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Experiments in Fluids

Erschienen in:

01.07.2021 | Research Article

Rotating three-dimensional velocimetry

verfasst von: Abbishek Gururaj, Mahyar Moaven, Zu Puayen Tan, Brian Thurow, Vrishank Raghav

Erschienen in: Experiments in Fluids | Ausgabe 7/2021

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Abstract

Flow evolution over helicopter rotors, wind turbine blades, and insect wings are unsteady, three-dimensional (3D), and influenced by phenomena unique to the rotating frame of reference (FoR), e.g., Coriolis and centrifugal forces. Conventional 3D-PIV techniques are unable to fully characterize these rotating FoR physics, since the measurements are limited to a fixed FoR of a relatively small volume through which the rotor blade or wing traverses intermittently. In this paper, a new “Rotating Three-Dimensional Velocimetry (R3DV)” technique is proposed to address these gaps. R3DV consists of 3D measurements made with a single stationary plenoptic camera in combination with a hub-mounted mirror that aligns the camera’s field of view with a rotating wing. In post-processing R3DV data, a rotational volumetric calibration method is developed to account for image acquisition through a rotating mirror. Rotating FoR volumes are then reconstructed using the Multiplicative Algebraic Reconstruction Technique (MART) algorithm with the adapted calibration scheme and subsequently cross-correlated to derive a 3D velocity field. R3DV was experimentally demonstrated in a study of 3D unsteady flow over an impulsively rotated flat-plate wing. Prominent flow features like the formation and shedding of the primary and secondary leading-edge vortices (LEVs) were observed, which corroborate well with the existing literature on rotating wings. The time-resolved variation of LEV velocity profiles and circulation with azimuthal angle exhibited expected trends. The ability to quantify 3D and time-resolved velocity fields in the rotating FoR demonstrates the feasibility of adopting R3DV as a technique to investigate rotating flows.

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Vorheriger Artikel Review of recent progress in the supersonic cold-spraying technique with solid particles and liquid suspensions

Nächster Artikel On the determination of the dissipation rate of turbulence kinetic energy

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Bhat SS, Zhao J, Sheridan J, Hourigan K, Thompson MC (2019) Uncoupling the effects of aspect ratio, Reynolds number and Rossby number on a rotating insect-wing planform. J Fluid Mech 859:921–948MathSciNetCrossRef

Birch JM, Dickinson MH (2001) Spanwise flow and the attachment of the leading-edge vortex on insect wings. Nature 412(6848):729–733CrossRef

Birch JM, Dickson WB, Dickinson MH (2004) Force production and flow structure of the leading edge vortex on flapping wings at high and low Reynolds numbers. J Exp Biol 207(7):1063–1072CrossRef

Butterfield CP (1988) Aerodynamic pressure and flow-visualization measurement from a rotating wind turbine blade. Tech. rep., Solar Energy Research Inst., Golden, CO (USA)

Butterfield CP (1989) Three-dimensional airfoil performance measurements on a rotating wing. Tech. rep., Solar Energy Research Inst., Golden, CO (USA)

Carr LW, Chandrasekhara M (1996) Compressibility effects on dynamic stall. Prog Aerosp Sci 32(6):523–573CrossRef

Carr Z, Chen C, Ringuette M (2012) The effect of aspect ratio on the three-dimensional vortex formation of rotating flat-plate wings. In: 50th AIAA aerospace sciences meeting including the new horizons forum and aerospace exposition, p 912

Carr Z, Chen C, Ringuette M (2013) Finite-span rotating wings: three-dimensional vortex formation and variations with aspect ratio. Exp Fluids 54(2):1–26CrossRef

Chen L, Wu J, Cheng B (2019) Volumetric measurement and vorticity dynamics of leading-edge vortex formation on a revolving wing. Exp Fluids 60(1):1–15CrossRef

Cheng B, Sane SP, Barbera G, Troolin DR, Strand T, Deng X (2013) Three-dimensional flow visualization and vorticity dynamics in revolving wings. Exp Fluids 54(1):1423CrossRef

