Authors: Khaled. M. Faqih

Abstract:

A model of vortex wake is suggested to determine the induced power during animal hovering flight. The wake is modeled by a series of equi-spaced rigid rectangular vortex plates, positioned horizontally and moving vertically downwards with identical speeds; each plate is generated during powering of the functionally wing stroke. The vortex representation of the wake considered in the current theory allows a considerable loss of momentum to occur. The current approach accords well with the nature of the wingbeat since it considers the unsteadiness in the wake as an important fluid dynamical characteristic. Induced power in hovering is calculated as the aerodynamic power required to generate the vortex wake system. Specific mean induced power to mean wing tip velocity ratio is determined by solely the normal spacing parameter (f) for a given wing stroke amplitude. The current theory gives much higher specific induced power estimate than anticipated by classical methods.

Keywords: vortex theory, hovering flight, induced power, Prandlt's tip theory.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1328832

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1684

References:

[1] C. Van Den Berg, and C. P. Ellington, "The vortex wake of a hovering model hawkmoth," Philos. Trans. R. Soc. London B, vol. 352, pp. 317-328, 1997.
[2] M. H Dickinson, F. O. Lehmann, and S. P. SANE, "Wing rotation and the aerodynamic basis of insect flight, " Science, vol. 284, pp. 1954- 1960, 1999.
[3] S. P. Sane and M. H. Dickinson, "The control of flight force by a flapping wing: lift and drag production," J. Exp.Biol., vol. 204, pp. 2607-2626, 2001.
[4] S. P. Sane and M. H. Dickinson, "The aerodynamic effects of wing rotation and a revised quasi-steady model of flapping flight," J. Exp.Biol., vol. 205, pp. 1087-1096, 2002.
[5] G. R. Spedding, M. Rosén, and A. Hedenström, "A family of vortex wakes generated by a thrush nightingale in free flight in a wind tunnel over its entire natural range of flight speeds," J. Exp. Biol., vol. 206, pp. 2313-2344, 2003.
[6] M. F. M. Osborne, "Aerodynamics of flapping flight with application to insects," J. Exp. Biol., vol. 28, pp. 221-245, 1951.
[7] C. J. Pennycuick, "A wind-tunnel study of gliding flight in the pigeon Columba livia," J. Exp. Biol., vol. 49, pp. 509-526, 1968.
[8] C. J. Pennycuick, Mechanics of flight In Avian Biology. Vol. 5 (ed. D. S. Farner and J. R. King), pp. 1-75. New York: Academic Press, 1975.
[9] T. Weis-Fogh, "Energetics of hovering flight in hummingbirds and in Drosophila," J. Exp. Biol., vol. 56, pp. 79-104, 1972.
[10] T. Weis-Fogh, "Quick estimates of flight fitness in hovering animals, including novel mechanisms for lift production," J. Exp. Biol., vol. 59, pp. 169-230, 1973.
[11] C. D. Cone, "The aerodynamics of flapping bird flight," Spec. Sci. Rep. Va Inst. Mar. Sci., vol. 52, 1968.
[12] J. M. V. Rayner, "Vortex theory of animal flight I. vortex wake of a hovering animal," J. Fluid Mech., vol. 91, pp. 697-730, 1979.
[13] C. P. Ellington, "The aerodynamics of hovering insect flight," Philos. Trans. R. Soc. London B, vol. 305, pp. 1-181, 1984.
[14] S. P. Sane, "Induced airflow in flying insects. I. A theoretical model of the induced flow," J. Exp. Biol., vol. 209, pp. 32-42, 2006.
[15] L. M. Milne-Thompson, Theoretical Aerodynamics. Dover, New York, 1958.
[16] C. P. Ellington, "The aerodynamics of normal hovering flight," In Comparative Physiology -Water, Ions and Fluid Mechanics (ed. K. Schmidt-Nielsen, L. Bolis and S. H. P. Maddrell), Cambridge University Press, pp. 327-345, 1978.
[17] M. J. Lighthill, "On the Weis-Fogh mechanism of lift generation," J. Fluid Mech, vol. 60, pp. 1-17, 1973.
[18] T. Weis-Fogh and R. McN. Alexander, "The sustained power output from striated muscle," In Scale Effects in Animal Locomotion (ed. T. J. Pedley), London: Academic Press, pp. 511-525, 1977.
[19] C. J. Pennycuick and M. A. Rezende, "The specific power output of aerobic muscle, related to the power density of mitochondria," J. Exp. Biol., vol. 108, pp. 377-392, 1984.
[20] A. Betz and L. Prandtl, Schraubenpropeller mit geringstem Energieverlust. Nachr. Ges. Wiss. Göttingen, pp. 193-213, 1919.
[21] I. S. Gradshteyn and I. M. Rhyzhik, Tables of Integrals, Series and Products. Academic Press, New York, section 2.58, 1965.
[22] O. Sotavalta, "The essential factor regulating the wing stroke frequency of insects in wing mutilation and loading experiments at subatmospheric," Ann. Zool. Soc., vol. 15 (2), pp. 1-67, 1952.