Air traffic volume is expected to triple in the U.S. and Europe by 2025, and as a result, the aerospace industry is facing stricter noise regulations. Apart from the engines, one of the significant contributors of aircraft noise is the deployment of high-lift devices, like leading-edge slats. The unsteady turbulent flow over a leading-edge slat is studied herein. In particular, particle image velocimetry (PIV) measurements were performed on a scale-model wing equipped with a leading-edge slat in the H.J. Irving–J.C.C. Picot Wind Tunnel. Two Reynolds numbers based on wing chord were studied: Re = 6 × 105 and 1.3 × 106. A snapshot proper orthogonal decomposition (POD) analysis indicated that differences in the time-averaged statistics between the two Reynolds numbers were tied to differences in the coherent structures formed in the slat cove shear layer. In particular, the lower Reynolds number flow seemed to be dominated by a large-scale vortex formed in the slat cove that was related to the unsteady flapping and subsequent impingement of the shear layer onto the underside of the slat. A train of smaller, more regular vortices was detected for the larger Reynolds number case, which seemed to cause the shear layer to be less curved and impinge closer to the tail of the slat than for the lower Reynolds number case. The smaller structures are consistent with Rossiter modes being excited within the slat cove. The impingement of the shear layers on and the proximity of the vortices to the slat and the main wing are expected to be strong acoustic dipoles in both cases.
Issue Section:
Flows in Complex Systems
Keywords:
Acoustics,
Fluid instability,
Fluid-structure interaction,
PIV,
Turbulence,
Unsteady flows,
Vortices
References
1.
Crighton
, D.
, and Hubbard
, H. H.
, 1991
, “Aeroacoustics of Flight Vehicles, Theory and Practice–Volume 1: Noise Sources
,” NASA Langley Research Center, Hampton, VA, Technical Report No. NASA-RP-1258-VOL-1
.https://ntrs.nasa.gov/search.jsp?R=199200013802.
Guo
, Y. P.
, and Joshi
, M. C.
, 2003
, “Noise Characteristics of Aircraft High Lift Systems
,” AIAA J.
, 41
(7
), pp. 1247
–1256
.3.
Jenkins
, L. N.
, Khorrami
, M. R.
, and Choudhari
, M. M.
, 2004
, “Characterization of Unsteady Flow Structures Near Leading-Edge Slat—Part I: PIV Measurements
,” AIAA
Paper No. 2004-2801.4.
Henning
, A.
, Kaepernick
, K.
, Ehrenfried
, K.
, Koop
, L.
, and Dillman
, A.
, 2006
, “Investigation of Aeroacoustic Noise Sources by Simultaneous PIV and Microphone Measurement
,” 13th International Symposium on Applications of Laser Techniques to Fluid Mechanics
, Lisbon, Portugal, June 26–29, p. 1185.https://www.researchgate.net/publication/224779404_Investigation_of_Aeroacoustic_Noise_Sources_by_Simultaneous_PIV_and_Microphone_Measurement5.
Moriarty
, P.
, and Heinick
, J.
, 1999
, “PIV Measurements Near a Leading-Edge Slat
,” Third International Workshop on PIV
, Santa Barbara, CA, Sept. 16–18.6.
Richard
, P.
, Wilkins
, S.
, and Hall
, J. W.
, 2014
, “Flow Around a Leading-Edge Slat—Part I: Turbulent Flow Statistics
,” ASME
Paper No. PVP 2014-28316.7.
Wilkins
, S.
, Richard
, P.
, and Hall
, J. W.
, 2014
, “Flow Around a Leading Edge Slat—Part II: Cove Flow Dynamics Via Snapshot Pod
,” ASME
Paper No. PVP2014-28315.8.
Wilkins
, S.
, Richard
, P.
, and Hall
, J. W.
, 2014
, “Velocity Field Estimation Using Unsteady Wall Pressure Measurements in a Leading Edge Slat Flow
,” AIAA
Paper No. 2014-0896.9.
Wilkins
, S.
, Richard
, P.
, and Hall
, J. W.
