Accession Number : ADA440294


Title :   Effects of Boundary Layer Flow Control Using Plasma Actuator Discharges


Descriptive Note : Master Thesis, Mar-Sep 2005


Corporate Author : AIR FORCE INST OF TECH WRIGHT-PATTERSON AFB OH SCHOOL OF ENGINEERING AND MANAGEMENT


Personal Author(s) : Newcamp, Jeffrey M


Full Text : https://apps.dtic.mil/dtic/tr/fulltext/u2/a440294.pdf


Report Date : Sep 2005


Pagination or Media Count : 125


Abstract : This study addresses the usage and effects of atmospheric plasma discharges on the near wall flow conditions for a Pak-B low-pressure turbine blade. A plasma actuator was built normal to the freestream flow in a low-speed wind tunnel. The test section of the wind tunnel had a contoured upper wall geometry designed to mimic the suction side of a Pak-B turbine blade. A high frequency ac voltage source supplied three voltages in the kilovolt range at four Reynolds numbers in the experiment, between 10,000 and 103,000. The effect of the plasma on the near-wall boundary layer conditions was evaluated at each of the Reynolds numbers and each of the three voltage levels. The corresponding power levels were between 15 and 25 W. Particle image velocimetry (PIV) was used to determine the 2D boundary layer characteristics of the flow. This research showed that the plasma discharges were able to dramatically increase the flow velocity near the wall; however, the plasma was unable to reattach an already detached boundary layer. Boundary layer traces were taken to validate the PIV results. Additionally, multiple manufacturing techniques were evaluated in an effort to make the electrodes more usable in turbine blade applications.


Descriptors :   *PLASMAS(PHYSICS) , *ACTUATORS , *BOUNDARY LAYER CONTROL , *BOUNDARY LAYER FLOW , *GLOW DISCHARGES , VELOCITY , POWER LEVELS , TEST EQUIPMENT , FREE STREAM , WIND TUNNELS , PARTICLE IMAGE VELOCIMETRY , CONTOURS , REYNOLDS NUMBER , SUCTION , LOW VELOCITY , GEOMETRY , TURBINE BLADES , VOLTAGE , MANUFACTURING


Subject Categories : Electricity and Magnetism
      Fluid Mechanics
      Plasma Physics and Magnetohydrodynamics


Distribution Statement : APPROVED FOR PUBLIC RELEASE