INVESTIGADORES
ARTANA Guillermo Osvaldo
artículos
Título:
Electric wind produced by surface plasma actuators: a new dielectric barrier discharge based on a three-electrode geometry
Autor/es:
12. E. MOREAU, R. SOSA AND G. ARTANA
Revista:
JOURNAL OF PHYSICS - D (APPLIED PHYSICS)
Editorial:
IOP PUBLISHING LTD
Referencias:
Año: 2008 vol. 41 p. 115204 - 115216
ISSN:
0022-3727
Resumen:
Active flow control is a rapidly developing topic because the associated industrial applications
are of immense importance, particularly for aeronautics. Among all the flow control methods,
such as the use of mechanical flaps or wall jets, plasma-based devices are very promising
devices. The main advantages of such systems are their robustness, their simplicity, their
low-power consumption and that they allow a real-time control at high frequency. This paper
deals with an experimental study about the electric wind produced by a surface discharge
based on a three-electrode geometry. This new device is composed of a typical two-electrode
surface barrier discharge excited by an AC high voltage, plus a third electrode at which a DC
high voltage is applied in order to extend the discharge region and to accelerate the ion drift
velocity. In the first part the electrical current of these different surface discharges is presented
and discussed. This shows that the current behaviour depends on the DC component polarity.
The second part is dedicated to analysing the electric wind characteristics through Schlieren
visualizations and to measuring its time-averaged velocity with a Pitot tube sensor. The results
show that an excitation of the electrodes with an AC voltage plus a positive DC component can
significantly modify the topology of the electric wind produced by a single DBD. In practice,
this DC component allows us to increase the value of the maximum induced velocity (up to
+150% at a few centimetres downstream of the discharge) and the plasma extension, to enhance
the depression occurring above the discharge region and to increase the discharge-induced
mass flow rate (up to +100%), without increasing the electrical power consumption.), without increasing the electrical power consumption.