Computation of mode radiation from a generic aeroengine intake
Computation of mode radiation from a generic aeroengine intake
The radiation of acoustic modes from an aeroengine intake duct is reviewed. The method is based upon a computational scheme which allows acoustic waves, propagating inside the intake duct of a generic aircraft engine, to be admitted into a computational domain that includes the duct section, the exit plane of the duct, and the surrounding flow. The method comprises three elements: a matching process to admit acoustic waves into the in-duct propagation region; near-field propagation inside the duct and diffraction at the lip of the duct; and an integral surface for far-field directivity. The wave admission is realised through an absorbing non-reflecting boundary treatment which admits incoming waves and damps spurious waves generated by the numerical solutions. The wave propagation and diffraction are calculated by solving either the linearised Euler equations or the full Euler equations, using high-order compact schemes. Far field directivity is estimated via an integral surface solution of the Ffowcs Williams - Hawkings equation. This paper compares the use of the Euler and linearised Euler equations in determining acoustic radiation. The case of wave propagation from a realistic aeroengine intake with background mean flow is used for the comparison. First, axi-symmetric acoustic radiation is studied using two different mean flows. One simulating the engine at a high power setting, the other a situation where the flow around the lip becomes locally supersonic. Spinning mode radiation is then examined with the solution of the full 3D Euler equations and a 2.5D linearised Euler model. The model requirements are discussed along with an assessment of the readiness of the methods for industrial applications.
computational aeroacoustics, aeroengine intake, duct acoustic modes, 2.5D, model, sideline
Richards, S.
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Chen, X.X.
1c7ce635-f117-4cb5-8f61-cb6a9b23d8a5
Zhang, X.
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Neittaanmaki, P.
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Rossi, T.
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Korotov, S.
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Onate, E.
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Periaux, J.
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Knorzer, D.
cb0ebe5e-91b5-4be7-b121-b8801725f175
2004
Richards, S.
231c6be9-3769-47b3-ae97-06ea844e0448
Chen, X.X.
1c7ce635-f117-4cb5-8f61-cb6a9b23d8a5
Zhang, X.
3056a795-80f7-4bbd-9c75-ecbc93085421
Neittaanmaki, P.
16c49c30-4bbc-45a0-aac0-cfd4c26504e6
Rossi, T.
4b045723-b8b4-4414-a1a9-9eb987580c30
Korotov, S.
c8d4f8d2-61d5-42be-a782-679cbbb27253
Onate, E.
f76bdf4e-c3e8-45c7-a960-5f7d05c982df
Periaux, J.
de20bf91-e36d-4f59-8e93-5a7174773696
Knorzer, D.
cb0ebe5e-91b5-4be7-b121-b8801725f175
Richards, S., Chen, X.X. and Zhang, X.
(2004)
Computation of mode radiation from a generic aeroengine intake.
Neittaanmaki, P., Rossi, T., Korotov, S., Onate, E., Periaux, J. and Knorzer, D.
(eds.)
European Congress on Computational Methods in Applied Sciences and Engineering: ECCOMAS 2004, Jyvaskyla, Finland.
24 - 28 Jul 2004.
20 pp
.
Record type:
Conference or Workshop Item
(Other)
Abstract
The radiation of acoustic modes from an aeroengine intake duct is reviewed. The method is based upon a computational scheme which allows acoustic waves, propagating inside the intake duct of a generic aircraft engine, to be admitted into a computational domain that includes the duct section, the exit plane of the duct, and the surrounding flow. The method comprises three elements: a matching process to admit acoustic waves into the in-duct propagation region; near-field propagation inside the duct and diffraction at the lip of the duct; and an integral surface for far-field directivity. The wave admission is realised through an absorbing non-reflecting boundary treatment which admits incoming waves and damps spurious waves generated by the numerical solutions. The wave propagation and diffraction are calculated by solving either the linearised Euler equations or the full Euler equations, using high-order compact schemes. Far field directivity is estimated via an integral surface solution of the Ffowcs Williams - Hawkings equation. This paper compares the use of the Euler and linearised Euler equations in determining acoustic radiation. The case of wave propagation from a realistic aeroengine intake with background mean flow is used for the comparison. First, axi-symmetric acoustic radiation is studied using two different mean flows. One simulating the engine at a high power setting, the other a situation where the flow around the lip becomes locally supersonic. Spinning mode radiation is then examined with the solution of the full 3D Euler equations and a 2.5D linearised Euler model. The model requirements are discussed along with an assessment of the readiness of the methods for industrial applications.
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Published date: 2004
Venue - Dates:
European Congress on Computational Methods in Applied Sciences and Engineering: ECCOMAS 2004, Jyvaskyla, Finland, 2004-07-24 - 2004-07-28
Keywords:
computational aeroacoustics, aeroengine intake, duct acoustic modes, 2.5D, model, sideline
Identifiers
Local EPrints ID: 22956
URI: http://eprints.soton.ac.uk/id/eprint/22956
PURE UUID: 4e331878-efeb-41dd-a001-9ba4d24cfcb8
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Date deposited: 05 Apr 2006
Last modified: 17 Apr 2023 16:51
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Contributors
Author:
S. Richards
Author:
X. Zhang
Editor:
P. Neittaanmaki
Editor:
T. Rossi
Editor:
S. Korotov
Editor:
E. Onate
Editor:
J. Periaux
Editor:
D. Knorzer
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