Helmut V. Fuchs scite author profile

The noise produced by mean flow-turbulence interaction of a circular subsonic jet is investigated theoretically, and expanded in azimuthal constituents of the turbulent pressure fluctuations. It is found that the low-order azimuthal constituents are the most efficient sound sources. On the basis of pressure correlation measurements, the azimuthal constituents are determined in a low Mach number jet. It is found that, in a range of Strouhal numbers between 0·2 and 1, the first three to four azimuthal constituents clearly dominate over the rest of the turbulent source quantity. A strictly axisymmetric ring vortex model for the coherent structure of the turbulence is, however, shown to be inappropriate.

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Predicting the Absorption of Open Weave Textiles and Micro-Perforated Membranes Backed by an Air Space

Kang

Fuchs

1999

Journal of Sound and Vibration

155

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On the mean-field theory of the Karlsruhe Dynamo Experiment

Rädler

Rheinhardt

Apstein

et al. 2002

Nonlin. Processes Geophys.

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The intrinsic structure of turbulent jets

Lau¹,

Fisher

Fuchs

1972

Journal of Sound and Vibration

125

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Large-scale coherent structures in the wake of axisymmetric bodies

Fuchs

Mercker

Michel³

1979

J. Fluid Mech.

111

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The unsteady flow past a circular disk is studied with hot-wire and microphone probes positioned in planes normal to the axis of symmetry at 3 and 9 disk diameters down-stream. Both the fluctuating velocity and pressure signals are shown to be continuously dominated by large-scale coherent motions enveloping the wake flow as a whole. This suggests narrowband two-point space correlations as an experimental tool for describing spatial coherence and phase characteristics of the basically random signals. The specific symmetry imposed by the axisymmetric boundary conditions of the disk enables a decomposition of the large-scale flow phenomena into relatively simple elementary structures or modes. The resulting azimuthal constituents are quantified in terms of their respective magnitudes and individual power spectra.The capability of the approach to uncover characteristic features of turbulence as far as its large-scale domain is concerned is demonstrated by a comparison of the present results with certain remarkably different features found in earlier jet flow investigations: the m = 1 and m = 2 modes are found to clearly dominate in wakes whereas the m = 0 and m = 1 modes were dominant in jets in a relevant range of Strouhal numbers. These large-scale coherent structures are more than just an interesting flow phenomenon; they must have a tremendou back-reaction on rigid flow boundaries (particularly if these allow a vibrational response) and may give rise to specific feedback mechanisms.The analysing technique proposed for studying large-scale flow phenomena injets and wakes removes part of the randomness in the turbulent signals without artificially exciting or forcing them in one way or another. No conditional sampling of the naturally occurring fluctuations is required, either. The method may be applicable to other than strictly axisymmetric flow configurations, too.

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Applied Acoustics: Concepts, Absorbers, and Silencers for Acoustical Comfort and Noise Control

Fuchs¹

2013

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Coherent Structures in Jet Turbulence and Noise

1977

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Helmut V. Fuchs

Ten years of experience with leak detection by acoustic signal analysis

On turbulence and noise of an axisymmetric shear flow

Predicting the Absorption of Open Weave Textiles and Micro-Perforated Membranes Backed by an Air Space

On the mean-field theory of the Karlsruhe Dynamo Experiment

The intrinsic structure of turbulent jets

Large-scale coherent structures in the wake of axisymmetric bodies

Applied Acoustics: Concepts, Absorbers, and Silencers for Acoustical Comfort and Noise Control

Coherent Structures in Jet Turbulence and Noise

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