A parametric study of inclusion interaction in particulate- and fibre-reinforced materials using the boundary element technique

The purpose of the present work is to analyse the effect of inclusion interaction within a composite material using the boundary element (BE) technique. The stress distributions have been examined as a function of the inter-fibre/particle separation distance, interfacial conditions and the relative...

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Bibliographic Details
Published in:Journal of strain analysis for engineering design 2002-01, Vol.37 (1), p.47-58
Main Authors: Knight, M. G, de Lacerda, L. A, Henshall, J. L, Wrobel, L. C
Format: Article
Language:English
Subjects:
Bonding
Boundary element method
Boundary-integral methods
Composite materials
Computational techniques
Computer simulation
Crack initiation
Exact sciences and technology
Fiber reinforced materials
Finite element method
Fracture strength
Fundamental areas of phenomenology (including applications)
Inclusions
Mathematical analysis
Mathematical methods in physics
Mathematical models
Mechanical contact (friction...)
Microcracks
Modulus of elasticity
Parametric statistics
Physics
Solid mechanics
Stresses
Structural and continuum mechanics
Tribology and mechanical contacts
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Summary:The purpose of the present work is to analyse the effect of inclusion interaction within a composite material using the boundary element (BE) technique. The stress distributions have been examined as a function of the inter-fibre/particle separation distance, interfacial conditions and the relative moduli and size of neighbouring inclusions. In particular, the relative size of interacting inclusions detrimentally affects the localized stress concentrations (fully bonded), and in certain circumstances can result in a complete loss of contact within 'shielded’ inclusions (non-bonded). Furthermore, the analysis of inclusions with differing Young's moduli shows that, if one of them has a modulus greater than that of the matrix, and the other a modulus lower than that of the matrix, then there is a significant reduction in the local stress concentrations. Hence, microcracks, which often nucleate in and around second-phase materials, would have a lower probability of initiation, which in turn could lead to an improvement in the fracture strength of the bulk material. For verification, the results have been found to correlate well with the present authors' finite element (FE) simulations and, where possible, comparison of the results with analytical models shows good agreement.
ISSN:0309-3247
2041-3130
DOI:10.1243/0309324021514826