Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-29T09:40:06.391Z Has data issue: false hasContentIssue false
  • English
  • Français

Equivalent dynamic beam–rod models of aircraft wing structures

Published online by Cambridge University Press:  04 July 2016

U. Lee
U. Lee*
Affiliation:
Department of Mechanical Engineering Inha University, Incheon, South Korea
Get access Rights & Permissions [Opens in a new window]

Abstract

The equivalent continuum beam-rod model of an aircraft wing structure with composite laminated skins has been developed based on the concept of energy equivalence. The equivalent structural properties of the continuum beam-rod model are obtained by directly comparing the reduced stiffness and mass matrices for a typical segment of aircraft wing with those for a finite element of continuum beam-rod model. The finite element stiffness and mass matrices are condensed through the well known finite element formulation procedure to be used in calculating the reduced stiffness and mass matrices for the aircraft wing segment in terms of the continuum degrees of freedom introduced in this paper. The present method of continuum modelling may yield every equivalent structural property including all possible couplings between bending, torsional and transverse shear deformations. To evaluate the equivalent continuum beam-rod model developed herein, the free vibration and aeroelastic analyses for a box-beam type aircraft wing structure have been conducted by using the continuum beam-rod model, and the numerical results are compared with the results by using other different models of the aircraft wing structure.

Type
Research Article
Information
The Aeronautical Journal , Volume 99 , Issue 990 , December 1995 , pp. 450 - 457
Copyright
Copyright © Royal Aeronautical Society 1995 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Noor, A.K., Anderson, M.S. and Green, W.H. Continuum models for beam and plate-like lattice structures, AIAA J, 1978, 16, (12), pp 12191228.Google Scholar
2. Nayfeh, A.H. and Hefzy, M.S. Continuum modelling of the mechanical and thermal behaviour of discrete large structure, AIAA J, 1981, 19, (4), pp 766773.Google Scholar
3. Sun, C.T., Kim, B.J. and Bogdanoff, T.L. On the derivation of equivalent simple models for beam and plate-like structures in dynamic analysis, AIAA Paper 81-0624, 1981, pp 523532.Google Scholar
4. Lee, U. Dynamic continuum modelling of beamlike space structures using finite element matrices, AIAA J, 1990, 28, (4), pp 725731.Google Scholar
5. Lee, U. Dynamic continuum plate representations of large thin lattice structures, AIAA J, 1993, 31, (9), pp 17341736.Google Scholar
6. Giles, G.L. Equivalent plate analysis of aircraft wing box structure with general planform geometry, J Aircr, 1986, 23, (11), pp 859864.Google Scholar
7. Giles, G.L. Further generalisation of an equivalent plate representation for aircraft structural analysis, J Aircr, 1989, 26, (1), pp 6774.Google Scholar
8. Kapania, R.K. and Castel, F. A simple element for aeroelastic analysis of undamped and damped wings, AIAA J, 1990, 28, (2), pp 329337.Google Scholar
9. Hodges, D.H. Review of composite rotor blade modelling, AIAA J, 1990, 28, (3), pp 561565.Google Scholar
10. Bauchau, O.A., and Hong, C.H. Finite element approach to rotor blade modelling, J ofAmer Heli Soc 1987, 31, (1), pp 6067.Google Scholar
11. Bauchau, O.A. and Hong, C.H. Large displacement analysis of naturally curved and twisted composite beams, AIAA J, 1987, 25, (11), pp 14691475.Google Scholar
12. Bauchau, O.A. and Hong, C.H., Nonlinear composite beam theory, ASME J of App Mech, 1988, 55, pp 156163.Google Scholar
13. Stemple, A.D. and Lee, S.W. Finite-element model for composite beams with arbitrary cross-sectional warping, AIAA J, 1988, 26, (12), pp 15121520.Google Scholar
14. Mansfield, W.H. and Sobey, A.J. The fibre composite helicopter blade, Part 1: Stiffness properties, Part 2: Prospects for aeroelastic tailoring, Aeronaut Q, 1979, pp 413449.Google Scholar
15. Rehfield, L.W. Design analysis methodology for composite rotor blade, AFWAL-TR-85-3094, 1985, pp (v(a)-l-v(a)-15).Google Scholar
16. Rehfield, L.W., Atilgan, A.R. and Hodges, D.H. Nonclassical behaviour of thin-walled composite beams with closed cross sections, J Amer Heli Soc, April 1990, 35, (2), pp 4250.Google Scholar
17. Libove, C. Stresses and rate of twist in single-cell thin-walled beams with anisotropic walls, AIAA J, 1988, 26, (9), pp 11071118.Google Scholar
18. Bauchau, O.A. A beam theory for anosotropic materials, ASME J of App Mech, 1985, 52, pp 416422.Google Scholar
19. Bauchau, O.A. and Hong, C.H. Finite element approach to rotor blade modelling, J ofAmer Heli Soc, 1987, 32, (1), pp 6067.Google Scholar
20. Kosmatka, J.B. and Friedmann, P.P. Structural dynamic modelling of advanced composite propellers by the finite element method, 28th AIAA/ASME/ASCE/AHS Structures, Structural Dynamics and Materials Conference, Monterey, California, 1987.Google Scholar
21. Sivaneri, N.T. and Chopra, I. Dynamic stability of a rotor blade using finite element analysis, AIAA J, 1982, 20, (5), pp 716728.Google Scholar
22. Sivaneri, N.T. and Chopra, I. Finite element analysis for bearingless rotor blade aeroelasticity, J of Amer Heli Soc, 1984, 29, (2), pp 4251.Google Scholar
23. Hong, C.H. and Chopra, I. Aeroelastic stability analysis of a composite rotor blade, J Amer Heli Soc, 1985, 30, (2), pp 5767.Google Scholar
24. Hong, C.H. and Chopra, I. Aeroelastic stability analysis of a composite bearingless rotor blade, J of Amer Heli Soc, 1986, 31, (4), pp 2935.Google Scholar
25. Chandra, R., Stemple, A.D. and Chopra, I. Thin-walled composite beams under bending, torsional and extensional loads, J Aircr, 1990, 27, (7), pp 619626.Google Scholar
26. Song, O. and Librescu, L. Dynamic response to time-dependent excitation of cantilevered aircraft wing structures modelled as thin- walled beams, A1AA/SDM Conference, Paper AIAA-92-2213-CP, 1991.Google Scholar
27. Smith, E.C. and Chopra, I. Formulation and evaluation of an analytical model for composite box-beams, J of Amer Heli Soc, 1991, 36, (3), pp 2335.Google Scholar
28. Bisplinghoff, R.L. and Asbley, H. Principles of Aeroelasticity, Dover Pub, New York, 1975.Google Scholar
29. Langhaar, H.L. Energy Methods in Applied Mechanics, 1962, John Wiley & Sons, New York.Google Scholar
30. JrYates, E.C. Calculation of flutter characteristics for finite-span swept or unswept wings at subsonic and supersonic speeds by a modified strip analysis, NACA RM L57L10, 1958.Google Scholar
31. Bergen, P.D. Shape Sensitivity Analysis of Wing Dynamic Aeroelastic Response, MS Thesis, Virginia Polytechnic Institute and Stab University, July 1988.Google Scholar