Aerodynamic prediction of helicopter rotor in forward flight using blade element theory

Authors

  • M.F. Yaakub Department of Aeronautical Engineering, Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400 Batu Pahat, Johor, Malaysia.
  • A.A. Wahab Department of Aeronautical Engineering, Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400 Batu Pahat, Johor, Malaysia.
  • A. Abdullah Department of Aeronautical Engineering, Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400 Batu Pahat, Johor, Malaysia.
  • N.A.R. Nik Mohd Department of Aeronautics, Automotive and Ocean Engineering, Faculty of Mechanical Engineering, Universiti Teknologi Malaysia, 81310, Skudai, Malaysia.
  • S.S. Shamsuddin Department of Aeronautical Engineering, Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400 Batu Pahat, Johor, Malaysia.

DOI:

https://doi.org/10.15282/jmes.11.2.2017.12.0246%20

Keywords:

Aerodynamics, blade element theory, rotor, forward flight

Abstract

In this study, the helicopter blade in forward-flight condition was investigated. The blade element theory (BET) was used throughout this analysis to investigate the angle of attack variations at the blade cross sections, lift distribution along the blade and effects of increasing helicopter speed. Prouty’s helicopter data was used to validate the analysis results. In this analysis, the helicopter blade was divided into 50 equally spaced elements and the azimuth ψ was set at 7.2° for each movement of the blade. The helicopter speed of 80 m/s was considered. The analysis revealed that the computation results were in good agreement with Prouty’s diagram. Furthermore, it was also evident that in the case of a helicopter in forward-flight condition, the blade at retreating side was generally at low angle of attack and experienced low lift, in contrast to the blade at advancing side. The increment of the helicopter speed affected the lift distribution along the blade. The reverse flow area was widened two times from that given by the original Prouty’s diagram. In addition, it was proven that each helicopter has its own speed limit called velocity never exceed (VNE). It was also shown that BET is important in conducting the analysis to modify the helicopter blade design for the aerodynamic characteristics’ improvement as well as stability and general performance enhancement for the helicopter.

References

Leishman GJ. Principle of Helicopter Aerodynamic: Cambridge University Press; 2006.

Gessow A MG. Aerodynamic of Helicopter. New York: Frederick Ungar Publishing Co; 1999.

W. J. Helicopter Theory: Dover Publications, Inc; 1994.

RW. P. Helicopter Performance of Stability and Control. PWS Engineering Boston; 2005.

McCormick D, Anderson T, Wake B, Mac Martin D. Rotorcraft Retreating Blade Stall Control. AIAA; 2000.

Raghav V, Komerath N. An exploration of radial flow on a rotating blade in retreating blade stall. Journal of the American Helicopter Society. 2013;58:1-10.

Hooper W. Technology for advanced helicopter. SAE Paper No872370. 1987.

Gustafson F, Gessow A. Effect of Blade Stalling on the Efficiency of a Helicopter Rotor as Measured in Flight. NACA Technical Note 1250. 1947.

NAR NM, Wahab A. Feasibility Study on Improving of Helicopter Forward Flight Speed via Modification of the Blade Dimension and Engine Performance. Proceeding of RIVET06. Kuala Lumpur; 2006.

McVeigh MA, McHugh FJ. Influence of tip shape, chord, blade number, and airfoil on advanced rotor performance. Journal of the American Helicopter Society. 1982;29:55-62.

Vu NA, Lee JW, Shu JI. Aerodynamic design optimization of helicopter rotor blades including airfoil shape for hover performance. Chinese Journal of Aeronautics. 2013;26:1-8.

Harrison R, Stacey S, Hansford B. BERP IV: The design development and testing of an advanced rotor blade. 64th Annual Forum of the American Helicopter Society' 2008.

Brocklehurst A, Beedy J, Barakos G, Badcock K, Richards B. Experimental and CFD investigation of helicopter BERP tip aerodynamics. Integrating CFD and Experiments in Aerodynamics International Symposium. Glasgow; 2007.

Perry FJ. Aerodynamics of the World Speed Record. 3rd Annual National Forum of the American Helicopter Society. 1987.

