Phase shift and attenuation characteristics of acoustic waves in a flowing gas confined by cylindrical walls

Phase shift and attenuation characteristics of acoustic waves in a flowing gas confined by cylindrical walls

Wave propagation in flowing ideal gases confined by cylindrical waveguides is described in the low-frequency range using an iterative Frobenius series expansion method. The primary concern is to present a mathematical model enabling any radial-dependent flow profile to be analyzed. In contrast to pr...

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Bibliographic Details
Published in:Journal of sound and vibration Vol. 261; no. 5; pp. 791 - 804
Main Author: Willatzen, M.
Format: Journal Article
Language:English
Published: London Elsevier Ltd 10-04-2003
Elsevier
Subjects:
Acoustics
Aeroacoustics and atmospheric sound
Aeroacoustics, atmospheric sound
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Physics
Pipe flow
Phase shift
Radial flow
Numerical method
Wave damping
Experimental study
Low frequency
Modeling
Frobenius theorem
Gas flow
Cylindrical shell
Non linear effect
Aeroacoustics
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Summary:Wave propagation in flowing ideal gases confined by cylindrical waveguides is described in the low-frequency range using an iterative Frobenius series expansion method. The primary concern is to present a mathematical model enabling any radial-dependent flow profile to be analyzed. In contrast to previous analytical results, the present model is applicable in the general case where cubic and higher order terms in the axial acoustic velocity become important and to examine the influence of a non-vanishing radial velocity term. As a numerical test case, it is found that a gas flow velocity w( r)—for simplifying reasons assumed to be a linear combination of a flat flow profile and a parabolic flow profile corresponding to a mean flow equal to w ̄ —is well approximated by a flat flow profile of the same mean flow value w ̄ at low shear wavenumbers and at higher shear wavenumbers (calculations were done for shear wavenumbers up to 8). In actual fact, the error introduced by making this mean flow approximation is smaller than the error introduced by neglecting the radial velocity term.
ISSN:0022-460X
1095-8568
DOI:10.1016/S0022-460X(02)00990-2