๐”– Bobbio Scriptorium
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Fracture of adhesive joints

โœ Scribed by S. S. Wang; F. J. McGarry; J. F. Mandell

Publisher
Society for Plastic Engineers
Year
1981
Tongue
English
Weight
430 KB
Volume
2
Category
Article
ISSN
0272-8397

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โœฆ Synopsis

Abstract

This paper presents some of the important results obtained from a series of studies on cohesive fracture in adhesively bonded joints. Due to the complex nature of the adhesive joint fracture, an accurate and efficient numerical method particularly suitable for the present problem has been developed, based on a hybridโ€stress finite element formulation. Fracture characteristics in adhesively bonded joints are described in terms of local crackโ€tip deformation and stress fields in the polymeric adhesive layer. Effects of material properties, joint geometry, and bondโ€line thickness on the crack behavior are studied for classical lapโ€shear and currently used doubleโ€cantileverโ€beam joints. Of particular interest are the crackโ€tip stress intensities in the adhesive layer; their values are obtained for several cases of practical importance.

๐Ÿ“œ SIMILAR VOLUMES

Fracture mechanics of adhesive joints
Fracture mechanics of adhesive joints
โœ G. M. Spinks; A. Noakes; B. J. Egan; N. A. Isles ๐Ÿ“‚ Article ๐Ÿ“… 1993 ๐Ÿ› Springer ๐ŸŒ English โš– 247 KB
Mixed mode fracture analysis of adhesive
Mixed mode fracture analysis of adhesive lap joints
โœ Gengkai Hu ๐Ÿ“‚ Article ๐Ÿ“… 1995 ๐Ÿ› Elsevier Science โš– 392 KB

A Cherepanov-Rice J integral is derived for Goland-Reissner type joints. It is shown that the resulting J integral is path independent under the assumption of small rotation of adherents and thin adhesive thickness. It represents the product of strain energy density at the edge of the joint and adhe