An indirect method for the characterization of locally reacting liners
An indirect method for the characterization of locally reacting liners
An indirect technique for educing the homogenized acoustic impedance of a liner mounted on the wall of a barrel is presented. It is based on measurements and computational simulations of the multimodal scattering matrix of this lined duct. Measurements are performed with a multisource method and the use of an anechoic duct termination. The numerical computation of the scattering matrix relies on a finite element model, and assume that the duct is axisymmetric and uniformly covered by a locally reacting material. The impedance is educed by minimizing the difference between the theoretical and experimental acoustic power dissipations, which are deduced from the scattering matrix. The source is an incoming pressure field generated at one end of the duct only and composed of all cut-on modes. This technique was tested on a cylindrical barrel whose wall was partially lined with a realistic, locally reacting material made of honeycomb cells and a perforated facing sheet. Results for the acoustic impedance are compared with those deduced from semiempirical models and the experimental two microphone method. The best agreement with the indirect method is found with the semiempirical impedance results when the difference between the acoustic power dissipated by the actual lined barrel and the reference barrel is chosen as the cost function of the minimizing procedure.
acoustic impedance, acoustic materials, acoustic variables measurement, acoustic wave propagation, acoustic wave scattering, ducts, finite element analysis, noise abatement
3548-3559
Taktak, Mohamed
97645be0-3416-4239-acf0-aada2ce379e8
Ville, Jean Michel
6fb94f58-4928-464d-a276-916514a0a018
Haddar, Mohamed
b8dd8a0e-7702-4a03-9c08-83686bf54e10
Gabard, Gwenael
bfd82aee-20f2-4e2c-ad92-087dc8ff6ce7
Foucart, Felix
78c6612b-7949-47fb-ad82-7060797f5cdf
June 2010
Taktak, Mohamed
97645be0-3416-4239-acf0-aada2ce379e8
Ville, Jean Michel
6fb94f58-4928-464d-a276-916514a0a018
Haddar, Mohamed
b8dd8a0e-7702-4a03-9c08-83686bf54e10
Gabard, Gwenael
bfd82aee-20f2-4e2c-ad92-087dc8ff6ce7
Foucart, Felix
78c6612b-7949-47fb-ad82-7060797f5cdf
Taktak, Mohamed, Ville, Jean Michel, Haddar, Mohamed, Gabard, Gwenael and Foucart, Felix
(2010)
An indirect method for the characterization of locally reacting liners.
Journal of the Acoustical Society of America, 127 (6), .
(doi:10.1121/1.3365250).
Abstract
An indirect technique for educing the homogenized acoustic impedance of a liner mounted on the wall of a barrel is presented. It is based on measurements and computational simulations of the multimodal scattering matrix of this lined duct. Measurements are performed with a multisource method and the use of an anechoic duct termination. The numerical computation of the scattering matrix relies on a finite element model, and assume that the duct is axisymmetric and uniformly covered by a locally reacting material. The impedance is educed by minimizing the difference between the theoretical and experimental acoustic power dissipations, which are deduced from the scattering matrix. The source is an incoming pressure field generated at one end of the duct only and composed of all cut-on modes. This technique was tested on a cylindrical barrel whose wall was partially lined with a realistic, locally reacting material made of honeycomb cells and a perforated facing sheet. Results for the acoustic impedance are compared with those deduced from semiempirical models and the experimental two microphone method. The best agreement with the indirect method is found with the semiempirical impedance results when the difference between the acoustic power dissipated by the actual lined barrel and the reference barrel is chosen as the cost function of the minimizing procedure.
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Published date: June 2010
Keywords:
acoustic impedance, acoustic materials, acoustic variables measurement, acoustic wave propagation, acoustic wave scattering, ducts, finite element analysis, noise abatement
Identifiers
Local EPrints ID: 157969
URI: http://eprints.soton.ac.uk/id/eprint/157969
ISSN: 0001-4966
PURE UUID: 73dfd66c-e143-4349-8dc2-b43118223c6e
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Date deposited: 14 Jun 2010 11:12
Last modified: 14 Mar 2024 01:49
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Contributors
Author:
Mohamed Taktak
Author:
Jean Michel Ville
Author:
Mohamed Haddar
Author:
Gwenael Gabard
Author:
Felix Foucart
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