Modelling damage due to low speed impact in laminated composites of toughened interfaces through 'ex situ' technique
Modelling damage due to low speed impact in laminated composites of toughened interfaces through 'ex situ' technique
Laminated composites are widely employed in the aerospace industry for their high performances. One of the major drawbacks in using these materials for aerospace applications has been their weaknesses in resisting lateral impacts which tend to induce damage in laminates. Delamination is one of the major forms of damage which compromise the integrity of the laminates as load carrying structures. To tackle this issue, the 'ex-situ' toughening technique, was developed by Yi et al [1,3] in Beijing Institute of Aeronautical Materials (BIAM), China and has since been applied successfully to processing laminated composites made from prepregs and later to those made using RTM. Experimental evidences have demonstrated the toughening effects of such technique. Effects of toughening are reflected mainly through critical energy release rates for mode I and II, GIc and GIIc, which to a large extent dictate the impact damage resistance of the laminates. These properties were obtained through standard tests, namely, double cantilever beam (DCB) and end-notched flexure (ENF) delamination tests for mode I and II, respectively. Three types of laminates made through RTM were used, neat BMI (non-toughened) as the control and 'ex-situ' RTM-16.8% and 20.2% PAEK, respectively, in the experiments conducted by BIAM. This paper is to present the capability of theoretical modelling the delamination damage of 'ex-situ' toughened laminates due to lateral impact using finite elements with appropriate treatments. Models representing the DCB and ENF specimens were generated to reproduce the results of these tests, and the predicted critical energy release rates is shown to agree well with the input values. The numerical modelling for these cases facilitated the development of FE model simulating the standard mixed mode tests, the prediction for which are also given in the paper.
'Ex-situ' toughening, Cohesive elements, Delamination
Li, Dafei
3adf5f18-f3bf-4a16-926d-feffba4a1bef
Sitnikova, Elena
e0c2f901-24fe-43d0-88e8-76f415675104
Li, Shuguang
f99c53b3-e42e-456f-97df-4c4e06de4a40
Yi, Xiaosu
944e79ff-4c49-4e3e-aca5-b8d0dcb6de2d
19 July 2015
Li, Dafei
3adf5f18-f3bf-4a16-926d-feffba4a1bef
Sitnikova, Elena
e0c2f901-24fe-43d0-88e8-76f415675104
Li, Shuguang
f99c53b3-e42e-456f-97df-4c4e06de4a40
Yi, Xiaosu
944e79ff-4c49-4e3e-aca5-b8d0dcb6de2d
Li, Dafei, Sitnikova, Elena, Li, Shuguang and Yi, Xiaosu
(2015)
Modelling damage due to low speed impact in laminated composites of toughened interfaces through 'ex situ' technique.
20th International Conference on Composite Materials, ICCM 2015, , Copenhagen, Denmark.
19 - 24 Jul 2015.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Laminated composites are widely employed in the aerospace industry for their high performances. One of the major drawbacks in using these materials for aerospace applications has been their weaknesses in resisting lateral impacts which tend to induce damage in laminates. Delamination is one of the major forms of damage which compromise the integrity of the laminates as load carrying structures. To tackle this issue, the 'ex-situ' toughening technique, was developed by Yi et al [1,3] in Beijing Institute of Aeronautical Materials (BIAM), China and has since been applied successfully to processing laminated composites made from prepregs and later to those made using RTM. Experimental evidences have demonstrated the toughening effects of such technique. Effects of toughening are reflected mainly through critical energy release rates for mode I and II, GIc and GIIc, which to a large extent dictate the impact damage resistance of the laminates. These properties were obtained through standard tests, namely, double cantilever beam (DCB) and end-notched flexure (ENF) delamination tests for mode I and II, respectively. Three types of laminates made through RTM were used, neat BMI (non-toughened) as the control and 'ex-situ' RTM-16.8% and 20.2% PAEK, respectively, in the experiments conducted by BIAM. This paper is to present the capability of theoretical modelling the delamination damage of 'ex-situ' toughened laminates due to lateral impact using finite elements with appropriate treatments. Models representing the DCB and ENF specimens were generated to reproduce the results of these tests, and the predicted critical energy release rates is shown to agree well with the input values. The numerical modelling for these cases facilitated the development of FE model simulating the standard mixed mode tests, the prediction for which are also given in the paper.
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Published date: 19 July 2015
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© 2015 International Committee on Composite Materials. All rights reserved.
Venue - Dates:
20th International Conference on Composite Materials, ICCM 2015, , Copenhagen, Denmark, 2015-07-19 - 2015-07-24
Keywords:
'Ex-situ' toughening, Cohesive elements, Delamination
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Local EPrints ID: 497642
URI: http://eprints.soton.ac.uk/id/eprint/497642
PURE UUID: d83d2376-ddd0-402e-930e-eac2da09b186
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Date deposited: 28 Jan 2025 18:13
Last modified: 29 Jan 2025 03:16
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Contributors
Author:
Dafei Li
Author:
Elena Sitnikova
Author:
Shuguang Li
Author:
Xiaosu Yi
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