Sage Journals: Discover world-class research

Abstract

This article is concerned with the development of a finite element (FE) based micromechanics model for the prediction of compressive strength and post-peak compression response of 2D triaxial braided carbon fiber polymer matrix composites (2DTBC). This micromechanics based study was carried out on a series of single and multiple representative unit cell (RUC) 3-D FE models. The uniaxial compressive response, including unstable equilibrium paths, was studied using an arc-length method in conjunction with the ABAQUS commercial FE code. In the reported study, explicit account of the braid microstructure (geometry and packing) and the measured inelastic properties of the matrix (the in-situ properties) are accounted for via the use of the FE method. This enables accounting for the different length scales that are present in a 2DTBC. The computational model provides a means to assess the compressive response of 2DTBC and its dependence on various microstructural parameters. The model provides a means to compute the compression strength allowable for a 2DTBC structure. In particular, the dependence of compressive strength on the axial fiber tow properties and axial tow geometrical imperfections is discussed and shown to be significant in capturing the mechanism of damage development. Results are presented for 1, 4, 9, and 16 RUC representations of the 2DTBC, enabling to examine the dependence of compressive strength (or lack thereof) on the size of the region that is modeled. The predicted results are found to compare favorably against experiment.

Keywords

compression braided textile composite multicell micromechanics.

Get full access to this article

View all access options for this article.

References

Mungalov, D. and Bogdanovich, A. (2004). Complex Shape 3-d Braided Composite Preforms: Structural Shapes for Marine and Aerospace, SAMPE Journal, 40(3): 7-21.

Wan, Y.Z. , Chen, G.C. , Huang, Y. , Li, Q.Y. , Zhou, F.G. , Xin, J.Y. and Wang, Y.L. (2005). Characterization of Three-dimensional Braided Carbon/Kevlar Hybrid Composites for Orthopedic Usage , Materials Science and Engineering, A, 398: 227-232.

Chou, T.W. (1992). Microstructural Design of Fiber Composites, Cambridge Solid State Science Series.

Ishikawa, T. and Chou, T.W. (1982). Elastic Behavior of Woven Hybrid Composites, Journal of Composite Materials, 16(1): 2-19.

Ishikawa, T. and Chou, T.W. (1983). One-dimensional Micromechanical Analysis of Woven Fabric Composites, AIAA Journal, 21(12): 1714-1721.

Miravete, A. (1999). 3-D Textile Reinforcements in Composite Materials , Woodhead Publishing Limited, Cambridge, UK.

Whitcomb, J. and Noh, J. (2000). Concise Derivation of Formulas for 3d Sublaminate Homogenization, Journal of Composite Materials, 34(6): 522-535.

Naik, N.K. and Stembekar, P.S. (1992). Elastic Behaviour of Woven Fabric Composites: I - Lamina Analysis, Journal of Composite Materials, 26: 2196-2225.

Huang, Z.M. (2000). The Mechanical Properties of Composites Reinforced with Woven and Braided Fabrics, Composite Science and Technology , 60: 479-498.

10.

Sankar, B.V. and Marrey, R.V. (1993). A Unit-cell Model of Textile Composite Beams for Predicting Stiffness Properties, Composites Science and Technology, 49: 61-69.

11.

Naik, R. (1996). Analysis of 2d Triaxial and 3d Multi-interlock Braided Textile Composites, In: Proceedings of 37th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference, Salt Lake City, UT.

12.

Cox, B.N. and Dadkhah, M.S. (1995). The Macroscopic Elasticity of 3d Woven Composites, Journal of Composite Materials, 29: 785-819.

13.

Matsuda, T. , Nimiya, Y. and Ohno, N. (2007). Elastic-viscoplastic Behavior of Plain-woven GFRP Laminates: Homogenization Using a Reduced Domain of Analysis, Composite Structures, 79(4): 493-500.

14.

Lomov, S.V. , Ivanov, D.S. and Verpoest, I. (2007). Meso-fe Modelling of Textile Composites: Road Map, Data Flow and Algorithms, Composite Science and Technology , 67: 1870-1891.

15.

Cox, B.N. , Dadkhah, M.S. , Morris, W.L. and Flintoff, J.G. (1994). Failure Mechanism of 3d Woven Composites in Tension, Compression, and Bending, Acta Metall. Mater., 42(12): 3967-3984.

16.

Dadkhah, M.S. , Cox, B.N. and Morris, W.L. (1995). Compression - Compression Fatigue of 3d Woven Composites, Acta Metall. Mater., 43(12): 4235-4245.

17.

Quek, S.C. , Waas, A.M. , Shahwan, K.W. and Agaram, V. (2003). Analysis of 2d Triaxial Flat Braided Textile Composites, International Journal of Mechanical Sciences, 45: 1077-1096.

18.

Quek, S.C. , Waas, A.M. , Shahwan, K.W. and Agaram, V. (2003). Compressive Response and Failure of Braided Textile Composites: Part 2 - Computations, International Journal of Nonlinear Mechanics, 39(4): 650-663.

19.

Quek, S.C. , Waas, A.M. , Shahwan, K.W. and Agaram, V. (2003). Compressive Response and Failure of Braided Textile Composites: Part 1 - Experiments, International Journal of Nonlinear Mechanics, 39(4): 635-648.

20.

Karkkainen, R.L. and Sankar, B.V. (2006). A Direct Micromechanics Method for Analysis of Failure Initiation of Plain Weave Textile Composites, Composite Science and Technology, 66(1): 137-150.

21.

Karkkainen, R.L. , Sankar, B.V. and Tzeng, J.T. (2007). A Direct Micromechanical Approach Toward the Development of Quadratic Stress Gradient Failure Criteria for Textile Composites, Journal of Composite Materials, 41(16): 1917-1937.

22.

Karkkainen, R.L. , Sankar, B.V. and Tzeng, J.T. (2007). Strength Prediction of Multilayer Plain Weave Textile Composites Using the Direct Micromechanics Method, Composites Part B - Engineering, 38(7-8): 924-932.

23.

Song, S. (2007). Compression Response of Tri-axially Braided Textile Composites, Ph.D. thesis, University of Michigan, Ann Arbor, MI.

24.

Song, S. , Waas, A.W. , Shahwan, K.W. , Faruque, O. and Xiao, X. (2007). Braided Textile Composites Under Compressive Loads: Modeling the Response, Strength and Degradation, Composites Science and Technology, 67: 3059-3070.

25.

Huang, H. and Waas, A.M. (2008). The Effect of Phase Shifted Stacked Layers on the Compression Response of Woven Textile Composites, Journal of Composite Materials, in submission.

26.

Herakovich, C. (1998). Mechanics of Fibrous Composites , McGraw-Hill, New York.

27.

Hill, R. (1948). A Theory of the Yielding and Plastic Flow of Anisotropic Metals, Proc. R. Soc. London, 193(1033): 281-297.

28.

Tang, X.D. and Whitcomb, J.D. (2003). General Techniques for Exploiting Periodicity and Symmetries in Micromechanics Analysis of Textile Composites, Journal of Composite Materials, 37(13): 1167-1189.

29.

Riks, E. (1979). Incremental Approach to the Solution of Snapping and Buckling Problems, International Journal of Solids and Structures, 15(7): 529-551.

30.

Quek, S.C. (2002). Compressive Response and Failure of Braided Textile Composites: Experiments and Analysis, Ph.D. thesis, University of Michigan, Ann Arbor, MI.

Compression Response of 2D Braided Textile Composites: Single Cell and Multiple Cell Micromechanics Based Strength Predictions

Abstract

Keywords

Get full access to this article

References