Investigation of Transitional SBLIs using Plasma Based Disturbances
ORAL
Abstract
Plasma-based disturbances are used to generate second-mode instability wave
packets in a Mach 5 laminar boundary layer (BL) and in the presence of a
cylinder induced shock boundary layer interaction (SBLI). The experiments
are performed in an indraft wind tunnel at fixed Reu = 2.7 x 106 m-1. Local-
ized Arc Filament Plasma Actuators (LAFPAs) are first characterized in a
vacuum chamber to determine the effect of ambient pressure on the plasma
regime and the electrical energy deposition. Linear Stability Theory (LST)
predicts that second-mode frequency content varies between 20 kHz to 30 kHz
over the length of the wind tunnel test section. Synchronized wall pressure
(PCB) measurements and phase-locked Z-type schlieren imaging are used to
characterize the instability waves created by actuation. Frequency and wave-
length of the observed second mode wave packets match well with estimates
from LST. In the presence of an SBLI, a decrease in the frequency and an
increase in the associated wavelength is observed. Future work will address
the introduction of stronger forcing to study non-linear wave packets as well
as extend the scope of measurements and data analysis techniques relevant
to transitional SBLIs.
packets in a Mach 5 laminar boundary layer (BL) and in the presence of a
cylinder induced shock boundary layer interaction (SBLI). The experiments
are performed in an indraft wind tunnel at fixed Reu = 2.7 x 106 m-1. Local-
ized Arc Filament Plasma Actuators (LAFPAs) are first characterized in a
vacuum chamber to determine the effect of ambient pressure on the plasma
regime and the electrical energy deposition. Linear Stability Theory (LST)
predicts that second-mode frequency content varies between 20 kHz to 30 kHz
over the length of the wind tunnel test section. Synchronized wall pressure
(PCB) measurements and phase-locked Z-type schlieren imaging are used to
characterize the instability waves created by actuation. Frequency and wave-
length of the observed second mode wave packets match well with estimates
from LST. In the presence of an SBLI, a decrease in the frequency and an
increase in the associated wavelength is observed. Future work will address
the introduction of stronger forcing to study non-linear wave packets as well
as extend the scope of measurements and data analysis techniques relevant
to transitional SBLIs.
–
Presenters
-
Antonio Harder
University of Arizona
Authors
-
Antonio Harder
University of Arizona
-
Ashish Singh
University of Arizona
-
James A Threadgill
University of Arizona
-
Jesse C Little
University of Arizona
-
Christoph Hader
University of Arizona
-
Hermann F Fasel
University of Arizona