DiOttavio J, Watson K, Cormey J, Kondor S, Komerath N (2008) Discrete structures in the radial flow over a rotor blade in dynamic stall. In: 26th AIAA applied aerodynamics conference, p 7344

Ellington CP, Van Den Berg C, Willmott AP, Thomas AL (1996) Leading-edge vortices in insect flight. Nature 384(6610):626–630CrossRef

Fahringer TW, Lynch KP, Thurow BS (2015) Volumetric particle image velocimetry with a single plenoptic camera. Meas Sci Technol 26(11):115201CrossRef

Fahringer TW, Thurow BS, Humphreys WM, Bartram S (2017) Comparison of stereo-PIV and plenoptic-PIV measurements on the wake of a cylinder in NASA ground test facilities. In: 55th AIAA aerospace sciences meeting, p 0023

Gallant T (2017) Quantitative measurement techniques for wind turbine blade aerodynamic performance. Master’s thesis, University of Waterloo

Garmann D, Visbal M (2014) Dynamics of revolving wings for various aspect ratios. J Fluid Mech 748:932–956CrossRef

Garmann DJ, Visbal MR, Orkwis PD (2013) Three-dimensional flow structure and aerodynamic loading on a revolving wing. Phys Fluids 25(3):034101CrossRef

Graftieaux L, Michard M, Grosjean N (2001) Combining PIV, pod and vortex identification algorithms for the study of unsteady turbulent swirling flows. Meas Sci Technol 12(9):1422CrossRef

Hall EM, Fahringer TW, Guildenbecher DR, Thurow BS (2018) Volumetric calibration of a plenoptic camera. Appl Opt 57(4):914–923CrossRef

Jardin T (2017) Coriolis effect and the attachment of the leading edge vortex. J Fluid Mech 820:312–340MathSciNetCrossRef

Jardin T, David L (2015) Coriolis effects enhance lift on revolving wings. Physical Review E 91(3):031001

JCR H, Wray A, Moin P (1988) Eddies, stream, and convergence zones in turbulent flows. Center for turbulence research report CTR-S88 pp 193–208

Jones A, Babinsky H (2010) Unsteady lift generation on rotating wings at low Reynolds numbers. J Aircraft 47(3):1013–1021CrossRef

Juliano TJ, Disotell KJ, Gregory JW, Crafton J, Fonov S (2012) Motion-deblurred, fast-response pressure-sensitive paint on a rotor in forward flight. Meas Sci Technol 23(4):045303CrossRef

Kim D, Gharib M (2010) Experimental study of three-dimensional vortex structures in translating and rotating plates. Exp Fluids 49(1):329–339CrossRef

Lang W, Gardner AD, Mariappan S, Klein C, Raffel M (2015) Boundary-layer transition on a rotor blade measured by temperature-sensitive paint, thermal imaging and image derotation. Exp Fluids 56(6):1–14CrossRef

Lentink D, Dickinson MH (2009) Rotational accelerations stabilize leading edge vortices on revolving fly wings. J Exp Biol 212(16):2705–2719CrossRef

Liu T, Torgerson S, Sullivan J, Johnston R, Fleeter S, Liu T, Torgerson S, Sullivan J, Johnston R, Fleeter S (1997) Rotor blade pressure measurement in a high speed axial compressor using pressure and temperature sensitive paints. In: 35th aerospace sciences meeting and exhibit, p 162

Manar F, Medina A (2014) Tip vortex structure and aerodynamic loading on rotating wings in confined spaces. Exp Fluids 55(9):1–8CrossRef

Mayo D, Jones A (2013) Evolution and breakdown of a leading edge vortex on a rotating wing. In: 51st AIAA aerospace sciences meeting including the new horizons forum and aerospace exposition, p 843

McCroskey WJ (1971) Measurements of boundary layer transition, separation and streamline direction on rotating blades, vol 6321. National Aeronautics and Space Administration, Washington, D.C.

