Low-Frequency Unsteadiness in Turbulent Elliptic Wakes

Low-Frequency Unsteadiness in Turbulent Elliptic Wakes

Velocity fluctuations in the near wake of an elliptic disk are analyzed by the wavelet transform with Morlet wavelet. The wavelet transform demonstrates two dominant periodic components in the velocity fluctuations. The periodic components, which correspond to an alternate vortex shedding in the min...

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Bibliographic Details
Published in:JSME International Journal Series B Fluids and Thermal Engineering Vol. 42; no. 3; pp. 349 - 354
Main Authors: ABE, Yukinobu, KIYA, Masaru, MOCHIZUKI, Osamu
Format: Journal Article
Language:English
Published: Tokyo The Japan Society of Mechanical Engineers 1999
Japan Society of Mechanical Engineers
Japan Science and Technology Agency
Subjects:
Coherent Structure
Elliptic Disk
Exact sciences and technology
Fluid Dynamics
Fundamental areas of phenomenology (including applications)
Jets
Low-Frequency Unsteadiness
Physics
Rotational flow and vorticity
Separated flows
Turbulence
Turbulent flows, convection, and heat transfer
Unsteady flow
Vortex Shedding
Wake
Wakes
Wavelet Transform
Wavelet transforms
Cross correlations
Wavelet transforms
Vortex shedding
Turbulent flow
Power spectra
Elliptic plate
Wakes
Instrumentation
Velocity distribution
Vortex flow
Experimental study
Turbulence structure
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Summary:Velocity fluctuations in the near wake of an elliptic disk are analyzed by the wavelet transform with Morlet wavelet. The wavelet transform demonstrates two dominant periodic components in the velocity fluctuations. The periodic components, which correspond to an alternate vortex shedding in the minor plane and a meandering motion in the major plane, are found to have a low-frequency unsteadiness. The modulus of the wavelet transform reveals that the low-frequency unsteadiness has a central frequency of approximately one-fifth of the frequency of the corresponding periodic component in each plane. Moreover, the unsteadiness is in phase on both sides of the wake in the same plane but out of phase in the different planes. The unsteadiness is of large spatial extent in that the representative wavelength of the low-frequency unsteadiness is of the order of 30 minor diameters.
Bibliography:ObjectType-Article-2
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content type line 23
ISSN:1340-8054
1347-5371
DOI:10.1299/jsmeb.42.349