Stability and Limit Cycle Oscillation Amplitude Prediction for Multi-DOF Aeroelastic Systems with Piecewise Linear Non-Linearities

Dimitriadis, Grigorios; Vio, Gareth Arthur; Cooper, Jonathan Edward

Paper published in a book (Scientific congresses and symposiums)

Dimitriadis, Grigorios; Vio, Gareth Arthur; Cooper, Jonathan Edward

2004 • In Proceedings of the 2004 International Conference on Noise and Vibration Engineering

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Keywords :

Nonlinear Aeroelastic Systems; Limit Cycle Oscillations; Piecewise linear nonlinearities

Abstract :

[en] Discontinuous non-linearities such as freeplay and bilinear stiffness are often encountered in aeroelastic systems, sometimes as a result of wear and tear. It is important to predict the effect of such non-linearities on the dynamic behaviour of a system, so that adequate safety guidelines can be drafted. As a consequence, the prediction of the bifurcation behaviour of a system featuring a discontinuous nonlinearity is crucial. Additionally, the post-bifurcation behaviour of the system is also of interest since it may consist of relatively harmless Limit Cycle Oscillations (LCO) of low amplitude or of unexpected catastrophic high amplitude LCOs. In this paper the bifurcation and post-bifurcation behaviour of a simulated Multi-DOF aeroelastic system with bilinear and freeplay nonlinearities are investigated using the Harmonic Balance method and a novel method for the prediction of the bifurcation conditions and LCO amplitudes. The method is based on the fact that the nonlinearities investigated are piecewise linear. The ratios of the real parts of the system eigenvalues in the various ranges of the bilinear spring are used in order to infer LCO amplitude information. By means of a demonstration on a simulated aeroelastic system with piece-wise linear stiffness, it is shown that the proposed approach is successful in yielding the full bifurcation and post-bifurcation behaviour of the system. Comparison of the amplitude predictions obtained from the Harmonic Balance technique and the Piecewise Linearisation proposed approach show that the latter are more consistent and closer to the true amplitudes throughout the airspeed range. The bifurcation analysis is extended to the special case where the inner stiffness of the bilinear spring is equal to zero, i.e. freeplay stiffness. It is shown that the Piecewise Linear analysis fails to capture the bifurcation behaviour for this case, while the Harmonic Balance method still produces some accurate predictions.

Disciplines :

Aerospace & aeronautics engineering

Author, co-author :

Dimitriadis, Grigorios ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Interactions Fluide-Structure - Aérodynamique expérimentale

Vio, Gareth Arthur; University of Manchester > School of Engineering

Cooper, Jonathan Edward; University of Manchester > School of Engineering

Language :

English

Title :

Stability and Limit Cycle Oscillation Amplitude Prediction for Multi-DOF Aeroelastic Systems with Piecewise Linear Non-Linearities

Publication date :

September 2004

Event name :

2004 International Conference on Noise and Vibration Engineering

Event organizer :

Katholieke Universiteit Leuven

Event place :

Leuven, Belgium

Event date :

du 20 septembre 2004 au 22 septembre 2004

Audience :

International

Main work title :

Proceedings of the 2004 International Conference on Noise and Vibration Engineering

Publisher :

Katholieke Universiteit Leuven, Heverlee, Belgium

ISBN/EAN :

90-73802-82-2

Pages :

2101-2114

Available on ORBi :

since 30 September 2009

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Bibliography

C.M. Jr Denegri. Limit cycle oscillation flight test results of a fighter with external stores. Journal of Aircraft, 37(4):761-769, 2000.
S.A. Dunn, P.A. Farrell, P.J. Arms, C.A Hardie, and C.J. Rendo. F/A-18A Flight Flutter Testing Limit Cycle Oscillations of Flutter? In Proceedings of the CEAS International Forum on Aeroelasticity and structural dynamics, Madrid, Spain, June 2001.
F. Verhulst. Nonlinear differential equations and dynamical systems. Springer, 2nd edition, 2000.
B. H. K. Lee, S. J. Price, and Y. S. Wong. Nonlinear aeroelastic analysis of airfoils: bifurcation and chaos. Progress in Aerospace Sciences, 35:205-334, 1999.
L. Liu, Y. S. Wong, and B. H. K. Lee. Application of the centre manifold theory in non-linear aeroelasticity. Journal of Sound and Vibration, 234(4):641-659, 1999.
C.S. Hsu. Cell-to-Cell Mapping. Springer-Verlag, New York, 1987.
K.J. Badcock, M.A. Woodgate, B.E. Richards, and G.N. Barakos. The application of sparse matrix techniques to the cfd based bifurcation analysis of a symmetric wing. In Proceedings of the CEAS International Forum on Aeroelasticity and structural dynamics, Amsterdam, The Netherlands, June 2003.
H. Poincaré. Les méthodes nouvelles de la méchanique célèste. Gauthier-Villars, Paris, 1893.
A. Raghothama and S. Narayanan. Non-linear dyamics of a two-dimensional airfoil by incremental harmonic balance method. Journal of Sound and Vibration, 226(3):493-517, 1999.
I. Roberts, D. P. Jones, N. A. J. Lieven, M. Di Bernado, and A. R. Champneys. Analysis of piecewise linear aeroelastic systems using numerical continuation. Proceedings of the I MECHE Part G Journal of Aerospace Engineering, 216(1):1-11, 2002.
G. J. Hancock, J. R. Wright, and A. Simpson. On the teaching of the principles of wing flexure-torsion flutter. Aeronautical Journal, 89(888):285-305, October 1985.
G. Dimitriadis and J. E. Cooper. Limit cycle oscillation control and suppression. Aeronautical Journal, 103(1023):257-263, May 1999.
E. Breitbach. Effects of structural nonlinearities on aircraft vibration and testing. Report R-665, AGARD, January 1978.
W. G. Luber. Flutter prediction on a combat aircraft involving backlash and actuator failures on control surfaces. In Proceedings of the CEAS International Forum on Aeroelasticity and structural dynamics, pages 173-182, Rome, Italy, June 1997.
M.D. Conner, L.N. Virgin, and E.H. Dowell. Accurate numerical integration of state-space models for aeroelastic systems with freeplay. AIAA Journal, 34:2202-2205, 1996.
N.Kryloff and N.Bogoliuboff. Introduction to Nonlinear Mechanics (a free translation by S.Lefschetz). Princeton University Press, 1947.
Z. C. Yang and L. C. Zhao. Analysis of limit cycle flutter of an airfoil in incompressible flow. Journal of Sound and Vibration, 123(1):1-13, 1988.