, 2013
, “An Experimental Investigation of the Shear-Layer and Acoustic Sources Produced by a Leading Edge Slat
,” Bull. Am. Phys. Soc.
, 58
, p. M35.005.http://adsabs.harvard.edu/abs/2013APS..DFDM35005W10.
Choudhari
, M. M.
, Lockhard
, D. P.
, Macaraeg
, M. G.
, Singer
, B. A.
, Streett
, C. L.
, Neubert
, G. R.
, Stoker
, R. W.
, Underbrink
, J. R.
, Berkman
, M. E.
, Khorrami
, M. R.
, and Sadowski
, S. S.
, 2002
, “Aeroacoustic Experiments in the NASA Langley Low-Turbulence Pressure Tunnel
,” NASA Langley Research Center, Hampton, VA, Technical Report No. NASA/TM-2002-211432
.https://ntrs.nasa.gov/search.jsp?R=2002004380111.
Takeda
, K.
, Ashcroft
, G. B.
, Zhang
, X.
, and Nelson
, P. A.
, 2001
, “Unsteady Aerodynamics of Slat Cove Flow in a High-Lift Device Configuration
,” AIAA
Paper No. AIAA-2001-070612.
Makiya
, S.
, Inasawa
, A.
, and Asai
, M.
, 2010
, “Vortex Shedding and Noise Radiation From a Trailing-Edge
,” AIAA J.
, 48
(2
), pp. 502
–509
.13.
Mendoza
, J. M.
, Brooks
, T. F.
, and Humphreys
, W.
, Jr., 2002
, “An Aeroacoustic Study of a Leading Edge Slat Configuration
,” Int. J. Aeroacoustics
, 1
(3
), pp. 241
–274
.14.
Pascioni
, K. A.
, and Cattafesta
, L. N.
, 2016
, “Aeroacoustic Measurements of Leading-Edge Slat Noise
,” AIAA
Paper No. 2016-2960.15.
do Amaral
, F. R.
, do Carmo Pagani Junior
, C.
, Himeno
, F. H. T.
, Serrano
, J. C.
, and de Mederios
, M. A. F.
, 2016
, “Array Shading Applied to Beamforming Technique for Evaluation of Slat Noise From −6 deg to 18 deg Angles of Attack
,” EPTT, Tenth ABCM Spring School on Transition and Turbulence
, São José dos Campos, Brazil, Sept. 19–23.16.
Khorrami
, M. R.
, Choudhari
, M.
, and Jenkins
, L. N.
, 2004
, “Characterization of Unsteady Flow Structures Near Leading Edge Slat—Part II: 2D Computations
,” AIAA
Paper No. 2004-2802.17.
Choudhari
, M. M.
, and Khorrami
, M. R.
, 2007
, “Effect of Three-Dimensional Shear-Layer Structures on Slat Cove Unsteadiness
,” AIAA J.
, 45
(9
), pp. 2174–2186.18.
Lockhard
, D. P.
, and Choudhari
, M. M.
, 2009
, “Noise Radiation From a Leading-Edge Slat
,” AIAA
Paper No. 2009-3101.19.
Choudhari
, M.
, Lockard
, D.
, Khorrami
, M.
, and Mineck
, R.
, 2011
, “Slat Noise Simulations: Status and Challenges
,” Inter-Noise, Osaka, Japan, Sept. 4–7, Paper No. 20110015496
https://ntrs.nasa.gov/search.jsp?R=20110015496.20.
Singer
, B. A.
, Lockhard
, D. P.
, and Brentner
, K. S.
, 2000
, “Computational Aeroacoustic Analysis of Slat Trailing-Edge Flow
,” AIAA J.
, 38
(9
), pp. 1558
–1564
.21.
Khorrami
, M. R.
, Berkman
, M. E.
, and Choudhari
, M. M.
, 2000
, “Unsteady Flow Computations of a Slat With a Blunt Trailing-Edge
,” AIAA J.
, 38
(11
), pp. 2050
–2058
.22.
Khorrami
, M. R.
, Singer
, B. A.
