of f + = 1 (St = 0.23), and into two coherent vortices per cycle of actuation when f + = 0.5, both of which imply vortex shedding at St = 0.23. A similar configuration (with a dielectric-barrier discharge actuator) was studied by Greenblatt et al [27] (flat plate) and Benard et al [28] (NACA0015). For the flat plate at a = 20 • , 0.3 < f + < 0.6 provided the best lift enhancement, whereas f + > 3 was ineffective, and smoke visualization at f + = 0.4 showed a strong vortex advecting downstream along the chord; f + = 1.5 was optimal for a NACA0015 at a = 16 • .…”
Section: (B) Actuated Flowsmentioning
confidence: 89%
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“…For their inclined flat plate, they employed a wavelet algorithm to detect large-scale vortices in time-resolved particle image velocimetry (PIV) data, which revealed an interesting coalescence of smaller vortices produced near the actuator into one large coherent vortex advecting down the plate per cycle of actuation, in the case of f + = 1 (St = 0.23), and into two coherent vortices per cycle of actuation when f + = 0.5, both of which imply vortex shedding at St = 0.23. A similar configuration (with a dielectric-barrier discharge actuator) was studied by Greenblatt et al [27] (flat plate) and Benard et al [28] (NACA0015). For the flat plate at a = 20 • , 0.3 < f + < 0.6 provided the best lift enhancement, whereas f + > 3 was ineffective, and smoke visualization at f + = 0.4 showed a strong vortex advecting downstream along the chord; f + = 1.5 was optimal for a NACA0015 at a = 16 • .…”
Section: (B) Actuated Flowsmentioning
confidence: 89%
“…Recent studies have also documented the effect of the waveform on performance. It appears that periodic but pulsatile actuation or modulated highfrequency sinusoidal oscillation can produce performance equal to or greater than sinusoidal actuation at the same frequency [26,27,[29][30][31]. Indeed, it appears that pulses with as low a duty cycle as 5 per cent can be effective [27].…”
Section: (B) Actuated Flowsmentioning
confidence: 99%
“…The objectives for separation control have covered various types of fluid and transport machinery. For the twodimensional airfoil flows, NACA airfoils [5][6][7][8][9][10], a flat-plate airfoil [11,12], and a low-Reynolds-number airfoil [13,14] have been investigated. Moreover, a linear cascade of turbine blades [15][16][17], a vertical-axis wind turbine [18], and cylinder and bluff-body flows [19][20][21][22] have also been the target of flow separation control.…”
mentioning
confidence: 99%
“…[36][37][38][39][40][41] The actuator consists of two horizontally displaced electrodes separated by a dielectric material. The powered electrode is typically exposed to the surrounding gas, and the grounded electrode embedded beneath the dielectric.…”
Section: Micro-second Pulsed Dbd Plasma Actuatorsmentioning
confidence: 99%