Damage Analysis in Sandwich Beams with Cellular Core using Micromechanics Coupled to a Statistical Approach

Abstract

This paper deals with the analysis of damage and mechanical properties of sandwich beams. The face sheets consist of glass mat-reinforced polyester (GMRP) perfectly bonded to core material. The latter is a regular array of thermoplastic tubular cells called Tubulam®. Mechanical behaviour of sandwich beams is analysed and simulated under three and four-point bending and correlated to experimental results. Sandwich beam modelling was performed according to two steps. First, skins behaviour is modelled by a micromechanical approach based upon the generalised Mori and Tanaka theory. Moreover, in the second step, an analytical model based on the laminate theory predicts the overall properties of core material.

In this work, damage mechanisms are introduced in the modelling using probabilistic concepts applied at the microscopic scale of face sheets (fibres, matrix, interface between fibres and matrix) as well as at the mesoscopic scale namely tubular core and bond layer between core and skins. Finally, the developed model is validated by experimental tests: three and four-point bending. Experimentally measured global responses of the sandwich beams are compared to those numerically simulated and discussed in terms of damage chronology and evolution. The main point of the developed analysis is that the mechanical behaviour may be predicted on the basis of the structural parameters. Hence, it may provide an important analytical tool for aided design to optimise sandwich structures with respect to applied loading and micromechanical parameters.

Keywords

micromechanics sandwich beam tubular core damage mechanisms Weibull law

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References

1. Gibson, L.J. and Ashby, M.F. (1988). Cellular Solids Structure and Properties, (ed) Pergamon Press, England .

2. Kalamkarov, A.L. and Kolpakov, A.G. (1993). Numerical Design of Thin-walled Structural Members on Account of their Strength , Int. Journal for Numerical Methods in Engineering, 36: 3441-3449 .

3. Kalamkarov, A.L. (1992). Composite and Reinforced Elements of Construction, Wiley, Winchester, N.Y.

4. Karlsson, K.F. and Astrom, B.T. (1997). Manufacturing and Applications of Structural Sandwich Components , Composites Part A., 28A: 97-111 .

5. Kelsey, S. , Gellatly, R.A. and Clark, B.W. (1958). The Shear Modulus of Foil Honeycomb Core, Aircraft Engn., 294-302.

6. Grediac, M. (1993). A Finite Element Study of the Transverse Shear in Honeycomb Cores , Int. Journal of Solids Structures, 30-N13: 1777-1788 .

7. Desrumaux, F. , Meraghni, F. and Benzeggagh, M.L. (2000). Micromechanical Modelling Coupled to a Reliability Approach for Damage Evolution in Composite Materials , Applied Composite Materials, 7(4): 231-250 .

8. Desrumaux, F. , Meraghni, F. and Benzeggagh, M.L. (2001). Generalised Mori-Tanaka Scheme to Model Anisotropic Damage Using Numerical Eshelby Tensor , Journal of Composite Materials, 3(1): 603-624 .

9. Desrumaux, F. , Meraghni, F. and Benzeggagh, M.L. (1999). Self-consistent Modelling of Damaged Elastic Behaviour using Reliability Approach , In: Proc. Form the 12th International Conference on Composite Materials, Paris 1999.

10.

10. Meraghni, F. , Desrumaux, F. and Benzeggagh, M.L. (1999). Mechanical Behaviour of Cellular Core for Structural Sandwich Panels , Composites Part A, A30: 767-779 .

11.

11. Harlow, D.G. and Phoenix, S.L. (1978). The Chain of Bundles Probability Model for the Strength of Fibrous Materials. I: Analysis and Conjectures , Journal of Composite Materials, 12: 195-214 .

12.

12. Fitoussi, J. , Guo, G. and Baptiste, D. (1998). A Statistical Micro Mechanical Model of Anisotropic Damage for SMC Composites , Composites Science and Technology, 58: 759-763 .

13.

13. Chou, T.W. (1992). Microstructural Design of Fiber Composites, Cambridge Solid State Science Series, Cambridge University Press (GB) , ISBN: 0-521-35482-X, 99-168.

14.

14. Hitchon, J.W. and Phillips, D.C. (1978). The Effect of Specimen Size on the Strength of CFRP , Composites, 9(2): 119-124 .

15.

15. Sun, C.T. and Yamada, S.E. (1978). Strength Distribution of a Unidirectional Fibre Composite , Journal of Composite Materials, 12: 169-176 .

16.

16. Arnould, J.F. (1982). Etude de l’endommagement des materiaux composites par decohesion fibre-matrice, C.R. JNC 3, Paris , 159-169.

17.

17. Noor, A.K. and Peters, J.M. (1999). Analysis of Curved Sandwich Panels with Cutouts Subjected to Combined Temperature Gradient and Mechanical Loads , Journal of Sandwich Structures and Materials, 1: 42-59 .

18.

18. Standard Test Method for Flexural Properties of Flat Sandwich Constructions, ASTM Standard, C393-62. Reproved 1998.

19.

19. Benveniste, Y. (1987). A New Approach to the Application of Mori-Tanaka’s Theory , Mechanics of Materials, 6: 147-157 .

20.

20. Chen, T. , Dvorak, G.J. and Benveniste, Y. (1992). Mori-Tanaka Estimates of the Overall Elastic Moduli of Certain Composite Materials , Journal of Applied Mechanics, 59: 539-554 .

21.

21. Nemat-Nasser, S. and Hori, M. (1993). Micromechanics: Overall Properties of Heterogeneous Materials, North-Holland Series in Applied Mathematics and Mechanics, Vol. 37, ISBN 0-444-89881-6.

22.

22. Mori, T. and Tanaka, K. (1973). Average Stress in Matrix and Average Elastic Energy of Materials with Misfitting Inclusion, Acta Metal., 21-571.

23.

23. Mura, T. (1987). Micromechanics of Defects in Solids, 2nd edn, Martinus Nijhoff, la Hague .

24.

24. Mura, T. and Cheng, P.C. (1977). The Elastic Field Outside an Ellipsoidal Inclusion , ASME Journal of Applied Mechanics, 44: 591-594 .

25.

25. Meraghni, F. , Blakeman, C.J. and Benzeggagh, M.L. (1996). Effect of Interfacial Decohesion on Stiffness Reduction in a Random Discontinuous Fibre Composite Containing Matrix Microcracks , Composites Science and Technology, 56: 541-555 .

26.

26. Meraghni, F. and Benzeggagh, M.L. (1995). Micromechanical Modelling of Matrix Degradation in Randomly Oriented Discontinuous Fibre Composites , Composites Sciences and Technology, 55: 171-186 .

27.

27. Gavazzi, A.C. and Lagoudas, D.C. (1990). On the Evaluation of Eshelby’s Tensor and its Application to Elastoplastic Fibrous Composites , Computational Mechanics, 7: 13-19 .

28.

28. Berthelot, J.M. (1992). Matériaux composites, comportement mécanique et analyse des structures, (ed.) Masson, Paris .

29.

29. Allen, H.G. (1969). Analysis and Design of Sandwich Panels, Pergamon Press, Oxford .