, and Berkman
, M. E.
, 2001
, “Time-Accurate Simulations and Acoustic Analysis of Slat Free-Shear Layer
,” AIAA
Paper No. 2001-2155.https://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/20010057067.pdf23.
Terracol
, M.
, Manoha
, E.
, and Lemoine
, B.
, 2011
, “Investigation of the Unsteady Flow and Noise Sources Generation in a Slat Cove: Hybrid Zonal RANS/LES Simulation and Dedicated Experiment
,” AIAA
Paper No. 2011-3203.24.
Imamura
, T.
, Enomoto
, S.
, Yokokawa
, Y.
, and Yamamoto
, K.
, 2007
, “Simulation of the Broadband Noise From a Slat Using Zonal LES/RANS Hybrid Method
,” AIAA
Paper No. 2007-226.25.
Wang
, X.
, Hu
, Z.
, and Zhang
, X.
, 2013
, “Aeroacoustic Effects of High-Lift Wing Slat Track and Cut-Out System
,” Int. J. Aeroacoustics
, 12
(3
), pp. 283
–307
.26.
Himeno
, F. H.
, do Amaral
, F. R.
, and Medeiros
, M. A.
, 2016
, “Computational Analysis of Aeroacoustic Effect of a Seal on Slat Cove for Different Angles of Attack
,” EPTT, Tenth ABCM Spring School on Transition and Turbulence
, São José dos Campos, Brazil, Sept. 19–23.https://www.researchgate.net/publication/311718864_Computational_Analysis_of_Aeroacoustic_Effect_of_a_Seal_on_Slat_Cove_for_Different_Angles_of_Attack27.
Dobrzynski
, W.
, 2008
, “Almost 40 Years of Airframe Noise Research: What Did We Achieve?
,” 14th Aeroacoustics Conference
, Vancouver, BC, Canada, May 5–7.http://citeseerx.ist.psu.edu/viewdoc/download;jsessionid=7C2F333414C7C46DEF7896A20AD89280?doi=10.1.1.455.1755&rep=rep1&type=pdf28.
Lockard
, D. P.
, Choudhari
, M. M.
, and Buning
, P. G.
, 2014
, “Grid Sensitivity for Slat Noise Simulations
,” AIAA
Paper No. 2014-2627.29.
Deck
, S.
, and Laraufie
, R.
, 2013
, “Numerical Investigation of the Flow Dynamics past a Three-Element Aerofoil
,” J. Fluid Mech.
, 732
(10
), pp. 401
–444
.30.
Rossiter
, J. E.
, 1964
, “Wind Tunnel Experiments on the Flow Over Rectangular Cavities at Subsonic and Transonic Speeds
,” Royal Aircraft Establishment, Farnborough, UK, Technical Report No. 64037
.https://repository.tudelft.nl/view/aereports/uuid:a38f3704-18d9-4ac8-a204-14ae03d84d8c/31.
Delprat
, N.
, 2006
, “Rossiters Formula: A Simple Spectral Model for a Complex Amplitude Modulation Process?
,” Phys. Fluids
, 18
(7
), p. 071703.32.
Richard
, P. R.
, 2015
, “Experimental Investigation of the Unsteady Turbulent Flow Around a Leading-Edge Slat Configuration
,” Master’s thesis, University of New Brunswick, Fredericton, NB, Canada.33.
Everson
, R.
, and Sirovich
, L.
, 1995
, “The Karhunen–Loève Procedure for Gappy Data
,” J. Opt. Soc. Am.
, 12
(8
), pp. 1657
–1664
.34.
Bui-Thanh
, T.
, Damodaran
, M.
, and Willcox
, K.
, 2004
, “Aerodynamic Data Reconstruction and Inverse Design Using Proper Orthogonal Decomposition
,” AIAA J.
, 42
(8
), pp. 1505
–1516
.35.
Murray
, N. E.
, and Ukeiley
, L. S.
