论文信息 - Finite thermoelastic fracture criterion with application to laminate cracking analysis

Finite thermoelastic fracture criterion with application to laminate cracking analysis

A stress energy criterion for the development of a new finite size crack surface under temperature and load input, in the presence of thermal residual stresses, is established on the basis of an energy release formulation. It is shown that if a fixed specific crack opening surface energy γ exists, an upper bound on the critical energy release can be established on the basis of the thermoelastic principle of minimum complementary energy. On the basis of a variational formulation of thermoelastic laminate analysis a relation is established which permits construction of thermoelastic solutions for cracked laminates by a simple replacement in the corresponding isothermal solution. The results described above are applied to establish relations between crack density and standard deviation of crack interdistances of crack distribution in a cross-ply laminate layer, and load/temperature inputs of the laminate. It is shown that for certain ranges of crack densities, one small to medium and one large, the standard deviation is not needed. The physical and experimental significance of the results obtained is discussed.

Zvi Hashin | Z. Hashin

[1] George J. Dvorak,et al. Progressive Transverse Cracking In Composite Laminates , 1988 .

[2] J. E. Bailey,et al. Multiple transverse fracture in 90° cross-ply laminates of a glass fibre-reinforced polyester , 1977 .

[3] L. Berglund,et al. Thermo-Elastic Properties of Composite Laminates with Transverse Cracks , 1994 .

[4] J. E. Bailey,et al. Constrained cracking in glass fibre-reinforced epoxy cross-ply laminates , 1978 .

[5] John A. Nairn,et al. The Strain Energy Release Rate of Composite Microcracking: A Variational Approach , 1989 .

[6] Zvi Hashin,et al. Analysis of cracked laminates: a variational approach , 1985 .

[7] Z. Hashin. Analysis of Orthogonally Cracked Laminates Under Tension , 1987 .

[8] Kenneth Reifsnider,et al. Stiffness-reduction mechanisms in composite laminates , 1982 .

[9] Ramesh Talreja,et al. Damage mechanics of composite materials , 1994 .

[10] L. McCartney. Theory of stress transfer in a 0°—90°—0° cross-ply laminate containing a parallel array of transverse cracks , 1992 .

[11] Asd Wang,et al. Fracture Mechanics of Sublaminate Cracks in Composite Materials , 1984 .