Main criteria of sustainable natural fibre for efficient unidirectional biocomposites

This paper investigates biochemical, morphological and mechanical properties of a large range of plant fibres explored with the same methods. Biochemical results clearly exhibit strong differences between gelatinous, i.e. flax and hemp, and xylan type, i.e. jute and kenaf, cell walls. These differen...

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Veröffentlicht in:	Composites. Part A, Applied science and manufacturing Applied science and manufacturing, 2019-09, Vol.124, p.105504, Article 105504
Hauptverfasser:	Bourmaud, Alain, Mérotte, Justin, Siniscalco, David, Le Gall, Maelenn, Gager, Victor, Le Duigou, Antoine, Pierre, Floran, Behlouli, Karim, Arnould, Olivier, Beaugrand, Johnny, Baley, Christophe
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Sprache:	eng
Schlagworte:	Biocomposite Engineering Sciences Mechanical properties Mechanics Mechanics of materials Microstructures Natural fibers
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container_title	Composites. Part A, Applied science and manufacturing
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creator	Bourmaud, Alain Mérotte, Justin Siniscalco, David Le Gall, Maelenn Gager, Victor Le Duigou, Antoine Pierre, Floran Behlouli, Karim Arnould, Olivier Beaugrand, Johnny Baley, Christophe
description	This paper investigates biochemical, morphological and mechanical properties of a large range of plant fibres explored with the same methods. Biochemical results clearly exhibit strong differences between gelatinous, i.e. flax and hemp, and xylan type, i.e. jute and kenaf, cell walls. These differences into parietal composition have an impact on cell wall stiffness, highlighted through nanoindentation and atomic force microscopy measurements, but also on fibre individualisation, due to variations into fibre bundles cohesion. In addition, the morphology and particularly the lumen size induces apparent density differences. Moreover, the influence of fibre morphology and properties is demonstrated on UD materials. Finally, longitudinal Young’s modulus of each plant fibre batches is back-calculated from UD stiffness by an inverse method; the results obtained are in accordance with the values in the literature values, proving the interest of this method to estimate longitudinal Young’s modulus of short plant fibres.
doi_str_mv	10.1016/j.compositesa.2019.105504
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subjects	Biocomposite Engineering Sciences Mechanical properties Mechanics Mechanics of materials Microstructures Natural fibers
title	Main criteria of sustainable natural fibre for efficient unidirectional biocomposites
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