Abstract
The dielectric barrier discharge plasma actuator is a promising flow control device that uses surface discharge. The actuator generates an electrohydrodynamic force and Joule heating that contribute to the flow control. Thus, it is important to investigate the electrohydrodynamic and thermal effects on the air flow. To this end, the flow velocity field, density field, and surface temperature distribution induced by an alternating current dielectric barrier discharge plasma actuator were experimentally examined, adopting particle image velocimetry, the background oriented schlieren technique, and an infrared camera. These experiments were conducted for plate- and wire-exposed electrode plasma actuators to investigate the effect of the shape of the exposed electrode. It was confirmed that the topology of the discharge is different between the two types of plasma actuators. This results in a difference in the spatial distributions of the velocity and density fields between the two actuators. In particular, we clarified that there is an obvious difference in the peak position of the density and temperature distribution between the two actuators. We also confirmed that the difference in the spatial distribution of the vertical velocity makes the above difference.
Highlights
The above section clarified the qualitative characteristics of the flow fields, generated by the two types of PA
particle image velocimetry (PIV), aPIV, BOSa measurement, a surface temperature measurement using an IR camcamera, and discharge emission imaging were conducted for the plateand wire-PA
It was It was first clarified that the topology of the discharge was different between the two types of first clarified that the topology of the discharge was different between the two types of PA
Summary
The dielectric barrier discharge plasma actuator is a promising flow control device that uses surface discharge. It is important to investigate the electrohydrodynamic and the heat effects generation et al. Joule heating, the charged particles absorb the electric field energy ture distribution induced by an alternating current dielectric barrier discharge plasma actuator were through their motion (i.e.,adopting the discharge and particle (electrical experimentally examined, particlecurrent) image velocimetry, thecollisions background orientedresistivschlieren ity). Joule heating of the charged particles causes the gas heating, resulting in pressure technique, and an infrared camera. These experiments were conducted for plate- and wire-exposed and density perturbation in investigate the gas [13,14]
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