, 2007
, “An Application of Gappy Pod for Subsonic Cavity Flow PIV Data
,” Exp. Fluids
, 42
(1
), pp. 79
–91
.http://adsabs.harvard.edu/abs/2007ExFl...42...79M36.
Lumley
, J. L.
, 1967
, “The Structure of Inhomogeneous Turbulent Flow
,” Atmospheric Turbulence and Radio Wave Propagation
, Nauka, Moscow, June 15–22, pp. 166
–178
.37.
Murray
, N. E.
, and Ukeiley
, L. S.
, 2007
, “Modified Quadratic Stochastic Estimation of Resonating Subsonic Cavity Flow
,” J. Turbul.
, 8
, p. N53.38.
Siauw
, W. L.
, Bonnet
, J.
, Tensi
, J.
, and Cattafesta
, L.
, III, 2009
, “Flow Physics of Separated Flow Over a NACA 0015 Airfoil and Detection of Flow Separation
,” AIAA
Paper No. 2009-144.39.
Štefan
, D.
, Rudolf
, P.
, Muntean
, S.
, and Susan-Resiga
, R.
, 2017
, “Proper Orthogonal Decomposition of Self-Induced Instabilities in Decelerated Swirling Flows and Their Mitigation Through Axial Water Injection
,” ASME J. Fluids Eng.
, 139
(8
), p. 081101
.40.
Glauser
, M. N.
, Leib
, S. J.
, and George
, W. K.
, 1987
, “Coherent Structures in the Axisymmetric Turbulent Jet Mixing Layer
,” Turbulent Shear Flows 5, Springer
, Berlin
, pp. 134
–145
.41.
Bonnet
, J.
, Cole
, D.
, Delville
, J.
, Glauser
, M.
, and Ukeiley
, L.
, 1994
, “Stochastic Estimation and Proper Orthogonal Decomposition: Complementary Techniques for Identifying Structure
,” Exp. Fluids
, 17
(5
), pp. 307
–314
.42.
Citrinity
, J. H.
, and George
, W. K.
, 2000
, “Reconstruction of the Global Velocity Field in the Axisymmetric Mixing Layer Utilizing the Proper Orthogonal Decomposition
,” J. Fluid Mech.
, 418
, pp. 137–166.http://www.turbulence-online.com/Publications/Papers/CG00.pdf43.
Hall
, J. W.
, Tinney
, C. E.
, Ausseur
, J. M.
, Pinier
, J. T.
, Hall
, A. M.
, and Glauser
, M. N.
, 2008
, “Low-Dimensional Tools for Closed-Loop Flow-Control in High Reynolds Number Turbulent Flows
,” IUTAM Symposium on Flow Control and MEMS
, Kensington, UK, Sept. 19–22, pp. 293
–310
.44.
Namgyal
, L.
, and Hall
, J. W.
, 2013
, “Coherent Streamwise Vortex Structures in the Near-Field of the Three-Dimensional Wall Jet ASME
,” ASME J. Fluids Eng.
, 135
(6
), p. 061204
.45.
Sirovich
, L.
, 1987
, “Turbulence and the Dynamics of Coherent Structures—Part 1: Coherent Structures
,” Q. Appl. Math.
, 45
(3
), pp. 561
–571
.46.
Meyer
, K. E.
, Pedersen
, J. M.
, and Ozcan
, O.
, 2007
, “A Turbulent Jet in Crossflow Analysed With Proper Orthogonal Decomposition
,” J. Fluid Mech.
, 583
, pp. 199
–227
.47.
Hall
, J. W.
, and Ewing
, D.
, 2007
, “The Asymmetry of the Large-Scale Structures in Turbulent Three-Dimensional Wall Jets Exiting Long Rectangular Channels
,” ASME J. Fluids Eng.
, 129
(7
), pp. 929
–941
.48.
Hall
, J. W.
, and Ewing
, D.
, 2010
, “Spectral Linear Stochastic Estimation of the Turbulent Velocity in a Square Three-Dimensional Wall Jet
,” ASME J. Fluids Eng.
, 132
(5
), p. 051203
.Copyright © 2018 by ASME
You do not currently have access to this content.
