Point collocation scheme in silencers with temperature gradient and mean flow
Point collocation scheme in silencers with temperature gradient and mean flow
This work presents a mathematical approach based on the point collocation technique to compute the transmission loss of perforated dissipative silencers with transversal temperature gradients and mean flow. Three-dimensional wave propagation is considered in silencer geometries with arbitrary, but axially uniform, cross section. To reduce the computational requirements of a full multidimensional finite element calculation, a method is developed combining axial and transversal solutions of the wave equation. First, the finite element method is employed in a two-dimensional problem to extract the eigenvalues and associated eigenvectors for the silencer cross section. Mean flow as well as transversal temperature gradients and the corresponding thermal-induced material heterogeneities are included in the model. In addition, an axially uniform temperature field is taken into account, its value being the inlet/outlet average. A point collocation technique is then used to match the acoustic fields (pressure and axial acoustic velocity) at the geometric discontinuities between the silencer chamber and the inlet and outlet pipes. Transmission loss predictions are compared favorably with a general three-dimensional finite element approach, offering a reduction in the computational effort.
127-141
Denia, F.D.
5a64479b-10d6-482b-8f25-dc5b4ef39780
Sánchez-Orgaz, E.M.
13a66172-8b1f-474f-a3e1-137da7e5536c
Baeza, L.
09dc5565-ad4b-49af-a104-d4b6ad28e1b0
Kirby, R.
f8b19b66-86f1-4336-8f16-9dd5b1b63d69
1 January 2016
Denia, F.D.
5a64479b-10d6-482b-8f25-dc5b4ef39780
Sánchez-Orgaz, E.M.
13a66172-8b1f-474f-a3e1-137da7e5536c
Baeza, L.
09dc5565-ad4b-49af-a104-d4b6ad28e1b0
Kirby, R.
f8b19b66-86f1-4336-8f16-9dd5b1b63d69
Denia, F.D., Sánchez-Orgaz, E.M., Baeza, L. and Kirby, R.
(2016)
Point collocation scheme in silencers with temperature gradient and mean flow.
Journal of Computational and Applied Mathematics, 291, .
(doi:10.1016/j.cam.2015.02.007).
Abstract
This work presents a mathematical approach based on the point collocation technique to compute the transmission loss of perforated dissipative silencers with transversal temperature gradients and mean flow. Three-dimensional wave propagation is considered in silencer geometries with arbitrary, but axially uniform, cross section. To reduce the computational requirements of a full multidimensional finite element calculation, a method is developed combining axial and transversal solutions of the wave equation. First, the finite element method is employed in a two-dimensional problem to extract the eigenvalues and associated eigenvectors for the silencer cross section. Mean flow as well as transversal temperature gradients and the corresponding thermal-induced material heterogeneities are included in the model. In addition, an axially uniform temperature field is taken into account, its value being the inlet/outlet average. A point collocation technique is then used to match the acoustic fields (pressure and axial acoustic velocity) at the geometric discontinuities between the silencer chamber and the inlet and outlet pipes. Transmission loss predictions are compared favorably with a general three-dimensional finite element approach, offering a reduction in the computational effort.
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e-pub ahead of print date: 12 February 2015
Published date: 1 January 2016
Additional Information:
cited By 2
Organisations:
Modern Languages and Linguistics, Dynamics Group
Identifiers
Local EPrints ID: 410574
URI: http://eprints.soton.ac.uk/id/eprint/410574
ISSN: 0377-0427
PURE UUID: 40000ebc-e7e3-4818-a526-a94f214a223b
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Date deposited: 09 Jun 2017 09:08
Last modified: 15 Mar 2024 13:56
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Author:
F.D. Denia
Author:
E.M. Sánchez-Orgaz
Author:
L. Baeza
Author:
R. Kirby
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