News Release

Wrangling flow to quiet cars and aircraft

'Serpentine plasma actuators' described in Journal of Applied Physics may reduce noise and drag and increase fuel efficiency for future land and air vehicles

Peer-Reviewed Publication

American Institute of Physics

Flow Structures

image: Comparison of turbulent flow structures over an airfoil when a pulsed linear (left) and a serpentine (right) plasma actuator are used to control the flow. view more 

Credit: M. Riherd, APRG

WASHINGTON D.C. Oct. 18, 2013 -- Plasmas are a soup of charged particles in an electric field, and are normally found in stars and lightning bolts. With the use of high voltage equipment, very small plasmas can be used to manipulate fluid flows. In recent years, the development of devices known as plasma actuators has advanced the promise of controlling flows in new ways that increase lift, reduce drag and improve aerodynamic efficiencies -- advances that may lead to safer, more efficient and more quiet land and air vehicles in the near future.

Unlike other flow control devices, plasma actuator geometries can be easily modified. Enter the serpentine shape, courtesy of the Applied Physics Research Group (APRG), a University of Florida research team in Gainesville that has been developing this and other types of novel plasma actuators for several years. The serpentine's sinuous, ribbon-like curves appear to impart greater levels of versatility than traditional geometries used in plasma flow control devices, according to Mark Riherd, a doctoral candidate working under Subrata Roy, the founding director of APRG.

"Our serpentine device will have applications in reducing drag-related fuel costs for an automobile or an aircraft, minimizing the noise generated when flying over populated areas, mixing air-fuel mixtures for lean combustion, and enhancing heat transfer by generating local turbulence," Riherd said.

In a report appearing in the Journal of Applied Physics, which is produced by AIP Publishing, the team validated the complex, three-dimensional flow structures induced by their serpentine plasma actuators by comparing numerical results with recent physical experiments in non-moving air. They then simulated the effects of the actuators in a non-turbulent boundary layer and over a small aircraft wing. Further tests are needed, but early results suggest serpentine flow wrangling may improve transportation efficiencies.

"This may result in significant weight and fuel savings for future aircraft and automobiles, improving energy efficiency all around," Riherd said.

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The article, "On Using Serpentine Geometry Plasma Actuators for Flow Control" by Mark Riherd and Subrata Roy appears in the Journal of Applied Physics. See: http://dx.doi.org/10.1063/1.4818622

ABOUT THE JOURNAL

The Journal of Applied Physics, produced by AIP Publishing, is an influential international journal featuring significant new experimental and theoretical results of applied physics research. See: http://jap.aip.org


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