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Experimental Mechanics

Erschienen in:

01.08.2007

A Study of Crack–inclusion Interactions and Matrix–inclusion Debonding Using Moiré Interferometry and Finite Element Method

verfasst von: P. C. Savalia, H. V. Tippur

Erschienen in: Experimental Mechanics | Ausgabe 4/2007

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Abstract

Failure behavior of composite materials in general and particulate composites in particular is intimately linked to interactions between a matrix crack and a second phase inclusion. In this work, surface deformations are optically mapped in the vicinity of a crack–inclusion pair using moiré interferometry. Edge cracked epoxy beams, each with a symmetrically positioned cylindrical glass inclusion ahead of the tip, are used to simulate a compliant matrix crack interacting with a stiff inclusion. Processes involving microelectronic fabrication techniques are developed for creating linear gratings in the crack–inclusion vicinity. The debond evolution between the inclusion–matrix pair is successfully mapped by recording crack opening displacements under quasi-static loading conditions. The surface deformations are analyzed to study evolution of strain fields due to crack–inclusion interactions. A numerical model based on experimental observations is also developed to simulate debonding of the inclusion from the matrix. An element stiffness deactivation method in conjunction with critical radial stress criterion is successfully demonstrated using finite element method. The proposed methodology is shown to capture the experimentally observed debonding process well.

Vorheriger Artikel Full 3D Measurement of Strain Field by Scattered Light for Analysis of Structures

Nächster Artikel Coupled Strain and Fresnel Response of Photoelastic Coatings at Oblique Incidence

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Epoxy used throughout this work is Epo-Thin™ (Product no. 20-1840, 1842, 100 parts resin: 39 parts hardner) from Beuhler Inc., Pennsylvania.

Silicone rubber used is Platsil 73-60 RTV Silicone Rubber manufactured by Polytek Inc., Pennsylvania.

It should be noted that cohesive element formulations [24] have become popular in recent years for numerically simulating formation of new surfaces in materials. Several investigators have developed and/or adopted this approach for interfacial failure simulations under static and dynamic loading conditions [25, 26]. If one were to utilize the cohesive element approach, however, interfacial fracture parameters such as fracture energy and critical normal separation distance [27] for the inclusion-matrix system would be necessary. This would involve additional experimentation, beyond the scope of the current work.

A convergence study was carried out to examine the effect of bond layer element size on β value that produced good match with experimental results (not shown here for brevity).

Here, no quantitative agreement in the immediate vicinity of the inclusion is claimed since the displacement field asymmetry is due to one fixed and one frictionless roller support conditions used in the numerical simulation, unlike experimental simulations where both supports were rollers with finite friction.

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Titel: A Study of Crack–inclusion Interactions and Matrix–inclusion Debonding Using Moiré Interferometry and Finite Element Method
verfasst von: P. C. Savalia
H. V. Tippur
Publikationsdatum: 01.08.2007
Verlag: Kluwer Academic Publishers-Plenum Publishers
Erschienen in: Experimental Mechanics / Ausgabe 4/2007
Print ISSN: 0014-4851
Elektronische ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-006-9021-9

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