多片后缘小翼对直升机旋翼桨叶动态失速及桨毂振动载荷的控制

doi:10.7527/S1000-6893.2013.0197

Abstract

Abstract:

Delaying dynamic stall and reducing rotor-hub vibration loads are important ways to increase the forward speed and improve the flight performances of a helicopter. This paper investigate effective methods for the simultaneous control of the dynamic stall of retreating blade and rotor-hub vibration loads in the high-speed and high load conditions of a helicopter by using multiple trailing edge flaps. Structural dynamic models of the elastic blade and the rigid trailing edge flap are established. The blade section aerodynamic loads are calculated by using the Leishman-Beddoes two-dimensional unsteady dynamic stall model and the trailing edge flap section aerodynamic loads are calculated by using the Hariharan-Leishman two-dimensional subsonic unsteady aerodynamic model. The aeroelastic responses of the rotor system are solved by combining the Galerkin and numerical integration methods. The effective control strategies and control methods of multiple trailing edge flaps are established. The motion laws of the three trailing edge flaps and their control effects on the retreating blade dynamic stall and rotor hub vibration loads are analyzed. The analytical results show that application of the motion of the multiple trailing edge flaps is an effective way to control the retreating blade dynamic stall and the rotor hub vibration loads.

Key words: helicopter rotors, dynamic stall, hub vibration load, multiple trailing edge flaps, control

CLC Number:

V275⁺.1

WANG Rong, XIA Pinqi. Control of Helicopter Rotor Blade Dynamic Stall and Hub Vibration Loads by Multiple Trailing Edge Flaps[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2013, 34(5): 1083-1091.

References

[1] Chopra I. Review of state-of-art of smart structures and integrated systems. AIAA Journal, 2002, 40(11): 2145-2187.
[2] Shen J W, Chopra I. A parametric design study for a swashplateless helicopter rotor with trailing-edge flaps. Proceedings of American Helicopter Society 58th Annual Forum. Montreal: American Helicopter Society, 2002, 2: 2134-2148.
[3] Lim I G, Lee I. Aeroelastic analysis of rotor systems using trailing edge flaps. Journal of Sound and Vibration, 2009, 321(3-5): 525-536.
[4] Kim J S, Smith E C, Wang K W. Helicopter blade loads control via multiple trailing-edge flaps. Proceedings of the American Helicopter Society 62nd Annual Forum, Phoenix: American Helicopter Society, 2006.
[5] Carr L W, Mcalister K W. The effect of a leading-edge slat on the dynamic stall of an oscillating airfoil. Proceedings American Institute of Aeronautics and Astronautics, Aircraft Design, Systems and Technology Meeting, Fort Worth: American Institute of Aeronautics and Astronautics, 1983.
[6] Geissler W, Dietz G, Mai H, et al. Dynamic stall control investigations on a full size chord blade section. Proceedings of European Rotorcraft Forum, 2004: 14-16.
[7] Post M L, Corke T C. Separation control using plasma actuators: dynamic stall vortex control on oscillating airfoil. AIAA Journal, 2006, 44(12): 3125-3135.
[8] Singh C, Peake D J, Kokkalis A, et al. Parametric study of an air-jet vortex generator configuration to control rotorcraft retreating blade stall. Proceedings of 43rd AIAA Aerospace Sciences Meeting and Exhibit, Reno: American Institute of Aeronautics and Astronautics, 2005.
[9] Chandrasekhara M S. A review of compressible dynamic stall control principles and methods. Proceedings of the Tenth Asian Congress of Fluid Mechanics, 2004:1-6.
[10] Gerontakos P, Lee T. Dynamic stall flow control via a trailing-edge flap. AIAA Journal, 2006, 44(3): 469-480.
[11] Wang R, Xia P Q. Optimal control of rotor hub vibration loads by using motion of trailing edge flap. Journal of Vibration Engineering (in press).(in Chinese) 王荣, 夏品奇. 利用桨叶后缘小翼运动的旋翼桨毂振动载荷优化控制. 振动工程学报(待发表).
[12] Wang R, Xia P Q. Control of dynamic stall of helicopter rotor blades. Science China Technical Series, 2013, 56:171-180.
[13] Leishman J G. Principles of helicopter aerodynamics. 2nd ed. New York: Cambrige University Press, 2006: 607-614.
[14] Johnson W. The response and airloading of helicopter rotor blades due to dynamic stall. Massachusetts: Massachusetts Institute of Technology Aeroelastic and Structures Research Lab, 1970.
[15] Leishmann J G, Beddoes T S. A semi-empirical model for dynamic stall. Proceedings of 42nd Annual Forum of the American Helicopter Society, Washington: American Helicopter Society,1986: 3-17.
[16] Truong V K. A 2-D dynamic stall model based on a Hopf bifurcation. ONERA-TAP-93-156, France: Office National D'etudes et de Recherches Aerospatiales, 1993.
[17] Carr L W, Mccroskey W J, Mcalister K W, et al. An experimental study of dynamic stall on advanced airfoil sections. NASA-TM-84245, 1982.
[18] Hariharan N, Leishman J G. Unsteady aerodynamics of a flapped airfoil in subsonic flow by indicial concepts. Proceedings of the 36th AIAA/SME/AHS/A Structrues, Structural Dynamics, and Materials Conference, New Orleans: American Institute of Aeronautics and Astronautics, 1995:613-634.
[19] Theodorson T. General theory of aerodynamic instability and the mechanism of flutter. NACA-TR-496, 1949.
[20] Bousman W G. A qualitative examination of dynamic stall from flight test data. Journal of the American Helicopter Society, 1998, 43(4): 279-295.
[21] Zhang J H. Active-passive hybrid optimization of rotor blades with trailing edge flaps. Pennsylvania: College of Engineering, Pennsylvania State University, 2001.

Control of Helicopter Rotor Blade Dynamic Stall and Hub Vibration Loads by Multiple Trailing Edge Flaps

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