Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-29T08:05:26.100Z Has data issue: false hasContentIssue false
  • English
  • Français

Formation of vortices and spanwise flow on an insect-like flapping wing throughout a flapping half cycle

Published online by Cambridge University Press:  27 January 2016

N. Phillips  and
K. Knowles
N. Phillips*
Affiliation:
Aeromechanical Systems Group, Cranfield University, Defence Academy of the UK, Shrivenham, UK
K. Knowles*
Affiliation:
Aeromechanical Systems Group, Cranfield University, Defence Academy of the UK, Shrivenham, UK
*
[email protected]
[email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

This paper presents an experimental investigation of the evolution of the leading-edge vortex and spanwise flow generated by an insect-like flapping-wing at a Reynolds number relevant to flapping-wing micro air vehicles (FMAVs) (Re = ~15,000). Experiments were accomplished with a first-of-its-kind flapping-wing apparatus. Dense pseudo-volumetric particle image velocimetry (PIV) measurements from 18% – 117% span were taken at 12 azimuthal positions throughout a flapping half cycle. Results revealed the formation of a primary leading-edge vortex (LEV) which saw an increase in size and spanwise flow (towards the tip) through its core as the wing swept from rest to the mid-stroke position where signs of vortex breakdown were observed. Beyond mid-stroke, spanwise flow decreased and the tip vortex grew in size and exhibited a reversal in its axial direction. At the end of the flapping half cycle, the primary LEV was still present over the wing surface, suggesting that the LEV remains attached to the wing throughout the entire flapping half cycle.

