Effect of Airfoil Aerodynamic Loading on Trailing Edge Noise Sources

Stéphane Moreau; Michel Roger

doi:10.2514/1.5578

Noise source location and scaling of subsonic upper-surface blowing

International Journal of Aeroacoustics ◽

10.1177/1475472x20930652 ◽

2020 ◽

Vol 19 (3-5) ◽

pp. 191-206

Author(s):

Trae L Jennette ◽

Krish K Ahuja

Keyword(s):

Strouhal Number ◽

Noise Source ◽

Low Frequency ◽

Directivity Pattern ◽

Source Location ◽

Dipole Source ◽

Frequency Noise ◽

Noise Sources ◽

Trailing Edge ◽

Trailing Edge Noise

This paper deals with the topic of upper surface blowing noise. Using a model-scale rectangular nozzle of an aspect ratio of 10 and a sharp trailing edge, detailed noise contours were acquired with and without a subsonic jet blowing over a flat surface to determine the noise source location as a function of frequency. Additionally, velocity scaling of the upper surface blowing noise was carried out. It was found that the upper surface blowing increases the noise significantly. This is a result of both the trailing edge noise and turbulence downstream of the trailing edge, referred to as wake noise in the paper. It was found that low-frequency noise with a peak Strouhal number of 0.02 originates from the trailing edge whereas the high-frequency noise with the peak in the vicinity of Strouhal number of 0.2 originates near the nozzle exit. Low frequency (low Strouhal number) follows a velocity scaling corresponding to a dipole source where as the high Strouhal numbers as quadrupole sources. The culmination of these two effects is a cardioid-shaped directivity pattern. On the shielded side, the most dominant noise sources were at the trailing edge and in the near wake. The trailing edge mounting geometry also created anomalous acoustic diffraction indicating that not only is the geometry of the edge itself important, but also all geometry near the trailing edge.

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Trailing-edge noise reduction of a wing by a surface modification

INTER-NOISE and NOISE-CON Congress and Conference Proceedings ◽

10.3397/in-2021-2326 ◽

2021 ◽

Vol 263 (3) ◽

pp. 3194-3201

Author(s):

Varun Bharadwaj Ananthan ◽

R.A.D. Akkermans ◽

Dragan Kozulovic

Keyword(s):

Noise Reduction ◽

Stochastic Approach ◽

Slight Reduction ◽

Noise Sources ◽

Trailing Edge ◽

Sound Sources ◽

Airframe Noise ◽

Trailing Edge Noise ◽

Random Particle ◽

Noise Production

There is an increased emphasis on reducing airframe noise in the last decades. Airframe noise is sound generated by the interaction of a turbulent flow with the aircraft geometry, and significantly contributes to the overall noise production during the landing phase. One examples of airframe noise is the noise generated at a wing's trailing edge, i.e., trailing-edge noise. In this contribution, we numerically explore the local application of riblets for the purpose of trailing-edge noise reduction. Two configurations are studied: i) a clean NACA0012 wing section as a reference, and ii) the same configuration with riblets installed at the wing's aft part. The numerical investigation follows a hybrid computational aeroacoustics approach, where the time-average flow is studied by means of RANS. Noise sources are generated by means of a stochastic approach called Fast Random Particle Mesh method. The results show a deceleration of the flow behind the riblets. Furthermore, the turbulent kinetic energy indicates increased unsteadiness behind the riblets which is shifted away from the wall due to the presence of the riblets. Lastly, the sound sources are investigated by means of the 3D Lamb-vector, which indicates a slight reduction in magnitude near the trailing edge.

