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Design of composite helicopter rotor blades to meet given cross-sectional properties

Published online by Cambridge University Press:  03 February 2016

S. L. Lemanski ,
P. M. Weaver  and
G. F. J. Hill
S. L. Lemanski
Affiliation:
Department of Aerospace Engineering, University of Bristol, Bristol, UK
P. M. Weaver
Affiliation:
Department of Aerospace Engineering, University of Bristol, Bristol, UK
G. F. J. Hill
Affiliation:
Department of Aerospace Engineering, University of Bristol, Bristol, UK
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Abstract

This paper examines the design of a composite helicopter rotor blade to meet given cross-sectional properties. As with many real-world problems, the choice of objective and design variables can lead to a problem with a non-linear and/or non-convex objective function, which would require the use of stochastic optimisation methods to find an optimum. Since the objective function is evaluated from the results of a finite element analysis of the cross section, the computational expense of using stochastic methods would be prohibitive. It is shown that by choosing appropriate simplified design variables, the problem becomes convex with respect to those design variables. This allows deterministic optimisation methods to be used, which is considerably more computationally efficient than stochastic methods. It is also shown that the design variables can be chosen such that the response of each individual cross-sectional property can be closely modelled by a linear approximation, even though the response of a single objective function to many design parameters is non-linear. The design problem may therefore be reformulated into a number of simultaneous linear equations that are easily solved by matrix methods, thus allowing an optimum to be located with the minimum number of computationally expensive finite element analyses.

Type
Research Article
Information
The Aeronautical Journal , Volume 109 , Issue 1100 , October 2005 , pp. 471 - 475
Copyright
Copyright © Royal Aeronautical Society 2005 

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References

1. Kameyama, M., Fukunaga, H. and Sekine, H.. Optimum design of composite wing model for aeroelastic properties, 1997, Proceedings of 5th Japan International SAMPE Symposium.Google Scholar
2. Chattopadhyay, A., McCarthy, T.R. and Pagaldipti, N.. Multilevel decomposition procedure for efficient design optimization of helicopter rotor blades, AIAA J, 1995, 33, (2), pp 223230.Google Scholar
3. Jung, S.N., Nagaraj, V.T. and Chopra, I.. Assessment of composite helicopter blade modelling techniques, J Am Helicopter Soc, 1999, 44, (3), pp 188205.Google Scholar
4. Wörndle, R.. Calculation of the cross-section properties and the shear stresses of composite rotor blades, Vertica, 1982, 6, pp 111129.Google Scholar
5. Kosmatka, J.B. and Dong, S.B.. Saint-Venant solutions for prismatic anisotropic beams, Int J of Solids and Structures, 1991, 28, (7), pp 917938 Google Scholar
6. Hatch, C. and Lee, A.R.. Determination of the structural properties of helicopter rotor blades by theoretical and experimental methods, 1986, Paper No 67 presented at the 12th European Rotorcraft Forum.Google Scholar
7. Diamond, S.W., Theoretical Prediction of Composite Model Rotor Blade Structural Properties Using Various F.E. Modelling Idealisations, 1996, Defence Research Agency, Farnborough.Google Scholar
8. He, C. and Peters, D.A.. Finite state aeroelastic model for use in rotor design optimisation, J Aircr, 1993, 30, (5), pp 777784.Google Scholar
9. McCarthy, T.R., Chattopadhyay, A. and Zhang, S.. A coupled rotor/wing optimization procedure for high speed tilt-rotor aircraft, 1995, Proceedings of American Helicopter Society 51st Annual Forum, Vol 2.Google Scholar
10. Chattopadhyay, A., McCarthy, T.R. and Seeley, C.E.. Decomposition-based optimisation procedure for high-speed prop-rotors using composite tailoring, J Aircr, 1995, 32, (5), pp 10261033.Google Scholar
11. Chattopadhyay, A. and Narayan, J.. Optimum design of high speed prop-rotors using a multidisciplinary approach, Eng Optimization, 1993, 22, pp 117.Google Scholar
12. Ganguli, R. and Chopra, I.. Aeroelastic optimization of a helicopter rotor with two-cell composite blades, AIAA J, 1996, 34, (4), pp 835854.Google Scholar
13. Chandra, R. and Chopra, I.. Structural behaviour of two-cell composite rotor blades with elastic couplings, AIAA J, 1992, 30, (12), pp 29142924.Google Scholar
14. Hill, G.F.J. and Weaver, P.M.. Analysis of anisotropic prismatic sections, Aeronaut J, April 2004, 108, (1082), pp 197205.Google Scholar
15. Bartholomew, P. and Mercer, A.D., Analysis of an Anisotropic Beam with Arbitrary Cross-Section, Technical Report 84058, Royal Aircraft Establishment.Google Scholar
16. Fukunaga, H.. A solution procedure for determining laminate configurations from lamination parameters, Adv Composite Materials, 1984, 1991, 1, (3), pp 209224.Google Scholar
17. Fukunaga, H. and Sekine, H.. Stiffness design method of symmetric laminates using lamination parameters, AIAA J, 1992, 30, pp 27912793.Google Scholar
18. Miki, M.. Material design of composite laminates with required in-plane elastic properties, Prog in Sci and Eng of Composites, 1982, Hayashi, T., Kawata, K. and Umekawa, S. (Eds), ICCM-IV, Tokyo, Vol 2, pp 17251731.Google Scholar
19. Miki, M.. A Graphical method for designing fibrous laminated composites with required in-plane stiffness, Trans JSCM, 1983, 9, (2), pp 5155.Google Scholar