In situ fibre fracture measurement in carbon–epoxy laminates using high resolution computed tomography
In situ fibre fracture measurement in carbon–epoxy laminates using high resolution computed tomography
High resolution Synchrotron Radiation Computed Tomography (SRCT) has been used to capture fibre damage progression in a carbon–epoxy notched [90/0]s laminate loaded to failure. To the authors knowledge this provides the first direct in situ measurement of the accumulation of fibre fractures for a high performance material under structurally relevant load conditions (i.e. fractures within the bulk of an essentially conventional engineering laminate). A high level of confidence is placed in the measurements, as the failure processes are viewed internally at the relevant micromechanical length-scales, as opposed to previous indirect and/or surface-based methods. Whilst fibre breaks are the dominant composite damage mechanism considered in the present work, matrix damage, such as transverse ply cracks, 0? splits and delaminations, were also seen to occur in advance of extensive fibre breaks. At loads where fibre break density levels were significant, splitting and delamination were seen to separate the central 0? ply in the near notch region from the 90? plies. Fibre breaks were initially observed in isolated locations,
consistent with the stochastic nature of fibre strengths. The formation of clusters of broken fibres was observed at higher loads. The largest clusters observed consisted of a group of eleven breaks and a group of fourteen breaks. The large clusters were observed at the highest load, at sites with no prior breaks, indicating they occurred within a relatively narrow load range. No strong correlation was found between the location of matrix damage and fibre breaks. The data achieved has been made available online at www.materialsdatacentre.com for ongoing model development and validation.
carbon fibres, polymer matrix composites, pcm, fracture, stress transfer, synchrotron radiation computed tomography
1471-1477
Scott, A.E.
37356844-61d7-450e-b33e-032c2c41903b
Mavrogordato, Mark N.
f3e0879b-118a-463a-a130-1c890e9ab547
Wright, Peter
c68e1152-f238-4f70-aae1-1c58ab25b97b
Sinclair, I.
6005f6c1-f478-434e-a52d-d310c18ade0d
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
19 August 2011
Scott, A.E.
37356844-61d7-450e-b33e-032c2c41903b
Mavrogordato, Mark N.
f3e0879b-118a-463a-a130-1c890e9ab547
Wright, Peter
c68e1152-f238-4f70-aae1-1c58ab25b97b
Sinclair, I.
6005f6c1-f478-434e-a52d-d310c18ade0d
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Scott, A.E., Mavrogordato, Mark N., Wright, Peter, Sinclair, I. and Spearing, S.M.
(2011)
In situ fibre fracture measurement in carbon–epoxy laminates using high resolution computed tomography.
Composites Science and Technology, 71 (12), .
(doi:10.1016/j.compscitech.2011.06.004).
Abstract
High resolution Synchrotron Radiation Computed Tomography (SRCT) has been used to capture fibre damage progression in a carbon–epoxy notched [90/0]s laminate loaded to failure. To the authors knowledge this provides the first direct in situ measurement of the accumulation of fibre fractures for a high performance material under structurally relevant load conditions (i.e. fractures within the bulk of an essentially conventional engineering laminate). A high level of confidence is placed in the measurements, as the failure processes are viewed internally at the relevant micromechanical length-scales, as opposed to previous indirect and/or surface-based methods. Whilst fibre breaks are the dominant composite damage mechanism considered in the present work, matrix damage, such as transverse ply cracks, 0? splits and delaminations, were also seen to occur in advance of extensive fibre breaks. At loads where fibre break density levels were significant, splitting and delamination were seen to separate the central 0? ply in the near notch region from the 90? plies. Fibre breaks were initially observed in isolated locations,
consistent with the stochastic nature of fibre strengths. The formation of clusters of broken fibres was observed at higher loads. The largest clusters observed consisted of a group of eleven breaks and a group of fourteen breaks. The large clusters were observed at the highest load, at sites with no prior breaks, indicating they occurred within a relatively narrow load range. No strong correlation was found between the location of matrix damage and fibre breaks. The data achieved has been made available online at www.materialsdatacentre.com for ongoing model development and validation.
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Published date: 19 August 2011
Keywords:
carbon fibres, polymer matrix composites, pcm, fracture, stress transfer, synchrotron radiation computed tomography
Organisations:
Engineering Science Unit
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Local EPrints ID: 347381
URI: http://eprints.soton.ac.uk/id/eprint/347381
ISSN: 0266-3538
PURE UUID: 060dd2e6-390a-4152-8d38-74d46318196e
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Date deposited: 04 Feb 2013 14:44
Last modified: 15 Mar 2024 03:18
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Author:
A.E. Scott
Author:
Peter Wright
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