Kostas J, Foucaut J, Stanislas M. The flow produced by pulsed-jet vortex generators in a turbulent boundary layer in an adverse pressure gradient. Flow, Turbulence and Combustion. 2007;78:331-63.

Godard G, Stanislas M. Control of a decelerating boundary layer. Part 3: Optimization of round jets vortex generators. Aerospace Science Technology. 2006;10:455-64.

Tilmann CP, Langan KJ, Betterton JG, Wilson MJ. Characterization of pulsed vortex generator jets for active flow control. Land vehicle and sea vehicle (RTO/AVT) symposium. Germany; 2003. p. 51-512.

McCormick DC, Lozyniak SA, MacMartin DG, Lorber PF. Compact, high-power boundary layer separation control actuation development. Proceeding of ASME Paper No. 18279. 2001.

Amitay M, Smith DR, Kibens V, Parekh DE, Glezer A. Aerodynamic flow control over an unconventional airfoil using synthetic jet actuators. AIAA Journal. 2001;39:361-70.

Tejero E, Doerffer P, Szulc O. Application of Passive Control Device on Helicopter Rotor Blades. Journal of the American Helicopter Society. 2016;61:1-13.

De Gregorio F, Fraioli G. Flow control on a high thickness airfoil by a trapped vortex cavity. 14th Int Sym On Application of Laser Techniques to Fluid Mechanics. Lisbon, Portugal; 2008. p. 143-9.

Bouferrouk A, Chernyshenko S. Stabilisation of a trapped vortex for enhancing aerodynamic flows. In: 15th Australian Fluid Mechanics Conferences. University of Sydney; 2004.

Donelli RS IP, Iuliano E, Rosa DD. Optimization on thick airfoil to trap vortices. Report of VortexCell2050. 2008.

Kerho M. Adaptive airfoil dynamic stall control. Journal of Aircraft. 2007;44:1350-60.

Kumar D, Cesnik CE. Performance Enhancement in Dynamic Stall Condition Using Active Camber Deformation. Journal of the American Helicopter Society. 2015;60:1-12.

Chandrasekhara M, Martin PB, Tung C. Compressible Dynamic Stall Control Using a Variable Droop Leading Edge Airfoil. Journal of Aircraft. 2004;41:862-9.

Qureshi H, Hamdani HR, Parvez K. Effects on dynamic stall on cambered airfoil with drooping leading edge control. 44th AIAA Aerospace Science Meeting and Exhibition; 2006.

Geissler W, Trenker M. Numerical investigation of dynamic stall control by a nose-drooping device. American Helicopter Society Aerodynamics, Acoustics Test and Evaluation Technical Specialist Meeting; 2002.

Liu T, Montefort J, Liou W, Pantula S, Shams QA. Lift enhancement by static extended trailing edge. Journal of Aircraft. 2007;44:1939-47.

Maughmer M, Lesieutre G, Kinzel M. Miniature Trailing‐Edge Effectors for Rotorcraft Performance Enhancement. American Helicopter Society 61st Annual Forum. 2007;52:146-58.

Bae ES, Gandhi F, Maughmer M. Optimally scheduled deployment of gurney flap for rotorcraft power reduction. American Helicopter Society 65th Annual Forum. 2009.

Gibertini G, Zanotti A, Droandi G, Auteri F, Crosta G. Experimental investigation of a helicopter rotor with Gurney flaps. The Aeronautical Journal. 2017;121:191-212.

Paul J.C. "Lift and Profile-Drag Characteristic of an Airfoil Section as derived from Measured Helicopter Rotor Hovering Performance". NASA Technical Note 4357. 1958.

Downloads

Published

2017-06-30

How to Cite

[1]
M.F. Yaakub, A.A. Wahab, A. Abdullah, N.A.R. Nik Mohd, and S.S. Shamsuddin, “Aerodynamic prediction of helicopter rotor in forward flight using blade element theory”, J. Mech. Eng. Sci., vol. 11, no. 2, pp. 2711–2722, Jun. 2017.

Issue

Section

Article

Similar Articles

<< < 2 3 4 5 6 7 8 9 10 11 > >> 

You may also start an advanced similarity search for this article.