The purpose of this study is to investigate the delamination growth behavior of a glass fabric reinforced laminated composite under Mode I fatigue loading and to examine the applicability of a new fatigue crack growth rate model to this material. In this study, double contilever beam specimens were subjected to tension-tension cyclic loads with three different load ratios and the delamination growth rate was measured using the compliance method. The delamination growth rate was related to the strain energy release rate during fatigue cycling by a power law equation that takes into account not only the effect of the strain energy release rate range, but also the effect of delamination growth at various stages of loading using a weight average strain energy release rate. It was observed that this new model can represent the delamination growth rate of the fabric reinforced laminated composite at three different load ratios in a single unifying curve.

Issue Section:
Technical Papers
Topics:
Composite materials, Delamination, Fatigue, Textiles, Stress, Tension, Fatigue cracks, Glass, Weight (Mass)
1.
Atodaria
D. R.
,
Putatunda
S. K.
, and
Mallick
P. K.
,
1997
a, “
A Fatigue Crack Growth Model for Random Fiber Composites
,”
Journal of Composite Materials
, Vol.
31
, No.
18
, pp.
1838
1855
.
2.
Atodaria, D. R., Putatunda, S. K., and Mallick, P. K., 1997b, “Fatigue Crack Growth Behavior of A Random Fiber Sheet Molding Compound Composite,” 11th International Conference on Composite Materials, Gold Coast, Australia, July 12.
3.
Davies, P., 1989, “Delamination,” Advanced Composites, I. K. Partridge, ed., Elsevier Science, pp. 303–329.
4.
de Charentenay, F, X., Harry, J. M., Prel, Y. J., and Benzeggah, M. L., 1984, “Characterizing the Effect of Delamination Defect by Mode I Delamination Test,” Effects of Defects in Composite Materials, ASTM STP 836, pp. 84–103.
5.
Dowling, N. E., 1993, Mechanical Behavior of Materials, Prentice-Hall, N.Y.
6.
Kanninen
M. F.
,
1973
, “
An Augmented Double Cantilever Beam Model for Studying Crack Propagation and Arrest
,”
International J. of Fracture
, Vol.
9
, pp.
83
92
.
7.
Martin, R. H., and Murri, G. B., 1990, “Characterization of Mode I and Mode II Delamination Growth and Thresholds in AS 4/PEEK Composites,” Composite Materials: Testing and Design (9th Volume), ASTM STP 1059, pp. 251–270.
8.
Newaz, G. M., Lustiger, A., and Yung, J-Y., 1989, “Delamination Growth under Cyclic Loading at Elevated Temperature in Thermoplastic Composites,” Advances in Thermoplastic Matrix Composite Materials, ASTM STP 1044, pp. 264–278.
9.
Paris
P. C.
, and
Erdogan
F.
,
1963
, “
A Critical Analysis of Crack Propagation Laws
,”
ASME Journal of Basic Engineering
, Vol.
85
, pp.
528
534
.
10.
Poursartip, A., 1987, “The Characterization of Edge Delamination Growth in Laminates under Fatigue Loading,” Toughened Composites, ASTM STP 937, pp. 222–241.
11.
Ramkumar, R. L., and Whitcomb, J. D., 1985, “Characterization of Mode I and Mixed-Mode Delamination Growth in T300/5208 Graphite/Epoxy,” Delamination and Debonding of Materials, ASTM STP 876, pp. 315–335.
12.
Scrivner, G. C., and Chan, W. S., 1993, “Effects of Stress Ratio on Edge Delamination Characteristics in Laminated Composites,” Composite Materials: Fatigue and Fracture, ASTM STP 1156, pp. 538–551.
This content is only available via PDF.
Copyright © 1999
 by The American Society of Mechanical Engineers
You do not currently have access to this content.