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Numerical and Experimental Evaluation of Tensile Failure in Continuous Fiber Reinforced Ceramic Composite  

Kwon, Oh Heon (Department of Safety Engineering, Pukyong National University)
Park, Keyoung Dong (School of Mechanical Engineering, Pukyong National University)
Watanabe, Katsuhiko (Institute of Industrial Science, University of Tokyo)
Publication Information
International Journal of Safety / v.2, no.1, 2003 , pp. 23-27 More about this Journal
Abstract
Recently, continuous fiber reinforced ceramic composite(CFCC) has attracted attention to a number of engineers because of its significant benefit for several industrial area. This work was conducted to provide a basic characteristic of CFCC for tensile loading condition. The numerical analysis by general purpose finite element program was accomplished and compared with an experimental tensile test. The stress strain curves were expressed well by the numerical analysis and the first matrix cracking stress was in accordance with that of the experimental result. Moreover, fracture pattern was shown by kill command graphically.
Keywords
tensile failure; CFCC(Continuous Fiber Ceramic Composite); matrix cracking stress; fiber bridging effect;
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1 R. T. Bhatt, Ceramic International, Tensile Properties and Micro structural Characterization of Hi-Nicalon SiCIRBSN Composites, Vol. 26, pp. 535-539, 2000
2 W. A Curtin, Ultimate strength of fiber reinforced ceramics and metals, Composite A, Vol. 24, pp. 98-103, 1993   DOI   ScienceOn
3 C. X. Campbell, MS Thesis, University of Washington, Seattle, 1998
4 K. Y. Mark, MS Thesis, University of Washington, 1996
5 H. H. K. Xu, P. Ostertag and L. M. Braun, Short-Crack mechanical Properitiesand failure Mechanism of Si3N4 matrix/SiC fiber Composite, J. Am. Ceram. Soc., Vol. 77, pp. 1889-1896, 1994   DOI   ScienceOn
6 A G. Evans and D. B. Marshall, Mechanical Behavior of Ceramic matrix Composites, Fiber Reinforced Ceramic Composite Materials, Processing and Technology, Edited by General Atomics, San Diego, pp. 8-10, 1990
7 M. G. Jenkins, J. P. Piccola, Jr. and E. Lara-Curzio, Fracture Mechanics of Ceramics, Vol. 12, pp. 267282, 1996
8 S. K. Mital, Computational simulation of continuous fiber reinforced ceramic matrix composites behavior, Journal of advanced materials, Vol. 32, No.1, pp. 46-59, 2000
9 D. B. Marshall, B. N. Cox and AG.Evans, The mechanics of matrix cracking in brittle matrix fiber composites, Acta Metallurgica, Vol. 33, pp. 2013-2021, 1985   DOI   ScienceOn
10 K. Liao and K. Reifsnider, A tensile Strength model for Unidirectional fiber-reinforced brittle Matrix composites, Int. Jour. of Fracture, Vol. 106, pp. 95-115, 2000   DOI   ScienceOn
11 O. I .Benevolenski, J. Karger-Kocsis, T. Czigany and G.Romhany, Mode I fracture resistance of glass fiber mat-reinforced polypropylene composites at various degree of consolidation, Composites, Part A, Vol. 80, in press, 2003
12 D. C. Phillips, Long-fiber reinforced ceramics, pp. 190-194, Ceramic-Matrix Composite, Blackie, 1992