3D damage characterisation and the role of voids in the fatigue of wind turbine blade materials
3D damage characterisation and the role of voids in the fatigue of wind turbine blade materials
The fatigue mechanisms of Glass Fibre Reinforced Polymer (GFRP) used in wind turbine blades were examined using computed tomography (CT). Prior to mechanical testing, as-manufactured [+45/?45/0]3,s glass/epoxy specimens were CT scanned to provide 3-dimensional images of their internal microstructure, including voids. Voids were segmented and extracted, and individual characteristics and volumetric distributions were quantified. The coupons were then fatigue tested in uniaxial loading at R = ?1% to 40% of the nominal tensile failure stress. Some tests were conducted to failure for correlation with the initial void analysis and to establish failure modes. Other tests were stopped at various life fractions and examined using CT to identify key damage mechanisms. These scans revealed transverse matrix cracking in the surface layer, occurring predominantly at free edges. These free-edge cracks then appeared to facilitate edge delamination at the 45/?45° interface. Propagation from sub-critical, surface ply damage to critical, inner ply damage was identified with either a ?45/0° delamination, or a 0° fibre tow failure allowing a crack to propagate into the specimen bulk. Final failure occurred in compression and was characterised by total delamination between all the 45/?45° plies. A quantitative void analysis, taken from the pre-test CT scans, was also performed and compared against the specimens’ fatigue lives. This analysis, to the authors’ knowledge the first of its kind, measured and plotted approximately 10,000 voids within the gauge length of each specimen. The global void measurement parameters and distributions showed no correlation with fatigue life. A local ply-level investigation revealed a significant correlation between the largest void and fatigue life in the region of the laminate associated with the crack propagation from sub-critical to critical damage
337-343
Lambert, J.
dcb3b31b-375d-4c4c-aa1e-d7ade3c79fc0
Chambers, A.R.
74fa9b7e-6362-478e-a038-15f2828c5446
Sinclair, I.
6005f6c1-f478-434e-a52d-d310c18ade0d
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
18 January 2012
Lambert, J.
dcb3b31b-375d-4c4c-aa1e-d7ade3c79fc0
Chambers, A.R.
74fa9b7e-6362-478e-a038-15f2828c5446
Sinclair, I.
6005f6c1-f478-434e-a52d-d310c18ade0d
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Lambert, J., Chambers, A.R., Sinclair, I. and Spearing, S.M.
(2012)
3D damage characterisation and the role of voids in the fatigue of wind turbine blade materials.
Composites Science and Technology, 72 (2), .
(doi:10.1016/j.compscitech.2011.11.023).
Abstract
The fatigue mechanisms of Glass Fibre Reinforced Polymer (GFRP) used in wind turbine blades were examined using computed tomography (CT). Prior to mechanical testing, as-manufactured [+45/?45/0]3,s glass/epoxy specimens were CT scanned to provide 3-dimensional images of their internal microstructure, including voids. Voids were segmented and extracted, and individual characteristics and volumetric distributions were quantified. The coupons were then fatigue tested in uniaxial loading at R = ?1% to 40% of the nominal tensile failure stress. Some tests were conducted to failure for correlation with the initial void analysis and to establish failure modes. Other tests were stopped at various life fractions and examined using CT to identify key damage mechanisms. These scans revealed transverse matrix cracking in the surface layer, occurring predominantly at free edges. These free-edge cracks then appeared to facilitate edge delamination at the 45/?45° interface. Propagation from sub-critical, surface ply damage to critical, inner ply damage was identified with either a ?45/0° delamination, or a 0° fibre tow failure allowing a crack to propagate into the specimen bulk. Final failure occurred in compression and was characterised by total delamination between all the 45/?45° plies. A quantitative void analysis, taken from the pre-test CT scans, was also performed and compared against the specimens’ fatigue lives. This analysis, to the authors’ knowledge the first of its kind, measured and plotted approximately 10,000 voids within the gauge length of each specimen. The global void measurement parameters and distributions showed no correlation with fatigue life. A local ply-level investigation revealed a significant correlation between the largest void and fatigue life in the region of the laminate associated with the crack propagation from sub-critical to critical damage
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Published date: 18 January 2012
Organisations:
Engineering Mats & Surface Engineerg Gp
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Local EPrints ID: 207843
URI: http://eprints.soton.ac.uk/id/eprint/207843
ISSN: 0266-3538
PURE UUID: 84bdce89-03d9-4ed2-895d-6101a1d4ab75
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Date deposited: 13 Jan 2012 14:58
Last modified: 15 Mar 2024 03:18
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Author:
J. Lambert
Author:
A.R. Chambers
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