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Abstract

Considering the influence of bridge fibers, a representative volume element (RVE) with damaged regions of vanishing thickness is developed to study for estimation of laminates with transverse matrix cracks. For the open and closed cracks, the tensile force, the compressive force and the shear force are mainly studied by the stress-based variational approach with the pending partition loads at the statically indeterminate boundary, with considering not only three cases of the ideal transverse cracks, the smooth plane-surface open crack, the smooth plane-surface closed crack and the perfect meshing open crack, but also two cases of the non-ideal transverse cracks, the open cracks and closed cracks with the resistance resisting the relative sliding of crack surfaces. The expressions of the stress components in the RVE are obtained by means of assumption of the function of inter-laminar shear stresses. The governing equations are derived from the variational analysis based on the principle of minimum complementary energy. Both the effective mechanical properties and the distributions stresses of the damaged laminates with the ideal transverse cracks and those of the laminates with the non-ideal transverse cracks are estimated on the basis of the analysis of deformation on surface of the RVE.

Keywords

Transverse matrix crack smooth plane-surface crack perfect meshing crack angle-ply laminate stiffness reduction variational analysis

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References

Reifsnider

Schulte

, and Duke

JC.

Long-term fatigue behavior of composite materials. In: O’Brien

(ed.) Long-term behavior of composites. ASTM STP 813. Philadelphia, PA: American Society for Testing and Materials, 1983, pp.136–159.

Hoover

Kujawski

Ellyin

Transverse crack of symmetric and unsymmetric glass-fiber/epoxy-resin laminates. Compos Sci Technol 1997; 57: 1513–1526.

Chakrabarti

Sheikh

AH.

Vibration and buckling of sandwich laminates having interfacial imperfections. J Sandwich Struct Mater 2009; 11: 313–328.

Gune

Kayran

Non-linear progressive failure analysis of open-hole composite laminates under combined loading. J Sandwich Struct Mater 2013; 15: 309–339.

Katerelos

McCartney

Galiotis

Local strain re-distribution and stiffness degradation in cross-ply polymer composites under tension. Acta Mater 2005; 53: 3335–3343.

Amara

Tounsi

Benzair

Transverse cracking and elastic properties reduction in hygrothermal aged cross-ply laminates. Mater Sci Eng A 2005; 396: 369–375.

Ogihara

Takeda

Interaction between transverse cracks and delamination during damage progress in CFRP cross-ply laminates. Compos Sci Technol 1995; 54: 395–404.

Joffe

Varna

AJ.

Analytical modeling reduction in symmetric and balanced laminates due to cracks in 90° layers. Compos Sci Technol 1999; 59: 1641–1652.

Kashtalyan

Soutis

Stiffness degradation in cross-ply laminates damaged by transverse cracking and splitting. Compos Part A 2000; 31: 335–351.

10.

Hashin

Analysis of orthogonally cracked laminates under tension. J Appl Mech 1987; 54: 872879.

11.

Vinogradov

Hashin

Probabilistic energy based model for prediction of transverse cracking in cross-ply laminates. Int J Solids Struct 2005; 42: 365–392.

12.

Huang

Nie

Chan

CK.

An exact solution for stresses in cracked composite laminates and evaluation of the characteristic damage state. Compos Part B 2011; 42: 1008–1014.

13.

Zhang

Fan

Soutis

Analysis of multiple matrix cracking in [±θ_m/90_n]_s composite laminates. Composites 1992; 23: 291–298.

14.

Kashtalyan

Soutis

Analysis of local delaminations in composite laminates with angle-ply matrix cracks. Int J Solids Struct 2002; 39: 1515–1537.

15.

Kashtalyan

Soutis

Analysis of composite laminates with intra- and interlaminar damage. Prog Aerosp Sci 2005; 41: 152–173.

16.

Tounsi

Amara

Stiffness degradation in hygrothermal aged cross-ply laminate with transverse cracks. AIAA J 2005; 43: 1836–1843.

17.

Zhang

Minnetyan

Variational analysis of transverse cracking and local delamination in [θ_m/90_n]_s laminates. Int J Solids Struct 2006; 43: 7061–7081.

18.

Hafeez

Variation-based cracked laminate analysis revisited and fundamentally extended. Int J Solids Struct 2009; 46: 3505–3515.

19.

Vinogradov

Hashin

Variational analysis of cracked angle-ply laminates. Compos Sci Technol 2010; 70: 638–646.

20.

Hajikazemi

Sadr

Hosseini-Toudeshky

, et al. Thermo-elastic constants of cracked symmetric laminates: a refined variational approach. Int J Mech Sci 2014; 89: 47–57.

21.

Huang

Zhou

, et al. Variational analysis for angle-ply laminates with matrix cracks. Int J Solids Struct 2014; 51: 3669–3678.

22.

Huang

XQ.

Stress distributions and mechanical properties of laminates [θ_m/90_n]_S with closed and open cracks in shear loading. Int J Solids Struct 2017; 118–119: 97–108.

23.

Nuismer

Tan

SC.

Constitutive relations of a cracked composite Lamina. J Compos Mater 1988; 22: 306–321.

24.

Tan

Nuismer

RJ.

A theory for progressive matrix cracking in composite laminates. J Compos Mater 1989; 23: 1029–1047.

25.

Lundmark

Varna

Crack face sliding effect on stiffness of laminates with ply cracks. Compos Sci Technol 2006; 66: 1444–1454.

26.

Hashin

The spherical inclusion with imperfact interface. J Appl Mech 1991; 58: 444–449.

27.

Hashin

Thin interphase/imperfect interface in elasticity with application to coated fiber composites. J Mech Phys Solids 2002; 50: 2509–2537.

28.

Würkner

Berger

Gabbert

Numerical study of effective elastic properties of fiber reinforced composites with rhombic cell arrangements and imperfect interface. Int J Eng Sci 2013; 63: 1–9.

29.

Würkner

Berger

Gabbert

Numerical investigations of effective properties of fiber reinforced composites with parallelogram arrangements and imperfect interface. Compos Struct 2014; 116: 388–394.

30.

Huang

Liew

KM.

A sensitive interval of imperfect interface parameters based on the analysis of general solution for anisotropic matrix containing an elliptic inhomogeneity. Int J Solids Struct 2015; 73-74: 67–77.

31.

HY.

A new dislocation-like model for imperfect interfaces and their effect on load transfer. Compos Part A 1998; 29A: 1057–1062.

32.

Huang

Nie

Chan

CK.

Solution of the plane problem for anisotropic media containing an elliptic inhomogeneity with dislocation interface. Acta Mech 2013; 224: 2863–2880.

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Parameter analysis of damaged region for laminates with matrix defects

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