6533b7d7fe1ef96bd12678f2
RESEARCH PRODUCT
A vorticity based aeroacoustic prediction for the noise emission of a low-speed turbulent internal flow
G. TassoneR.m.a. Marrettasubject
Physics::Fluid DynamicsPhysicsGeneral Computer ScienceGround effect (cars)TurbulenceK-epsilon turbulence modelInternal flowComputationGeneral EngineeringEnclosureAeroacousticsMechanicsVorticitydescription
Abstract Turbulent internal flows are known to generate intense noise as well as surface pressure fluctuations. Numerically predicting the noise emission near the prescribed boundaries requires that the sound-generating turbulent flow be adequately represented and described. The k – e method provides a promising tool for obtaining the unsteady characteristics of a realistic turbulent flow interacting with a rectangular flat plate undergoing “ground effect”. The far-field acoustic calculation is facilitated by the Kambe model (from Lighthill’s theory) and an original post-processor has been developed to determine the far-field spectra and the source term characteristics. In pre-processed turbulent confined flows inside a rectangular enclosure, computations using the k – e method, coupled with a convenient post-processor, is used to predict noise radiation over a wide range of frequencies and geometrical configurations. The portability and effectiveness of the present method, however, start to be less evident when the turbulent flow has very chaotic internal features; these suggest the need for a wider computational aeroacoustic domain and a new procedure suitable for the turbulent flow representation.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2003-05-01 | Computers & Fluids |