Fatigue behavior of un-notched and open-hole quasi-isotropic pseudo-ductile thin-ply carbon/glass hybrid laminates
Fatigue behavior of un-notched and open-hole quasi-isotropic pseudo-ductile thin-ply carbon/glass hybrid laminates
This paper investigates the fatigue behavior of un-notched and open-hole Quasi-Isotropic (QI) thinply interlayer hybrids made of thin-ply T300 carbon/epoxy plies sandwiched between standard thickness S-glass/epoxy plies. Samples were initially quasi-statically loaded to failure to determine the critical stress level (pseudo-yield stress (σpy)) at which significant damage starts, i.e. multiple fragmentation of the carbon plies. Quasi-static results showed successful pseudo-ductility and notch-insensitivity before the final failure. The hybrid configurations were loaded at 4 Hz in tension-tension fatigue at different percentages of the σpy below that required to cause significant damage. It was observed that, for the un-notched samples cycled at 80% of the σpy, there is a small stiffness reduction from the early cycles caused by matrix cracking, and there is little stiffness reduction up to 100,000 cycles. By increasing the stress level to 90% of the σpy, there is a gradual stiffness reduction due to the appearance of the fragmentation and delamination which leads to the failure of the un-notched samples after 10,000 cycles. A similar behavior was observed for the open-hole laminates, where initially matrix cracking and subsequently some stiffness reduction were observed for the low stress level (50% of the σpy), with no more stiffness reduction up to 100,000 cycles. However a gradual delamination growth was observed for the high stress level (70% of the σpy), which leads to the final failure after 30,000 cycles. Overall good fatigue performance of pseudo-ductile hybrid composites, with gradual fatigue damage growth was observed, that shows their applicability for industrial applications.
Fatigue, Hybridisation, Open-hole, Pseudo-ductility, Quasi-isotropic
Fotouhi, M.
71cada36-1cae-451d-8e3a-ab040cc7551a
Suwarta, P.
03f07d7c-4d52-42a3-820e-8b8a9be9857f
Jenkin, R.
0910d2da-8719-479e-b423-73c0ac87d514
Jalalvand, M.
21ef0df8-fc7c-4466-a2fc-ee98ed3408a2
Wisnom, M.
655f9d97-0d4c-4654-9b0e-3e5150991e42
16 August 2019
Fotouhi, M.
71cada36-1cae-451d-8e3a-ab040cc7551a
Suwarta, P.
03f07d7c-4d52-42a3-820e-8b8a9be9857f
Jenkin, R.
0910d2da-8719-479e-b423-73c0ac87d514
Jalalvand, M.
21ef0df8-fc7c-4466-a2fc-ee98ed3408a2
Wisnom, M.
655f9d97-0d4c-4654-9b0e-3e5150991e42
Fotouhi, M., Suwarta, P., Jenkin, R., Jalalvand, M. and Wisnom, M.
(2019)
Fatigue behavior of un-notched and open-hole quasi-isotropic pseudo-ductile thin-ply carbon/glass hybrid laminates.
22nd International Conference on Composite Materials, ICCM 2019, , Melbourne, Australia.
11 - 16 Aug 2019.
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Conference or Workshop Item
(Paper)
Abstract
This paper investigates the fatigue behavior of un-notched and open-hole Quasi-Isotropic (QI) thinply interlayer hybrids made of thin-ply T300 carbon/epoxy plies sandwiched between standard thickness S-glass/epoxy plies. Samples were initially quasi-statically loaded to failure to determine the critical stress level (pseudo-yield stress (σpy)) at which significant damage starts, i.e. multiple fragmentation of the carbon plies. Quasi-static results showed successful pseudo-ductility and notch-insensitivity before the final failure. The hybrid configurations were loaded at 4 Hz in tension-tension fatigue at different percentages of the σpy below that required to cause significant damage. It was observed that, for the un-notched samples cycled at 80% of the σpy, there is a small stiffness reduction from the early cycles caused by matrix cracking, and there is little stiffness reduction up to 100,000 cycles. By increasing the stress level to 90% of the σpy, there is a gradual stiffness reduction due to the appearance of the fragmentation and delamination which leads to the failure of the un-notched samples after 10,000 cycles. A similar behavior was observed for the open-hole laminates, where initially matrix cracking and subsequently some stiffness reduction were observed for the low stress level (50% of the σpy), with no more stiffness reduction up to 100,000 cycles. However a gradual delamination growth was observed for the high stress level (70% of the σpy), which leads to the final failure after 30,000 cycles. Overall good fatigue performance of pseudo-ductile hybrid composites, with gradual fatigue damage growth was observed, that shows their applicability for industrial applications.
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Fatique_Behavior_Un-Notched_ICCM22_Full_Paper_253
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Published date: 16 August 2019
Additional Information:
Funding Information:
This work was funded under the UK Engineering and Physical Sciences Research Council (EPSRC) Programme Grant EP/I02946X/1 on High Performance Ductile Composite Technology in collaboration with Imperial College, London. The authors acknowledge Hexcel Corporation for supplying materials for this research. The data necessary to support the conclusions are included in the paper.
Publisher Copyright:
© 2019 International Committee on Composite Materials. All rights reserved.
Venue - Dates:
22nd International Conference on Composite Materials, ICCM 2019, , Melbourne, Australia, 2019-08-11 - 2019-08-16
Keywords:
Fatigue, Hybridisation, Open-hole, Pseudo-ductility, Quasi-isotropic
Identifiers
Local EPrints ID: 477810
URI: http://eprints.soton.ac.uk/id/eprint/477810
PURE UUID: 7aa6599c-1c31-4ac1-bdd0-d6ba43d5bdf3
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Date deposited: 14 Jun 2023 17:01
Last modified: 18 Mar 2024 03:57
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Contributors
Author:
M. Fotouhi
Author:
P. Suwarta
Author:
R. Jenkin
Author:
M. Wisnom
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