Surface integral analogy approaches for predicting noise from 3D high-lift low-noise wings
Journal article, 2014

Three surface integral approaches of the acoustic analogies are studied to predict the noise from three conceptual configurations of three-dimensional high-lift low-noise wings. The approaches refer to the Kirchhoff method, the Ffowcs Williams and Hawkings (FW-H) method of the permeable integral surface and the Curle method that is known as a special case of the FW-H method. The first two approaches are used to compute the noise generated by the core flow region where the energetic structures exist. The last approach is adopted to predict the noise specially from the pressure perturbation on the wall. A new way to construct the integral surface that encloses the core region is proposed for the first two methods. Considering the local properties of the flow around the complex object-the actual wing with high-lift devices-the integral surface based on the vorticity is constructed to follow the flow structures. The surface location is discussed for the Kirchhoff method and the FW-H method because a common surface is used for them. The noise from the core flow region is studied on the basis of the dependent integral quantities, which are indicated by the Kirchhoff formulation and by the FW-H formulation. The role of each wall component on noise contribution is analyzed using the Curle formulation. Effects of the volume integral terms of Lighthill's stress tensors on the noise prediction are then evaluated by comparing the results of the Curle method with the other two methods.

CORRELATIONS

RADIATION

FORMULATION

MOVING SURFACES

TIME

LARGE-EDDY SIMULATION

High-lift facilities

Mechanical

Engineering

SOUND

GENERATION

KIRCHHOFF SURFACE

Surface integral approaches of acoustic analogy

Aero-acoustics

AEROACOUSTICS

TRAILING-EDGE NOISE

Mechanics

Author

Huadong Yao

Chalmers, Applied Mechanics, Fluid Dynamics

Lars Davidson

Chalmers, Applied Mechanics, Fluid Dynamics

Lars-Erik Eriksson

Chalmers, Applied Mechanics, Fluid Dynamics

Peng Shia-Hui

Chalmers, Applied Mechanics, Fluid Dynamics

O. Grundestam

Swedish Defence Research Agency (FOI)

P. Eliasson

Swedish Defence Research Agency (FOI)

Acta Mechanica Sinica/Lixue Xuebao

0567-7718 (ISSN)

Vol. 30 3 326-338

Subject Categories

Mechanical Engineering

DOI

10.1007/s10409-014-0008-y

More information

Latest update

2/27/2018