Type
Research Article
Information
The Aeronautical Journal , Volume 117 , Issue 1191 , May 2013 , pp. 471 - 490
Copyright
Copyright © Royal Aeronautical Society 2013 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Ansari, S.A. A nonlinear, unsteady, aerodynamic model for insect-like flapping wings in the hover with micro air vehicle applications. PhD thesis, Cranfield University, Shrivenham, UK, 2004.Google Scholar
2. van den Berg, C. and Ellington, C.P. The three-dimensional leading-edge vortex of a hovering model hawkmoth, Philosophical Transactions of the Royal Society of London Series B, 1997, 352, (1351), pp 329340.Google Scholar
3. van den Berg, C. and Ellington, C.P. The vortex wake of a hovering model hawkmoth, Philosophical Transactions of the Royal Society of London Series B, 1997, 352, (1351), pp 317328.Google Scholar
4. Birch, J.M. and Dickinson, M.H. Spanwise flow and the attachment of the leading-edge vortex on insect wings, Nature, 2001, 412, (6848), pp 729733.Google Scholar
5. Bomphrey, R.J. Insects in flight: direct visualization and flow measurements, Bioinspiration & Biomimetics, 2006, 1, (1-9).Google Scholar
6. Bomphrey, R.J., Lawson, N.J., Harding, N.J, Taylor, G.K. and Thomas, A.L.R. The aerodynamics of Manduca sexta: digital particle image velocimetry analysis of the leading-edge vortex, J Experimental Biology, 2005, 208, pp 10791094.Google Scholar
7. Bomphrey, R.J., Lawson, N.J., Harding, N.J., Taylor, G.K. and Thomas, A.L.R. Application of digital particle image velocimetry to insect aerodynamics: measurement of the leading-edge vortex and near wake of a hawkmoth, Experiments in Fluids, 2006, 40, (4), pp 546554.Google Scholar
8. Dickinson, M.H., Lehmann, F.-O. and Sane, S.P. Wing rotation and the aerodynamic basis of insect flight, Science, 1999, 284, (5422), pp 19541960.Google Scholar
9. Ellington, C.P., van den Berg, C., Willmott, A.P. and Thomas, A.L.R. Leading-edge vortices in insect flight, Nature, 1996, 384, pp 626630.Google Scholar
10. Galin’ski, C. and Żbikowski, R. Materials challenges in the design of an insect-like flapping wing mechanism based on a four-bar linkage, Materials & Design, 2007, 28, (3), pp 783796.Google Scholar
11. Hunt, J.C.R., Wray, A.A. and Moin, P. Eddies, stream, and convergence zones in turbulent flows. Technical report, Center for Turbulence Research, 1988. Report CTR-S88.Google Scholar
12. Jones, A. and Babinsky, H. Reynolds number effects on leading edge vortex development on a waving wing, Experiments in Fluids, 2011, 51, (1), pp 197210.Google Scholar
13. Jones, A. and Babinsky, H. Unsteady lift generation on rotating wings at low Reynolds numbers, J Aircr, 2010, 47, (3), pp 10131021.Google Scholar
14. Knowles, R.D., Finnis, M.V., Saddington, A.J. and Knowles, K. Planar visualization of vortical flows. Proceedings of the Institution of Mechanical Engineering, Part G: J Aerospace Engineering, 2006, 220, (6), pp 619627.Google Scholar
15. N.J., Lawson and J., Wu Three-dimensional particle image velocimetry: error analysis of stereoscopic techniques, Measurement Science and Technology, 1997, 8, pp 894900.Google Scholar
16. Leibovich, S. Vortex stability and breakdown: survey and extension, AIAA J, 1984, 22, (9), pp 11921206.Google Scholar
17. Lentink, D. and Dickinson, M.H. Rotational accelerations stabilize leading edge vortices on revolving fly wings, J Experimental Biology, 2009, 212, pp 27052719.Google Scholar
18. Liu, H., Ellington, C.P., Kawachi, K., van den Berg, C. and Wilmott, A.P. A computational fluid dynamic study of hawkmoth hovering, J Experimental Biology, 1998, 201, pp 461477.Google Scholar
19. Lu, Y. and Shen, G.X. Three-dimensional flow structures and evolution of the leading-edge vortices on a flapping wing, J Experimental Biology, 2008, 211, (8), pp 12211230.Google Scholar
20. Lu, Y., Shen, G.X. and Lai, G.J. Dual leading-edge vortices on flapping wings, J Experimental Biology, 2006, 209, pp 50055016.Google Scholar
21. Maxworthy, T. Experiments on the Weis-Fogh mechanism of lift generation by insects in hovering flight. part 1: dynamics of the ‘fing’, J Fluid Mechanics, 1979, 93, pp 4763.Google Scholar
22. Pedersen, C.B. An Indicial-Polhamus Model of Aerodynamics of Insect-Like Flapping Wings in Hover, PhD thesis, Cranfield University, Shrivenham, UK, 2003.Google Scholar
23. Phillips, N. and Knowles, K. Progress in the development of an adjustable, insect-like flapping-wing apparatus utilising a three degree-of-freedom parallel spherical mechanism. International Powered Lift Conference, London, UK, 2008. Royal Aeronautical Society.Google Scholar
24. Phillips, N. Experimental Unsteady Aerodynamics Relevant to Insect-Inspired Flapping-Wing Micro Air Vehicles, PhD thesis, Cranfield University (Shrivenham), 2011. http://hdl.handle.net/1826/5824.Google Scholar
25. Poelma, C. and Dickson, W.B. and Dickinson, M.H. Time-resolved reconstruction of the full velocity field around a dynamically-scaled flapping wing, Experiments in Fluids, 2006, 41, pp 213225.Google Scholar
26. Prasad, A.K. Stereoscopic particle image velocimetry, Experiments in Fluids, 2000, 29, pp 103116.Google Scholar
27. Raffel, M. and Willert, C. and Kompenhans, J. Particle image velocimetry: a practical guide. Springer-Verlag, Berlin, Germany, 1998.Google Scholar
28. Scarano, F., David, L., Bsibsi, M. and Calluaud, D. S-PIV comparative assessment: image dewarping+misalignment correction and pinhole+geometric back projection, Experiments in Fluids, 2005, 39, pp 257266.Google Scholar
29. Srygley, R.B. and Thomas, A.L.R. Unconventional lift-generating mechanisms in free-flying butterflies, Nature, 2002, 420, pp 660664.Google Scholar
30. Tarascio, M.J., Ramasamy, M., Chopra, I. and Leishman, J.G. Flow visualization of micro air vehicle scaled insect-based flapping wings, J Aircr, 2005, 42, (2), pp 385390.Google Scholar
31. Thomas, A.l.R., Taylor, G.K., Srygley, R.B., Nudds, R.L. and Bomphrey, R.J. Dragonfly flight: free-flight and tethered flow visualizations reveal a diverse array of unsteady lift-generating mechanisms, controlled primarily via angle-of-attack, J Experimental Biology, 2004, 207, pp 42994323.Google Scholar
32. Usherwood, J.R. and Ellington, C.P. The aerodynamics of revolving wings I. model hawkmoth wings, J Experimental Biology, 2002, 205, pp 15471564.Google Scholar
33. Westerweel, J. Efficient detection of spurious vectors in particle image velocimetry data, Experiments in Fluids, 1994, 16, pp 236247.Google Scholar
34. Wilkins, P.C. and Knowles, K. The leading-edge vortex and aerodynamics of insect-based flapping-wing micro air vehicles, Aeronaut J, 2009, 113, (1143), pp 253262.Google Scholar
35. Wilkins, P.C. Some unsteady aerodynamics relevant to insect-inspired flapping-wing micro air vehicles. PhD thesis, Cranfield University (Shrivenham), 2008. http://hdl.handle.net/1826/2913.Google Scholar
35. Willert, C.E. Stereoscopic digital particle image velocimetry for application in wind tunnel flows, Measurement Science and Technology, 1997, 8, pp 14651479.Google Scholar
36. Willert, C.E. and Gharib, M. Digital particle image velocimetry, Experiments in Fluids, 1991, 10, pp 181193.Google Scholar
37. Willmott, A.P. and Ellington, C.P. The mechanics of flight in the hawkmoth Manduca sexta: I. kinematics of hovering and forward flight, J Experimental Biology, 1997, 200, pp 27052722.Google Scholar
38. Woods, M.I., Henderson, J.F. and Lock, G.D. Energy requirements for the fight of micro air vehicles, Aeronaut J, 2001, 105, (1043), pp 135149.Google Scholar
39. Żbikowski, R. Flapping wing autonomous micro air vehicles: research programme outline, Fourteenth International Conference on Unmanned Air Vehicle Systems, 1999, pp 38.138.5.Google Scholar