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Experimental Investigation Into Trailing Edge Noise Sources

12th AIAA/CEAS Aeroacoustics Conference (27th AIAA Aeroacoustics Conference) ◽

10.2514/6.2006-2476 ◽

2006 ◽

Cited By ~ 5

Author(s):

Ana Garcia-Sagrado ◽

Tom Hynes ◽

Howard Hodson

Keyword(s):

Experimental Investigation ◽

Noise Sources ◽

Trailing Edge ◽

Trailing Edge Noise

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A Study on Trailing Edge Noise Sources Using High~Speed Particle Image Velocimetry

New Results in Numerical and Experimental Fluid Mechanics V - Notes on Numerical Fluid Mechanics and Multidisciplinary Design (NNFM) ◽

10.1007/978-3-540-33287-9_46 ◽

2006 ◽

pp. 373-380 ◽

Cited By ~ 6

Author(s):

A. Schröfer ◽

M. Herr ◽

T. Lauke ◽

U. Dierksheide

Keyword(s):

Particle Image Velocimetry ◽

High Speed ◽

Particle Image ◽

Noise Sources ◽

Trailing Edge ◽

Trailing Edge Noise ◽

Image Velocimetry

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On Interaction of Airfoil Leading and Trailing Edge Noise Sources in Turbulent Flow

17th AIAA/CEAS Aeroacoustics Conference (32nd AIAA Aeroacoustics Conference) ◽

10.2514/6.2011-2859 ◽

2011 ◽

Cited By ~ 4

Author(s):

Vladimir Golubev ◽

Lap Nguyen ◽

Michel Roger ◽

Miguel Visbal

Keyword(s):

Turbulent Flow ◽

Noise Sources ◽

Trailing Edge ◽

Trailing Edge Noise

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Trailing edge noise theory for rotating blades in uniform flow

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2013.0065 ◽

2013 ◽

Vol 469 (2157) ◽

pp. 20130065 ◽

Cited By ~ 19

Author(s):

S. Sinayoko ◽

M. Kingan ◽

A. Agarwal

Keyword(s):

Angular Frequency ◽

Rotational Frequency ◽

Mean Flow ◽

Noise Sources ◽

Trailing Edge ◽

Trailing Edge Noise ◽

Rotating Blades ◽

Noise Radiation ◽

Cooling Fan ◽

New Formulation

This paper presents a new formulation for trailing edge noise radiation from rotating blades based on an analytical solution of the convective wave equation. It accounts for distributed loading and the effect of mean flow and spanwise wavenumber. A commonly used theory due to Schlinker and Amiet predicts trailing edge noise radiation from rotating blades. However, different versions of the theory exist; it is not known which version is the correct one, and what the range of validity of the theory is. This paper addresses both questions by deriving Schlinker and Amiet's theory in a simple way and by comparing it with the new formulation, using model blade elements representative of a wind turbine, a cooling fan and an aircraft propeller. The correct form of Schlinker and Amiet's theory is identified. It is valid at high enough frequency, i.e. for a Helmholtz number relative to chord greater than one and a rotational frequency much smaller than the angular frequency of the noise sources.

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Identification of Noise Sources in a Realistic Turbofan Rotor Using Large Eddy Simulation

Acoustics ◽

10.3390/acoustics2030037 ◽

2020 ◽

Vol 2 (3) ◽

pp. 691-706

Author(s):

Pavel Kholodov ◽

Stéphane Moreau

Keyword(s):

Large Eddy Simulation ◽

Dynamic Mode Decomposition ◽

Dynamic Mode ◽

Noise Sources ◽

Trailing Edge ◽

Trailing Edge Noise ◽

Eddy Simulation ◽

Mode Decomposition ◽

Edge Radiation ◽

Large Eddy

Large Eddy Simulation is performed using the NASA Source Diagnostic Test turbofan at approach conditions (62% of the design speed). The simulation is performed in a periodic domain containing one fan blade (rotor-alone configuration). The aerodynamic and acoustic results are compared with experimental data. The dilatation field and the dynamic mode decomposition (DMD) are employed to reveal the noise sources around the rotor. The trailing-edge radiation is effective starting from 50% of span. The strongest DMD modes come from the tip region. Two major noise contributors are shown, the first being the tip noise and the second being the trailing-edge noise. The Ffowcs Williams and Hawkings’ (FWH) analogy is used to compute the far-field noise from the solid surface of the blade. The analogy is computed for the full blade, for its tip region (outer 20% of span) and for lower 80% of span to see the contribution of the latter. The acoustics spectrum below 6 kHz is dominated by the tip part (tip noise), whereas the rest of the blade (trailing-edge noise) contributes more beyond that frequency.

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