Leading-Edge Vortex Improves Lift in Slow-Flying Bats

Author

F. T. Muijres
L. C. Johansson
R. Barfield
M. Wolf
G. R. Spedding
A. Hedenström

Files

Publication Date

2-29-2008

Publication Title

Science

Volume Number

319

Issue Number

5867

Abstract

Staying aloft when hovering and flying slowly is demanding. According to quasi–steady-state aerodynamic theory, slow-flying vertebrates should not be able to generate enough lift to remain aloft. Therefore, unsteady aerodynamic mechanisms to enhance lift production have been proposed. Using digital particle image velocimetry, we showed that a small nectar-feeding bat is able to increase lift by as much as 40% using attached leading-edge vortices (LEVs) during slow forward flight, resulting in a maximum lift coefficient of 4.8. The airflow passing over the LEV reattaches behind the LEV smoothly to the wing, despite the exceptionally large local angles of attack and wing camber. Our results show that the use of unsteady aerodynamic mechanisms in flapping flight is not limited to insects but is also used by larger and heavier animals.

Document Type

Article

Digital Object Identifier (DOI)

https://doi.org/10.1126/science.1153019

Language

English

Recommended Citation

Muijres, F. T.; Johansson, L. C.; Barfield, R.; Wolf, M.; Spedding, G. R.; and Hedenström, A., "Leading-Edge Vortex Improves Lift in Slow-Flying Bats" (2008). KIP Articles. 8977.
https://digitalcommons.usf.edu/kip_articles/8977