Lift generation by the avian tail

Variation with tail spread of the lift generated by a bird tail was measured on mounted, frozen European starlings (Sturnus vulgaris) in a wind tunnel at a typical air speed and body and tail angle of attack in order to test predictions of existing aerodynamic theories modelling tail lift. Measured...

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Bibliographic Details
Published in:Proceedings of the Royal Society. B, Biological sciences Biological sciences, 2001-07, Vol.268 (1475), p.1443-1448
Main Authors: Maybury, W. J., Rayner, J. M. V., Couldrick, L. B.
Format: Article
Language:English
Subjects:
Aerodynamic coefficients
Aerodynamic lift
Aerodynamics
Animal wings
Animals
Aspect ratio
Biomechanical Phenomena
Bird
Birds
Body Constitution
Body-Tail Interaction
Feathers
Flight
Flight, Animal - physiology
Lift
Modeling
Models, Biological
Planforms
Songbirds - anatomy & histology
Songbirds - physiology
Starlings
Sturnus vulgaris
Tail
Tail - physiology
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Summary:Variation with tail spread of the lift generated by a bird tail was measured on mounted, frozen European starlings (Sturnus vulgaris) in a wind tunnel at a typical air speed and body and tail angle of attack in order to test predictions of existing aerodynamic theories modelling tail lift. Measured lift at all but the lowest tail spread angles was significantly lower than the predictions of slender wing, leading edge vortex and lifting line models of lift production. Instead, the tail lift coefficient based on tail area was independent of tail spread, tail aspect ratio and maximum tail span. Theoretical models do not predict bird tail lift reliably and, when applied to tail morphology, may underestimate the aerodynamic optimum tail feather length. Flow visualization experiments reveal that an isolated tail generates leading edge vortices as expected for a low-aspect ratio delta wing, but that in the intact bird body-tail interactions are critical in determining tail aerodynamics: lifting vortices shed from the body interact with the tail and degrade tail lift compared with that of an isolated tail.
ISSN:0962-8452
1471-2954
DOI:10.1098/rspb.2001.1666