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The generation of tonal noise from sawtooth trailing-edge serrations at low Reynolds numbers

Published online by Cambridge University Press:  10 May 2016

D. J. Moreau*
Affiliation:
School of Mechanical and Manufacturing Engineering, University of New South Wales, SydneyAustralia
C. J. Doolan
Affiliation:
School of Mechanical and Manufacturing Engineering, University of New South Wales, SydneyAustralia

Abstract

The flow and noise created by sawtooth trailing-edge serrations has been studied experimentally at a low Reynolds number. Experiments have been performed on a flat-plate model with an elliptical leading edge and an asymmetrically bevelled trailing edge at Reynolds numbers of Rec = 1 × 105–1.3 × 105, based on chord. Wide serrations with a wavelength (λs) to amplitude (2h) ratio of λs/h = 0.6 were found to reduce the overall sound pressure level by up to 11dB. In contrast, narrower serrations with λs/h = 0.2 produce tonal noise and increase the overall noise level by up to 4dB. Intense vortices across the span of the trailing edge with narrow serrations are shown to be the source of tonal noise. Wide serrations reduce turbulent velocity fluctuations at low frequencies which explains the lower radiated noise. The narrow serrations that produce low Reynolds number tonal noise were shown previously to be effective at higher Reynolds numbers (Rec > 2 × 105), demonstrating that care is needed to fully understand the flow field over serrations for all intended operating conditions.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2016 

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References

REFERENCES

1.Blake, W.Mechanics of flow induced sound and vibration, Vol. II: Complex Flow-Structure Interactions, 1986, Academic Press, New York, US.Google Scholar
2.Blake, W. and Gershfeld, J.Frontiers in Experimental Fluid Mechanics: The Aeroacoustics of Trailing Edges, 1989, Springer-Verlag, Berlin.Google Scholar
3.Herr, M. and Dobrzynski, W.Experimental investigations in low-noise trailing-edge design, AIAA J, 2005, 43, (6), pp 11671175.Google Scholar
4.Geyer, T., Sarradj, E. and Fritzsche, C.Measurement of the noise generation at the trailing edge of porous airfoils, Experiments in Fluids, 2010, 48, pp 291308.Google Scholar
5.Herr, M.On the design of silent trailing-edges, New Results in Numerical and Experimental Fluid Mechanics VI, 2008, 96, pp 430437.CrossRefGoogle Scholar
6.Finez, A., Jondeau, E., Roger, M. and Jacob, M.C. Broadband noise reduction with trailing edge brushes, 16th AIAA Aeroacoustics Conference, 2010, AIAA Paper 2010-3980.Google Scholar
7.Howe, M.S.Aerodynamic noise of a serrated trailing edge, J Fluids and Structures, 1991, 5, (1), pp 3345.Google Scholar
8.Howe, M.S.Noise produced by a sawtooth trailing edge, J the Acoustical Society of America, 1991, 90, (1), pp 482487.Google Scholar
9.Sandberg, R.D. and Jones, L.E.Direct numerical simulations of low Reynolds number flow over airfoils with trailing-edge serrations, J Sound and Vibration, 2011, 330, (16), pp 38183831.Google Scholar
10.Braun, K., Van der Borg, N., Dassen, A., Doorenspleet, F., Gordner, A., Ocker, J. and Parchen, R. Serrated trailing edge noise (STENO), European Wind Energy Conference, 1999, pp 180-183.Google Scholar
11.Parchen, R., Hoffmans, W., Gordner, Q., Braun, K., Van der Borg, N. and Dassen, A. Reduction of airfoil self-noise at low Mach number with a serrated trailing edge, 6th International Congress on Sound and Vibration, 1999, pp 3433-3440.Google Scholar
12.Oerlemans, S., Fisher, M., Maeder, T. and Kogler, K.Reduction of wind turbine noise using optimized airfoils and trailing-edge serrations, AIAA J, 2009, 47, (6), pp 14701481.Google Scholar
13.Gruber, M., Joseph, P.F. and Chong, T.P. On the mechanisms of serrated airfoil trailing edge noise reduction, 17th AIAA/CEAS Aeroacoustics Conference, 2011, AIAA Paper 2011-2781.Google Scholar
14.Chong, T.P., Joseph, P.F. and Gruber, M.Airfoil self noise reduction by non-flat plate type trailing edge serrations, Applied Acoustics, 2013, 74, (4), pp 607613.Google Scholar
15.Chong, T.P., Vathylakis, A., Joseph, P.F. and Gruber, M.Self-noise produced by an airfoil with nonflat plate trailing edge serrations, AIAA J, 2013, 51, (10), pp 26652677.CrossRefGoogle Scholar
16.Fischer, A., Bertagnolio, F., Shen, W.Z., Madsen, J., Madsen, H.A., Bak, C., Devenport, W. and Intaratep, N. Wind tunnel test of trailing edge serrations for reduction of wind turbine noise, Inter–noise 2014, 2014, Paper 693.Google Scholar
17.Moreau, D.J. and Doolan, C.J.Noise-reduction mechanism of a flat-plate serrated trailing edge, AIAA J, 2013, 51, (10), pp 25132522.Google Scholar
18.Chong, T.P., Joseph, P.F. and Gruber, M. An experimental study of airfoil instability noise with trailing edge serrations, 16th AIAA/CEAS Aeroacoustics Conference, 2010, AIAA Paper 2010-3723.Google Scholar
19.Chong, T.P., Vathylakis, A., Joseph, P.F. and Gruber, M. On the noise and wake flow of an airfoil with broken and serrated trailing edges, 17th AIAA/CEAS Aeroacoustics Conference, 2011, AIAA Paper 2011-2860.Google Scholar
20.Moreau, D.J., Doolan, C.J., Tetlow, M., Roberts, M. and Brooks, L.A. The flow and noise generated by a sharp trailing edge, The 17th Australasian Fluid Mechanics Conference, 2010, Paper 169.Google Scholar
21.Leclercq, D., Doolan, C. and Reichl, J. Development and validation of a small-scale anechoic wind tunnel, 14th International Congress on Sound and Vibration, 2007, Paper 105.Google Scholar
22.Moreau, D.J., Brooks, L.A. and Doolan, C.J.Broadband trailing edge noise from a sharp-edged strut, J the Acoustical Society of America, 2011, 129, (5), pp 28202829.Google Scholar
23.Bendat, J. and Piersol, A.Random Data: Analysis and Measurement Procedures, 2010, Wiley, New York, US.Google Scholar
24.Cebeci, T. and Bradshaw, P.Momentum Transfer in Boundary Layers, 1977, Hemisphere Publishing Corporation, Washington, New York, US.Google Scholar
25.Moreau, D.J., Brooks, L.A. and Doolan, C.J.The effect of boundary layer type on trailing edge noise from sharp-edged flat plates at low-to-moderate Reynolds number, J Sound and Vibration, 2012, 331, pp 39763988.Google Scholar
26.Arbey, H. and Bataille, J.Noise generated by airfoil profiles placed in a uniform laminar flow, JFluid Mechanics, 1983, 134, pp 3347.CrossRefGoogle Scholar
27.Kingan, M.J. and Pearse, J.R., Laminar boundary layer instability noise produced by an aerofoil, J Sound and Vibration, 2009, 322, pp 808828.Google Scholar
28.Chong, T.P. and Joseph, P.F.Ladder structure in tonal noise generated by laminar flow around an airfoil, J Acoustical Society of America, 2012, 131, pp 461467.Google Scholar