Conversion of acoustic energy by lossless liners

doi:10.1016/S0022-460X(82)80018-7

Journal of Sound and Vibration

Volume 82, Issue 3, 8 June 1982, Pages 371-381

https://doi.org/10.1016/S0022-460X(82)80018-7 Get rights and content

The Blokhintzev acoustic energy equation is applied to a two-dimensional duct containing a uniform flow with a finite length lining. It is shown that the difference of the incident and outgoing acoustic energy differs in general from the energy dissipated in the liner, the difference being related to the displacements at the liner's edges. It is shown that in the case of a locally reacting lossless liner for frequencies below the first cut-off frequency and for low Mach number acoustic energy is generated if the flow and the incident sound wave are in the same direction and is absorbed if these two directions are opposite unless special edge conditions are met. Furthermore it is shown under the same conditions that the ratio of the reflection coefficient at finite flow velocity to the reflection coefficient at vanishing velocity is to first order in Mach number independent of the liner characteristics. A numerical calculation confirms these predictions at least for mass-like liner admittance.

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Cited by (7)

The effect of shear stress on the propagation and scattering of sound in flow ducts
1992, Journal of Sound and Vibration
The scattering of plane sound waves at a lined section of an otherwise rigid flow duct with circular cross-section is investigated theoretically and experimentally. Measurements have been carried out at low Mach numbers and at moderate frequencies. The lining consists of a pervious screen with a very low flow resistance backed by narrow cavities. Therefore, in the first instance, the liner can be modelled by a locally reacting yielding wall. Additionally, the wall shear stress originating from the interaction between the turbulent flow and the pervious wall affects the sound propagation in the lined duct and the sound scattering at the discontinuities of the wall compliance. The influence of the lateral gradients of the mean flow velocity and of the sound pressure have also been considered. The sound field is characterized by the flux of mass and momentum. Concerning the scattering of the plane wave at the discontinuities, it turns out that the plane-wave acoustical flux of mass and momentum are continuous at the interface: i.e., the effect of the near field at the discontinuity on the plane wave is negligibly small.
On the production and absorption of sound by lossless liners in the presence of mean flow
1984, Journal of Sound and Vibration
The interaction of sound with the leading and trailing edges of a nominally lossless acoustic liner is examined in the presence of mean flow. It is argued that acoustic energy is conserved only if the whole flow is irrotational. In practice the sound induces vorticity production at the liner, and in particular that generated at the edges of the liner leads to a net transfer of energy between the acoustic field and the mean flow. Analytical results are given for a “pressure release” liner in a rigid plane wall, it being concluded that there is a net production of acoustic energy at a trailing edge for all subsonic mean flow Mach numbers M. At a leading edge there is a net production or absorption of sound, depending on both the direction of propagation of the incident wave and the value of M.
Vortex sound in the presence of a low Mach number flow across a drum-like silencer
2011, Journal of the Acoustical Society of America
Near cut-on/cut-off transition in lined ducts with flow
2002, 8th AIAA/CEAS Aeroacoustics Conference and Exhibit
Energy conservation, time-reversal invariance and reciprocity in ducts with flow
2001, Journal of Fluid Mechanics
Eigensolutions for liners in uniform mean flow ducts
1983, AIAA Journal

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^†: This is a slightly modified version of a paper presented at the 7ème Colloque d'Acoustique Aéronautique, Lyon, 1980

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Conversion of acoustic energy by lossless liners†

Journal of Sound and Vibration

Journal of Sound and Vibration

Journal of Sound and Vibration

Journal of Sound and Vibration

Journal of Sound and Vibration

Journal of Sound and Vibration

Journal of Sound and Vibration

Journal of Sound and Vibration