Unsteady Plasma Actuators for Separation Control of Low-Pressure Turbine Blades

“…Introduction T HERE is currently considerable interest in the use of single dielectric barrier discharge (SDBD) plasma actuators for aerodynamic flow control. The diverse applications are too numerous to list here but include, for example, active airfoil leading edge separation control [1,2], control of airfoil dynamic stall [3], bluff body flow control [4][5][6][7][8], boundary layer flow control [9][10][11], highlift applications [12], and turbomachinery flow control [13][14][15], to name just a few. The physics surrounding the operation of SDBD plasma actuators has been the focus of several studies [16][17][18][19] and the mechanism of actuation is now fairly well understood.…”

Optimization of Dielectric Barrier Discharge Plasma Actuators for Active Aerodynamic Flow Control

“…Introduction T HERE is currently considerable interest in the use of single dielectric barrier discharge (SDBD) plasma actuators for aerodynamic flow control. The diverse applications are too numerous to list here but include, for example, active airfoil leading edge separation control [1,2], control of airfoil dynamic stall [3], bluff body flow control [4][5][6][7][8], boundary layer flow control [9][10][11], highlift applications [12], and turbomachinery flow control [13][14][15], to name just a few. The physics surrounding the operation of SDBD plasma actuators has been the focus of several studies [16][17][18][19] and the mechanism of actuation is now fairly well understood.…”

Optimization of Dielectric Barrier Discharge Plasma Actuators for Active Aerodynamic Flow Control

“…Post and Corke [17,18] successfully demonstrated their use in the control of separation over stationary and oscillating airfoils. Huang et al [19,20] also used them to control separation over turbine blades. A review is provided by Corke and Post [21].…”

Flow Control over a Conical Forebody Using Duty-Cycled Plasma Actuators

“…Different plasma actuators can be operated in various modes, depending on their geometrical configuration and the kind of high voltage applied (e.g., Nanosecond pulsed DBD, plasma synthetic jet, sliding DBD, Pulse DBD actuators). Very promising results for the application of plasma actuators have been observed in a wide range of aeronautic applications (boundary layer transition control [7], Separation control [8,10], control of a subsonic rotor blade wake [11], increasing the lift on a UAV [12], noise reduction [13] and pressure sensor [14], elimination of low Reynolds number separation in Low-Pressure Turbine flows [15] and reduction of the effects of turbine tip leakage [16]). …”

“…In this configuration, two electrodes are typically separated by a dielectric barrier usually made of glass, Kapton or teflon as depicted in Figure 1. When a high AC voltage signal, of sufficient amplitude (5-40kVpp ) and frequency (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20), is applied between the electrodes the intense electric field partially ionizes the surrounding air, producing a nonthermal plasma on the dielectric surface. The collisions between the neutral particles and accelerated ions generate a net body force on the surrounding fluid.…”

Numerical modeling of coanda effect in a novel propulsive system