Delamination and Buckling in 3D Composites

Cox, B. N.

doi:10.1177/002199839402801203

Cited by 40 publications

(18 citation statements)

References 2 publications

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“…The microstructure-property relationship at the interphase region is critical to a successful composite and for that, it is essential to understand adhesion between fiber and matrix. It is accepted that the interlaminar fracture toughness of a laminated composite is determined principally by the properties of the matrix material including its ultimate strain, ability to develop plastic deformation and fracture toughness [3,22,25]. The fiber-matrix interphase properties are not a decisive factor in determining the interlaminar fracture toughness in composites [23,25].…”

Section: Interphasementioning

confidence: 99%

“…These composites, still being laminated materials, can experience premature failure. Interlaminar stresses caused by cracks or defects can arise in these composites and their propagation along the intra-layer planes or plies cannot be arrested due to the lack of fibers in the transverse direction to the laminate [1][2][3][20][21][22]. This cracking process between plies is called delamination and represents a fundamental weakness of laminated composite materials [1][2][3]23].…”

Section: Introductionmentioning

confidence: 99%

“…This constitutes an attempt to mitigate delamination at the macroscopic or continuum level by reducing the buckling load or bridging the cracks. The most efficient reinforcement cases include: i. Three-dimensional (3D) woven fabrics that include a third set of tows with components in the z-direction besides those in the warp and fill directions [22,24,25]. ii.…”

Section: Introductionmentioning

confidence: 99%

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Novel carbon nanotube array-reinforced laminated composite materials with higher interlaminar elastic properties

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Song

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Section: Interphasementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Novel carbon nanotube array-reinforced laminated composite materials with higher interlaminar elastic properties

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et al. 2008

Composites Science and Technology

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“…It is, therefore, required to take into account the effects of bridging. Cox [1] researched initial buckling of one-dimensional delamination with linear bridging and found many useful results, but the results simulated by the classical beam theory appear not to be suf®cient for engineering applications, [8,9]. In this paper we extend Cox's work to a circular thin-®lm delamination constrained by linear restoring forces.…”

Section: Introductionmentioning

confidence: 95%

“…In recent years, the ®rst aspect has been widely researched, and many useful results obtained have greatly contributed to engineering design, [2±7]. The second aspect however, has not caused much attention so far, [1,8,9]. It is well known that the through-thickness tows in 3D composites can bridge the delamination cracks and prevent buckling of the adjacent delaminated layers; therefore, while the ®bers do not eliminate delaminations, they do minimize the loss of strength under subsequent compression.…”

mentioning

confidence: 99%

The effects of bridging in a 3D composite on buckling, postbuckling and growth of delamination

Huang

et al. 1999

Archive of Applied Mechanics (Ingenieur Archiv)

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Buckling and postbuckling solutions to circular delamination constrained by transversal restoring forces, which occur extensively in stitched or woven composites with three-dimensional (3D) reinforcement, are obtained by using von Karman's geometrically nonlinear thin plate theory by means of Taylor's series expansion. The through-thickness tows are assumed to provide continuous and linear restoring tractions, opposing the de¯ection of the annular delaminated region adjacent to a penny-shaped crack. When the end of the delaminated layer is clamped, and the de¯ection is permitted in the positive direction of the z-axis only, there exists a characteristic delamination radius a Ã for initial buckling. In the case that the initial delamination radius a 0 exceeds a Ã , it will consist of waves whose sizes decrease gradually, as they are apart from the delamination center with larger distances, and will usually not span the whole crack region. Therefore, buckling pro®les can be divided into two types:(1) lacking contact phenomena between the delaminated layer and the base plate; (2) having contact surfaces inside the delamination region. In this paper, growth laws of buckling, postbuckling and growth of delamination at lacking contact surface are discussed. The corresponding stability of the delamination growth under ®xed boundary load is studied, and the dependence of stable scope upon the fracture toughness of the composite and the elastic constant of bridging ®ber is summarized. It follows from the analysis that bridging can increase the load-bearing capacity of composite structure, improve its mechanical performances and restrain the growth of delamination. IntroductionOwing to their low weight and high strength, composite materials have been widely used in automobile, construction, and weight-sensitive aeronautical and astronautical industries [1±7]. However, composites delaminate on occasion due to imperfections in production technology and under high impact. This phenomenon generally causes unexpected degradation of structure strength. In order to exert larger potential of composite materials, two tasks must be accomplished ®rst: the analysis of the nature of buckling, postbuckling and growth of delamination, and the design of some effective methods for the repair of the composite structure by increasing its load-bearing capacity and decreasing its susceptibility to delaminations. In recent years, the ®rst aspect has been widely researched, and many useful results obtained have greatly contributed to engineering design, [2±7]. The second aspect however, has not caused much attention so far, [1,8,9]. It is well known that the through-thickness tows in 3D composites can bridge the delamination cracks and prevent buckling of the adjacent delaminated layers; therefore, while the ®bers do not eliminate delaminations, they do minimize the loss of strength under subsequent compression. It is, therefore, required to take into account the effects of bridging. Cox [1] researched initial buckling of one-dimensional delamin...

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3 D Textile Composites: Mechanical Properties

Pankow

Waas

2012

Wiley Encyclopedia of Composites

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This article discusses many different aspects of 3D woven textile composites. The basics of 3D weaving are introduced along with the fabrication techniques and a discussion of the general types of architectures. Mechanical properties are then examined showing the benefits and drawbacks of the architecture systems. Various different modeling techniques are evaluated including computational techniques that capture architecture‐dependent mechanisms. Finally, the response of 3D woven material is examined under high rates of loading, and its blast and ballistic resistance is discussed.

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Delamination and Buckling in 3D Composites

Cited by 40 publications

References 2 publications

Novel carbon nanotube array-reinforced laminated composite materials with higher interlaminar elastic properties

Novel carbon nanotube array-reinforced laminated composite materials with higher interlaminar elastic properties

The effects of bridging in a 3D composite on buckling, postbuckling and growth of delamination

3 D Textile Composites: Mechanical Properties

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