Medina A, Jones AR (2016) Leading-edge vortex burst on a low-aspect-ratio rotating flat plate. Phys Rev Fluids 1(4):044501CrossRef

Mulleners K, Kindler K, Raffel M (2012) Dynamic stall on a fully equipped helicopter model. Aerosp Sci Technol 19(1):72–76CrossRef

Nguyen K, Johnson W (1998) Evaluation of dynamic stall models with uh-60a airloads flight test data. In: Annual forum proceedings-American helicopter society, American Helicopter Society, vol 54, pp 576–588

Ozen CA, Rockwell D (2012) Three-dimensional vortex structure on a rotating wing. J Fluid Mech 707:541–550CrossRef

Percin M, Van Oudheusden B (2015) Three-dimensional flow structures and unsteady forces on pitching and surging revolving flat plates. Exp Fluids 56(2):47CrossRef

Raghav V, Komerath N (2013) An exploration of radial flow on a rotating blade in retreating blade stall. J Am Helicop Soc 58(2):1–10CrossRef

Raghav V, Komerath N (2014) Velocity measurements on a retreating blade in dynamic stall. Exp Fluids 55(2):1669CrossRef

Raghav V, Komerath N (2015) Dynamic stall life cycle on a rotating blade in steady forward flight. J Am Helicop Soc 60(3):1–12CrossRef

Rice BE, McKenzie JA, Peltier SJ, Combs CS, Thurow BS, Clifford CJ, Johnson K (2018) Comparison of 4-camera tomographic PIV and single-camera plenoptic PIV. In: 2018 AIAA aerospace sciences meeting, p 2036

Tan ZP, Thurow BS (2020) Depth-of-field reduction due to blurring in a relayed plenoptic camera and mitigation via deconvolution. Meas Sci Technol 31(5):055403CrossRef

Tan ZP, Johnson K, Clifford C, Thurow BS et al (2019) Development of a modular, high-speed plenoptic-camera for 3d flow-measurement. Opt Express 27(9):13400–13415CrossRef

Tan ZP, Alarcon R, Allen J, Thurow BS, Moss A (2020) Development of a high-speed plenoptic imaging system and its application to marine biology PIV. Meas Sci Technol 31(5):054005CrossRef

Tanner W, Yaggy P (1966) Experimental boundary layer study on hovering rotors. J Am Helicop Soc 11(3):22–37CrossRef

Vey S, Marten D, Pechlivanoglou G, Nayeri C, Paschereit CO (2015) Experimental and numerical investigations of a small research wind turbine. In: 33rd AIAA applied aerodynamics conference, p 3392

Wabick KJ, Buchholz J, Johnson K, Thurow BS (2018) Characterization of vorticity transport in the leading-edge vortex of a rolling wing using plenoptic PIV. In: 2018 AIAA aerospace sciences meeting, p 1292

Watkins AN, Leighty BD, Lipford WE, Goodman KZ, Crafton J, Gregory JW (2016) Measuring surface pressures on rotor blades using pressure-sensitive paint. AIAA J 54(1):206–215CrossRef

Wojcik CJ, Buchholz JH (2014) Vorticity transport in the leading-edge vortex on a rotating blade. J Fluid Mech 743:249–261CrossRef

Wolfinger M, Rockwell D (2014) Flow structure on a rotating wing: effect of radius of gyration. J Fluid Mech 755:83–110CrossRef

Titel: Rotating three-dimensional velocimetry
verfasst von: Abbishek Gururaj
Mahyar Moaven
Zu Puayen Tan
Brian Thurow
Vrishank Raghav
Publikationsdatum: 01.07.2021
Verlag: Springer Berlin Heidelberg
Erschienen in: Experiments in Fluids / Ausgabe 7/2021
Print ISSN: 0723-4864
Elektronische ISSN: 1432-1114
DOI: https://doi.org/10.1007/s00348-021-03241-4

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Abstract

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