Delamination toughening of composite laminates using weakening or toughening interlaminar patches to initiate multiple delaminations

A numerical study

Journal Article (2022)
Author(s)

Guillem Gall Trabal (Aalborg University)

Brian Lau Verndal Bak (Aalborg University)

B. Chen (TU Delft - Aerospace Structures & Computational Mechanics)

Simon Mosbjerg Jensen (Aalborg University)

Esben Lindgaard (Aalborg University)

Research Group
Aerospace Structures & Computational Mechanics
Copyright
© 2022 Guillem Gall Trabal, Brian Lau Verndal Bak, B. Y. Chen, Simon Mosbjerg Jensen, Esben Lindgaard
DOI related publication
https://doi.org/10.1016/j.engfracmech.2022.108730
More Info
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Publication Year
2022
Language
English
Copyright
© 2022 Guillem Gall Trabal, Brian Lau Verndal Bak, B. Y. Chen, Simon Mosbjerg Jensen, Esben Lindgaard
Research Group
Aerospace Structures & Computational Mechanics
Volume number
273
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Abstract

A numerical study on toughening laminated composite materials against delamination by initiating multiple interlaminar cracks is presented. Different configurations of interface toughening and weakening patches, that modify the interface properties at selected locations, are investigated as a way to trigger multiple delaminations. Both interface toughening and weakening patches can be configured to toughen the laminated material by initiating multiple delaminations. The initiation of multiple delaminations and the increase in toughness depend on the interface strengths and toughness of the patches. The main mechanisms behind the initiation of multiple delaminations for both cases are presented. An adaptive refinement method implemented within a Matlab Finite Element Analysis code that models the interfaces of the laminate with cohesive elements is used for the analyses. The adaptive refinement framework allows efficient analysis of multiple delaminations with very fine meshes at the wake of the crack tips. A discussion on the overall performance of the toughening concept, and the main parameters affecting the results, i.e. the length of the interface toughening or weakening patches, the distance of the substrate between the affected interfaces, and the material's mechanical properties, is carried out. The results presented in the paper show that a toughening effect against delamination can be achieved using interface toughening or weakening patches to onset multiple delaminations.