High performance quasi-isotropic thin-ply carbon/glass hybrid composites with pseudo-ductile behaviour in all fibre orientations

This study exploits the potential of thin-ply carbon/glass hybrid laminates to generate high performance Quasi-Isotropic (QI) composite plates that show pseudo-ductility in all fibre orientations under tensile loading, overcoming the inherent brittleness of conventional composites. Two types of QI l...

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Published in:Composites science and technology 2017-11, Vol.152, p.101-110
Main Authors: Fotouhi, Mohamad, Jalalvand, Meisam, Wisnom, Michael R.
Format: Article
Language:English
Subjects:
Brittleness
Carbon fiber reinforced plastics
Carbon fibers
Carbon fibres
Composite structures
Delamination
Ductility
Failure
Fiber orientation
Fragmentation
Glass fibres
Hybrid composites
Laminates
Layers
Plates (structural members)
Stacking sequence (composite materials)
Stiffness
Strain
Thin-ply
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cited_by cdi_FETCH-LOGICAL-c400t-5c2ee19454bb730833fba2b9d43512b048236ed6e3105e2fd228fb38e69a0fed3
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container_title Composites science and technology
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creator Fotouhi, Mohamad
Jalalvand, Meisam
Wisnom, Michael R.
description This study exploits the potential of thin-ply carbon/glass hybrid laminates to generate high performance Quasi-Isotropic (QI) composite plates that show pseudo-ductility in all fibre orientations under tensile loading, overcoming the inherent brittleness of conventional composites. Two types of QI lay-ups with 45° and 60° intervals, i.e. [45/90/-45/0] and [60/-60/0], were used to fabricate novel architectures of a QI T300-carbon laminate sandwiched between the two halves of a QI S-glass laminate. The fabricated plates were then loaded in all their fibre orientations. The laminates were designed by choosing an appropriate ratio of the carbon thickness to the laminate thickness using a robust analytical damage mode map. The experimental results verified the analytical predictions and showed a desirable pseudo-ductile failure in all the fibre orientations. Microscope images taken through the laminates thickness showed fragmentations (fibre fractures in the carbon layer) appearing only in the 0° carbon plies. A hybrid effect was observed, with an increase in strain and stress to failure of the carbon fibres, which was found to be dependent on the stiffness of the plies separating the 0° carbon plies and the plies adjacent to the 0° carbon plies. Altering the stacking sequence changes the stiffness of the separator and adjacent plies, therefore, leads to changes in the pseudo-ductile characteristics such as the initiation and final failure strains.
doi_str_mv 10.1016/j.compscitech.2017.08.024
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subjects Brittleness
Carbon fiber reinforced plastics
Carbon fibers
Carbon fibres
Composite structures
Delamination
Ductility
Failure
Fiber orientation
Fragmentation
Glass fibres
Hybrid composites
Laminates
Layers
Plates (structural members)
Stacking sequence (composite materials)
Stiffness
Strain
Thin-ply
title High performance quasi-isotropic thin-ply carbon/glass hybrid composites with pseudo-ductile behaviour in all fibre orientations
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