Gaining mechanistic insight into key factors contributing to crack path transition in particle toughened carbon fibre reinforced polymer composites using 3D X-ray computed tomography
Gaining mechanistic insight into key factors contributing to crack path transition in particle toughened carbon fibre reinforced polymer composites using 3D X-ray computed tomography
Composite materials are increasingly used to help in reducing the carbon footprint of transportation and upscaling renewable energy infrastructure that provides clean energy for future cities. However, the inherent susceptibility of carbon fibre reinforced polymers to impact damage results in knock-down in design and is linked to the micro-mechanistic response of the material to damage. In situ experimental and high-resolution imaging techniques using X-ray computed tomography (X-ray CT) have been used to gain a mechanistic understanding of the key factors controlling crack path — and hence macro-scale toughness within a composite. Multiscale Synchrotron Radiation Computed Tomography (SRCT) and lab-based micro-focus X-ray CT are used to investigate different material systems toughness response from standard Double Cantilever Beam tests. The crack transition to the weaker ply region of the composite is identified as a controlling factor across a scale of mm’s, and ‘trigger’ regions are reported on and investigated. The ‘trigger’ regions were identified as gaps in the ply adjacent to the interlayer. This work feeds directly into delamination growth predictions, a better understanding of material response, and enabling informed manufacture and design, allowing for reduced material usage, longer life and more sustainable vehicles and infrastructure.
61-66
Ball, Keiran
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Lee, Yeajin
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Furtado, Carolina
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Arteiro, Albertino
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Patel, Palak
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Majkut, Marta
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Helfen, Lukas
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Wardle, Brian L.
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Mavrogordato, Mark
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Sinclair, Ian
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Spearing, Mark
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25 June 2022
Ball, Keiran
b9f5b1bd-02b6-4c82-86dc-335a08738be6
Lee, Yeajin
68771a14-4343-4e99-9837-832b10b6b5e7
Furtado, Carolina
c76c5f54-d539-42f7-8d2d-55fd32ea43e7
Arteiro, Albertino
dcfdf34b-22d8-429d-8a17-15ee46ef7eeb
Patel, Palak
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Majkut, Marta
e4af7a2b-3f82-4d9a-aff9-6a8c0fb36fe9
Helfen, Lukas
29f093fe-3507-407b-a539-48fa3439a549
Wardle, Brian L.
6c973fee-f02f-4f3c-8d45-a0e80335fa54
Mavrogordato, Mark
faedf03d-e357-4ec3-818e-e5ff5368fdf0
Sinclair, Ian
6005f6c1-f478-434e-a52d-d310c18ade0d
Spearing, Mark
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Ball, Keiran, Lee, Yeajin, Furtado, Carolina, Arteiro, Albertino, Patel, Palak, Majkut, Marta, Helfen, Lukas, Wardle, Brian L., Mavrogordato, Mark, Sinclair, Ian and Spearing, Mark
(2022)
Gaining mechanistic insight into key factors contributing to crack path transition in particle toughened carbon fibre reinforced polymer composites using 3D X-ray computed tomography.
Energy Reports, 8 (Supplement 11), .
(doi:10.1016/j.egyr.2022.05.041).
Abstract
Composite materials are increasingly used to help in reducing the carbon footprint of transportation and upscaling renewable energy infrastructure that provides clean energy for future cities. However, the inherent susceptibility of carbon fibre reinforced polymers to impact damage results in knock-down in design and is linked to the micro-mechanistic response of the material to damage. In situ experimental and high-resolution imaging techniques using X-ray computed tomography (X-ray CT) have been used to gain a mechanistic understanding of the key factors controlling crack path — and hence macro-scale toughness within a composite. Multiscale Synchrotron Radiation Computed Tomography (SRCT) and lab-based micro-focus X-ray CT are used to investigate different material systems toughness response from standard Double Cantilever Beam tests. The crack transition to the weaker ply region of the composite is identified as a controlling factor across a scale of mm’s, and ‘trigger’ regions are reported on and investigated. The ‘trigger’ regions were identified as gaps in the ply adjacent to the interlayer. This work feeds directly into delamination growth predictions, a better understanding of material response, and enabling informed manufacture and design, allowing for reduced material usage, longer life and more sustainable vehicles and infrastructure.
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Accepted/In Press date: 13 May 2022
e-pub ahead of print date: 25 June 2022
Published date: 25 June 2022
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Local EPrints ID: 482039
URI: http://eprints.soton.ac.uk/id/eprint/482039
ISSN: 2352-4847
PURE UUID: 92aa8ccf-eeaa-410d-8677-3af37b10334b
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Date deposited: 18 Sep 2023 16:35
Last modified: 18 Mar 2024 02:58
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Author:
Yeajin Lee
Author:
Carolina Furtado
Author:
Albertino Arteiro
Author:
Palak Patel
Author:
Marta Majkut
Author:
Lukas Helfen
Author:
Brian L. Wardle
Author:
Mark Mavrogordato
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