Characterisation of nonlinear response of 3D layer-to-layer angle interlock woven composites under warp tension
Characterisation of nonlinear response of 3D layer-to-layer angle interlock woven composites under warp tension
3D woven composites, known for their exceptional structural integrity, are highly attractive for aeronautical applications, particularly in critical components such as aero-engine fan blades. Despite their promising potential, a comprehensive understanding of their mechanical behaviour remains essential for optimised design and application. Significant nonlinear behaviour well before the ultimate failure of 3D woven composites with a layer-to-layer angle interlock fibre architecture under warp tension has been observed in experiments. Although the same experimental observation for this type of material had been reported in the literature previously, the fundamental mechanisms of nonlinearity were not fully studied. In this work, the contributing factors that lead to this severe nonlinearity are investigated and their effects on modelling the response of 3D woven composites are characterised. An appropriately defined mesoscale single-layer unit cell is adopted for this purpose to simplify the finite element modelling, along with a justification performed. Fibre tow/matrix debonding, damage in neat matrix and nonlinear shear in fibre tows have been identified as the most significant sources of nonlinearity and their modelling strategies are discussed. In comparison with the experiments, the results demonstrate the specific effects of each identified factor on the nonlinear behaviour of the material. As modelling of 3D woven composites is computationally costly, this study would provide important insights into the choice of appropriate modelling strategies for 3D woven composites in a design process.
YAN, Shibo
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LI, Junru
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XU, Mingming
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SITNIKOVA, Elena
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KONG, Weiyi
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HU, Shoufeng
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LI, Shuguang
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YAN, Shibo
b7d82b79-caf1-4e7c-90bd-1a8a70aef479
LI, Junru
11c2bd65-bda3-4fd0-b6b0-e3284ea075e5
XU, Mingming
1c48e267-bacb-4777-9bb8-f2f249a6c83f
SITNIKOVA, Elena
e0c2f901-24fe-43d0-88e8-76f415675104
KONG, Weiyi
2a9173e1-82fd-4ab7-9782-3e256baecb39
HU, Shoufeng
f7c4b96f-ae29-4fff-a14c-c11cadd25c54
LI, Shuguang
cfb6a3f7-8167-4235-b891-ea06c8cfba92
YAN, Shibo, LI, Junru, XU, Mingming, SITNIKOVA, Elena, KONG, Weiyi, HU, Shoufeng and LI, Shuguang
(2025)
Characterisation of nonlinear response of 3D layer-to-layer angle interlock woven composites under warp tension.
Chinese Journal of Aeronautics, [103905].
(doi:10.1016/j.cja.2025.103905).
Abstract
3D woven composites, known for their exceptional structural integrity, are highly attractive for aeronautical applications, particularly in critical components such as aero-engine fan blades. Despite their promising potential, a comprehensive understanding of their mechanical behaviour remains essential for optimised design and application. Significant nonlinear behaviour well before the ultimate failure of 3D woven composites with a layer-to-layer angle interlock fibre architecture under warp tension has been observed in experiments. Although the same experimental observation for this type of material had been reported in the literature previously, the fundamental mechanisms of nonlinearity were not fully studied. In this work, the contributing factors that lead to this severe nonlinearity are investigated and their effects on modelling the response of 3D woven composites are characterised. An appropriately defined mesoscale single-layer unit cell is adopted for this purpose to simplify the finite element modelling, along with a justification performed. Fibre tow/matrix debonding, damage in neat matrix and nonlinear shear in fibre tows have been identified as the most significant sources of nonlinearity and their modelling strategies are discussed. In comparison with the experiments, the results demonstrate the specific effects of each identified factor on the nonlinear behaviour of the material. As modelling of 3D woven composites is computationally costly, this study would provide important insights into the choice of appropriate modelling strategies for 3D woven composites in a design process.
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Accepted/In Press date: 24 October 2025
e-pub ahead of print date: 29 October 2025
Identifiers
Local EPrints ID: 507498
URI: http://eprints.soton.ac.uk/id/eprint/507498
ISSN: 1000-9361
PURE UUID: fe8eded8-6adf-4c03-ac8e-5aba7c1778cf
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Date deposited: 10 Dec 2025 17:51
Last modified: 11 Dec 2025 03:14
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Author:
Shibo YAN
Author:
Junru LI
Author:
Mingming XU
Author:
Elena SITNIKOVA
Author:
Weiyi KONG
Author:
Shoufeng HU
Author:
Shuguang LI
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