Sage Journals: Discover world-class research

Abstract

Compressive failure of carbon fiber reinforced unidirectional vinyl ester composites (CFRP) under impact is studied experimentally and analytically. Both impact and quasi-static compressive tests are carried out for CFRP with Vf= 10% to 60%. Stress-stain curves at strain rates of 10-3 s-1 and 10-3 s-1 are obtained. The compressive strength increases under impact loading. As the fiber volume fraction increases, the failure mode changes from shear failure to kinking. The local stress fields in the fiber and matrix are analysed to illustrate the deformation and compressive failure mechanisms for unidirectional composites. Based on analysing the local matrix yield at the fiber-matrix interface due to shear stress concentration, the compressive strength is predicted. Assuming that shear failure and kinking occurs on the plane of the maximum shear strain in composites, the angle of the plane of the maximum shear strain is determined. The analytical model is utilised to explain the various experimental observations of CFRP failure, as well as GFRP failure reported in Reference [17], such as, the compressive strength, the failure mode, the effects of fiber volume fractions and strain rates.

Keywords

compressive failure CFRP strain-rate volume fraction

Get full access to this article

View all access options for this article.

References

1. Rosen, B. W. 1965. “Mechanics of Composite Strengthening,” Fiber Composite Materials, ASM Metal Park, OH, pp. 37–75.

2. Argon, A. G. 1972. “Fracture of Composites,” Treatise on Material Science,Vol. 1, H. Herman , Ed., pp. 79–114.

3. Budiansky, B. 1983. “Micromechanics,” Computers and Structures, 16(1–4), pp. 3–12.

4. Jelf, P. M. and N. A. Fleck . 1992. “Compression Failure Mechanisms in Unidirectional Composites,” J. Comp. Mater., 26(18), pp. 2706–2726.

5. Schultheisz, C. R. and A. M. Waas . 1996. “Compressive Failure of Composites, Part I: Testing and Micromechanical Theories,” Prog. Aerospace Sci., 32, pp. 1–42.

6. Waas, A. M. and C. R. Schultheisz . 1996. “Compressive Failure of Composites, Part II: Experimental Studies,” Prog. Aerospace Sci., 32, pp. 43–78.

7. Hsiao, H. M. and I. M. Daniel . 1998. “Strain Rate Behavior of Composite Materials,” Composite Part B, 29B, pp. 521–533.

8. Kolsky, H. 1949. “An Investigation of the Mechanical Properties of Materials at Very High Rates of Loading,” Proc. Phys. Soc., London, 62B, pp. 676–700.

9. Sierakowski, R. L. , G. E. Nevill, Jr. , C. A. Ross and E. R. Jones . 1971. “Dynamic Compressive Strength and Failure of Steel Reinforced Epoxy Composites,” J. Comp. Mater., 5, pp. 362–377.

10.

10. Jenq, S. T. and S. L. Sheu . 1993. “High Strain Rate Compressional Behavior of Stitched and Unstitched Composite Laminates with Radial Constraint,” Comp. Structure, 25, pp. 427–438.

11.

11. Harding. J.

“Effect of Strain Rate and Specimen Geometry on the Compressive Strength of Woven Glass-Reinforced Epoxy Laminates,”

Composites, 24(2), 1993, pp. 323–332.

12.

12. Zheo, H. and G. Gary . 1997. “An Experimental Investigation of Compressive Failure Strength of Fiber-Reinforced Polymer-Matrix Composite Plates under Impact Loading,” Composite Science and Technology, 57, pp. 287–292.

13.

13. Woldesenbet, E. and J. R. Vinson . 1999. “Specimen Geometry Effect on High-Strain-Rate Testing of Graphite/Epoxy Composites,” AIAA Journal, 37(9): pp. 1102–1106.

14.

14. Fan, J. and W. S. Slaughter . 1997. “High Strain Rate Compression of Fiber Composites,” J. Mech. Phys. Solids, 45(5), pp. 731–751.

15.

15. Sierakowski, R. L. and S. K. Chaturvedi . 1997. “Dynamic Loading and Characterization of Fiber-Reinforced Composites,” John Wiley & Sons, Inc. New York.

16.

16. Nemat-Nasser, S. , Y-F. Li , and J. B. Isaac . 1994. “Experimental/Computational Evaluation of Flow Stress at High Strain Rates with Application to Adiabatic Shear Banding,” Mech. of Materials, 17, pp. 111–134.

17.

17. Yuan, J. , N. Takeda and A. M. Waas . “Impact Compressive Failure of GFRP Unidirectional Composites,” J. Sci. and Eng. of Composite Mater., 9(11), 2000, pp. 1–9.

18.

18. J. Yuan , N. Takeda and A. M. Waas , “A Note on the Data Processing in the Split Hopkinson Pressure Bar Tests,” Experimental Techniques, 22(5), Sept-Oct. 1998, pp. 21–24.

19.

19. Hahn, H. T. and J. G. William . 1986. “Composite Failure Mechanics in Unidirectional Composites,” Composite Materials: Testing and Design 7th Conference,ASTMSTP 893, pp. 115–139.

20.

20. Wisnom, M. R. 1990. “The Effect of Fiber Misalignment on the Compressive Strength of Unidirectional Carbon Fiber/Epoxy,” Composites, 21(5), pp. 403–407.

21.

21. Karayaka, M. and H. Sehitoglu , 1996. “Failure Behavior of Unidirectional AS4/3501-6 Carbon/Epoxy Laminates,” J. Comp. Mater., 30(10), pp. 1150–1176.

22.

22. Hashin, Z. and B. W. Rosen . 1964. “The Elastic Moduli of Fiber-Reinforced Materials,” J. Application Mechanics, 31, pp. 223–232.

23.

23. Christensen, R. M. 1979. “Mechanics of Composite Materials,” John Wiley and Sons, Inc.

24.

24. Z. Hashin , 1979. “Analysis of Properties of Fiber Composites with Anisotropic Constituents,” J. Applied Mechanics, 46, pp. 543–550.

Compressive Failure Mechanism and Impact Behavior of Unidirectional Carbon-Fiber/Vinyl Ester Composites

Abstract

Keywords

Get full access to this article

References