The effect of fibers-matrix interaction on the composite materials elongation

Failure process in composite materials is the basis of various actual researches. It study is the almost treated with fiber bundle model (FBM), in the framework of local load sharing rule (LLS), were the breakdown mechanisms is controlled by different parameters. Almost tentative investigates only f...

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Bibliographic Details
Published in:IOP conference series. Materials Science and Engineering 2020-11, Vol.948 (1), p.12032
Main Authors: Tanasehte, M, Hader, A, Sbiaai, H, Achik, I, Boughaleb, Y
Format: Article
Language:English
Subjects:
Composite materials
Deceleration
elastic energy
Elongation
Failure
Fiber bundle model
Fibers
Load sharing
matrix-fibers interaction
Parameters
Substations
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Summary:Failure process in composite materials is the basis of various actual researches. It study is the almost treated with fiber bundle model (FBM), in the framework of local load sharing rule (LLS), were the breakdown mechanisms is controlled by different parameters. Almost tentative investigates only fiber failure process and neglects the effect of the matrix, as a second crucial component of composite. Effectively, quantification of fibers-matrix interactions is not generally clear. Furthermore, the diversity of composite intrinsic proprieties complicates this quantification. The originality of our investigations is to quantify all interactions between fibers and matrix in a single parameter. Likewise, this latter gives us a different results than the ones obtained with FBM where the interaction amplitude is neglected. Moreover, interaction decelerates the failure process; it subdivides the avalanche phenomena on two consecutive regimes separated by delaying duration. These results are more similar to the ones obtained regular fibers substations. Therefore any fiber have its own elongation, the mean fiber elongation produces an elastic energy. The temporal variation of these latter presents two extremum separated by time duration; at this separated period, the material self-rearranging. These results are more similar to the ones obtained by the regular fibers substitution process.
ISSN:1757-8981
1757-899X
DOI:10.1088/1757-899X/948/1/012032