Geometrical optimization of adhesive joints under tensile impact loads using cohesive zone modelling

Industrial developments have led to an increasingly wide implementation of adhesive bonding. Due to the variability of adhesive bonding performance caused by different adhesive properties, it is necessary to validate Finite Element Method (FEM) tools. It is possible to increase the performance of ad...

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Published in:International journal of adhesion and adhesives 2020-03, Vol.97, p.102492, Article 102492
Main Authors: Valente, J.P.A., Campilho, R.D.S.G., Marques, E.A.S., Machado, J.J.M., da Silva, Lucas F.M.
Format: Article
Language:English
Subjects:
Adhesive bonding
Adhesive joint
Adhesive joints
Adhesive strength
Chamfering
Cohesive zone models
Design modifications
Finite element method
Geometrical optimization
Impact loading
Impact loads
Impact strength
Lap joints
Optimization
Parameter modification
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cited_by cdi_FETCH-LOGICAL-c340t-c22232dbe5b236837e29b28378b6621d15ea90a983b8676f7de691c5c35ee5c93
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container_end_page
container_issue
container_start_page 102492
container_title International journal of adhesion and adhesives
container_volume 97
creator Valente, J.P.A.
Campilho, R.D.S.G.
Marques, E.A.S.
Machado, J.J.M.
da Silva, Lucas F.M.
description Industrial developments have led to an increasingly wide implementation of adhesive bonding. Due to the variability of adhesive bonding performance caused by different adhesive properties, it is necessary to validate Finite Element Method (FEM) tools. It is possible to increase the performance of adhesive joints when subjected to impact loadings, without making complex design changes, with the variation of geometric parameters or by modifying the adherends’ geometry. This work compares the results of different geometric changes applied to a single-lap joint (SLJ), when subjected to impact, through Cohesive Zone Models (CZM). Geometry modifications of the SLJ are made by introducing outer and inner chamfers into the adhesives, as well as adding adhesive fillets, to observe the effects of these modifications with different types of adhesives. The combination of the geometric changes that produce the best result is subsequently made. As a result of this work, the CZM technique was validated for the impact strength prediction of adhesive joints and the optimal joint geometries were defined as a function of the adhesive.
doi_str_mv 10.1016/j.ijadhadh.2019.102492
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subjects Adhesive bonding
Adhesive joint
Adhesive joints
Adhesive strength
Chamfering
Cohesive zone models
Design modifications
Finite element method
Geometrical optimization
Impact loading
Impact loads
Impact strength
Lap joints
Optimization
Parameter modification
title Geometrical optimization of adhesive joints under tensile impact loads using cohesive zone modelling
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