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Abstract

This paper provides a detailed study of a non-linear aeroelastic phenomenon first addressed by Safi et al., i.e. coupling a model for wear in mechanical linkages to the aeroelastic response of a non-linear wing—aileron or stabilizer—elevator system. The aeroelastic behaviour of these systems with free-play structural non-linearity in the control surface restoring moment is examined. The underlying dynamics and deterioration of the system due to ageing are investigated. Extensive numerical simulations are performed using Wagner' function to evaluate the aerodynamic forces. The resulting equations are integrated numerically to give time histories of the airfoil—aileron motion. Regions of limit cycle oscillations (LCOs) and chaotic vibration are identified well below the linear flutter speed. Finally qualitative and quantitative wear analyses are presented to provide relationships to predict the depth of wear in the mechanical connections experiencing LCOs. The problem is shown to be coupled with an accelerating wear rate as the free play develops.

Keywords

non-linear aeroelasticity control surface free play

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References

Woolston

D. S.

Runyan

H. L.

Andrews

R. E.

An investigation of effects of certain types of structural nonlinearities on wing and control surface flutter. J. Aeronaut. Sci., 1957, 24 (1), 57–63.

Yang

Z. C.

Zhao

L. C.

Analysis of limit cycle flutter of an airfoil in incompressible flow. J. Sound Vibr., 1988, 123 (1), 1–13.

Zhao

L. C.

Yang

Z. C.

Chaotic motions of an airfoil with nonlinear stiffness in incompressible flow. J. Sound Vibr., 1990, 138 (2), 245–254.

Tang

D. M.

Dowell

E. H.

Flutter and stall response of a helicopter blade with structural nonlinearity. J. Aircr., 1992, 29 (5), 953–960.

Price

S. J.

Alighanbari

Lee

B. H. K.

The aeroelastic response of a two-dimensional airfoil with bilinear and cubic structural nonlinearities. In Proceedings of the AIAA 35th Structures, Structural Dynamics, and Materials Conference, 1994, pp. 1771–1780 (American Institute of Aeronautics and Astronautics, Washington, DC).

Price

S. J.

Alighanbari

Lee

B. H. K.

The aeroelastic response of a two-dimensional airfoil with bilinear and cubic structural nonlinearities. J. Fluids Structs, 1995, 9 (2), 175–193.

Kim

S. H.

Lee

Aeroelastic analysis of a flexible airfoil with a freeplay nonlinearity. J. Sound Vibr., 1996, 193 (4), 923–946.

O'Niel

Strganac

T. W.

Aeroelastic response of a rigid wing supported by nonlinear springs. J. Aircr., 1998, 35 (4), 616–622.

Tang

Dowell

E. H.

Hall

K. C.

Limit cycle oscillations of a cantilevered wing. Am. Inst. Aeronaut. Astronaut. J., 1999, 37 (3), 364–371.

10.

Safi

S. A.

Kelly

D. W.

Archer

R. D.

Model for development of backlash in aircraft control circuit mechanical links. Am. Inst. Aeronaut. Astronaut. J. Aircr., 1999, 36 (2), 480–482.

11.

Means of Compliance with Section 23.629, Flutter. Advisory Circular 23.629–1A, US Department of Transport, Federal Aviation Administration, 1985.

12.

Fung

Y. C.

An Introduction to the Theory of Aeroelasticity, 1955 (John Wiley, London).

13.

Bisplinghoff

R. L.

Ashley

Halfman

R. L.

Aeroelasticity, 1955 (Addison-Wesley, Reading, Massachusetts).

14.

Scanlan

R. H.

Rosenbaum

Introduction to the Study of Aircraft Vibration and Flutter, 1st edition, 1951 (Macmillan, London).

15.

Wood

L. A.

Aircraft Vibration and Flutter, Vols I and II, 1995 (The Sir Lawrence Wackett Centre for Aerospace Design Technology, Royal Melbourne Institute of Technology, Melbourne).

16.

Lin

R. M.

Ewins

D. J.

Chaotic vibration of mechanical systems with backlash. J. Mech. Systems Signal Processing, 1993, 7 (3), 257–272.

17.

Archard

J. F.

Contact and rubbing of flat surfaces. J. Appl. Physics, 1953, 24 (8), 981–988.

18.

Design and Material Selection for Dry Rubbing Bearings, Item 87007, 1987 (Engineering Science Data Unit, London).

19.

Engal

P. A.

Impact wear analysis and application. In Wear Control Handbook (Eds Peterson

M. B.

Winer

W. O.

) 1980, pp. 1103–1141 (American Society of Mechanical Engineers, New York).

20.

Bayer

R. G.

Mechanical Wear Prediction and Prevention, 1994 (Marcel Dekker, New York).

Interaction between wear processes and limit cycle oscillations of a control surface with free-play non-linearity

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