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Aerodynamic performances of propellers with parametric considerations on the optimal design

Published online by Cambridge University Press:  04 July 2016

S. D’Angelo
Affiliation:
Department of Aeronautical and Space EngineeringPolitecnico di Torino, Turin, Italy
F. Berardi
Affiliation:
Department of Aeronautical and Space EngineeringPolitecnico di Torino, Turin, Italy
E. Minisci
Affiliation:
Department of Aeronautical and Space EngineeringPolitecnico di Torino, Turin, Italy

Abstract

In this paper two numerical procedures are presented: the first algorithm allows for the determination of the geometric characteristics of the maximum efficiency propeller for a given operative condition and profile distribution along the blade; the output of this numerical procedure is the chord distribution and twist angle of the blade, together with its efficiency and its torque and thrust coefficients for the prescribed operative condition. The aerodynamic characteristics of the optimum propeller when operating in a condition different from the design one are obtained by a second algorithm that allows for the evaluation of the efficiency, the thrust and torque coefficients of a propeller of known geometry, when the blade pitch and operative condition are varied.

In the paper the formulation used for deriving the geometry of the optimum propeller and determining its performances when operating off-design is described in detail. The results obtained from the proposed propeller model have been validated by comparison with experimental data.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2002 

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References

1. Pistolesi, E. Aerodinamica, Torino, UTET, 1932.Google Scholar
2. Goldstein, . On the vortex theory of screw propellers, Proc Royal Society, 123, 1929.Google Scholar
3. Prandtl, Betz, et al Schraubenpropeller mit geringstem Energieverlust, Nachrichten d. K. Gesellschaft der Wissenschaften zu Göttingen, 1919.Google Scholar
4. Hilton, W.F. High Speed Aerodynamics, New York, Longmans, Green and Co, 1951.Google Scholar
5. Dommash, D.O., Sherby, S.S. and Connolly, T.F. Airplane Aerodynamics, New York, Pitman Publishing Corporation, 1967.Google Scholar
6. Abbott, I.H. and Von Doenhoff, A.E. Theory of Wing Sections, New York, Dover, 1959.Google Scholar
7. Hoerner, S.F. and Borst, H.V. Fluid-Dynamic Lift, second edition, Brick Town, Hoerner, 1985.Google Scholar
8. Carpenter, P.J. Lift and profile-drag characteristics of an NACA 0012 airfoil section as derived from measured helicopter hovering performance, NACA TN 4357, 1958.Google Scholar
9. Hoerner, S.F. Fluid-Dynamic Drag, Brick Town, Hoerner, 1958.Google Scholar
10. Martinov, A.K. Practical Aerodynamics, Oxford, Pergamon press, 1965.Google Scholar
11. Biermann, D. and Hartman, E. P. The aerodynamic characteristics of six full-scale propellers having different airfoil sections, NACA Report 650, 1939.Google Scholar
12. Loftin, L.K. and Smith, H.A. Aerodynamic characteristics of 15 NACA airfoil sections at seven Reynolds numbers from 0.7 x 106 to 9.0 x 106, NACA TN 1945, 1949.Google Scholar
13. Larrabee, E.E. Practical Design of Minimum Induced Loss Propellers, SAE Preprint 790585, 1979.Google Scholar
14. Eppler, R. and Hepperle, M. A Procedure for Propeller Design by Inverse Methods, published in G.S. Dulikravich, proc Int Confon Inverse Design Concepts in Engineering Sciences (ICIDES), Austin TX, 17-18 October, 1984.Google Scholar
15. Simonetti, F. and Ardito Marretta, R.M. A numerical variational approach for rotor-propeller aerodynamics in axial flight, Computer Modelling in Engineering and Sciences, 1, (3), 2000.Google Scholar