Mechanical analysis and toughening mechanisms of a multiphase recycled CFRP

Soraia Pimenta; Silvestre T. Pinho; Paul Robinson; Kok H. Wong; Stephen J. Pickering

doi:10.1016/j.compscitech.2010.06.017

Mechanical analysis and toughening mechanisms of a multiphase recycled CFRP

Soraia Pimenta, Silvestre T. Pinho, Paul Robinson, Kok H. Wong, Stephen J. Pickering

Research output: Journal Publication › Article › peer-review

52 Citations (Scopus)

Abstract

The mechanical response of a recycled CFRP is investigated experimentally. A complex multiscale microstructure is revealed, with both dispersed fibres (with fractured-sections) and fibre-bundles. The specific properties of the recyclate compare favourably with those of aluminium and glass-fibre composites. Micromechanical studies show that tensile failure follows the pre-existing fractured-sections on the dispersed-fibres, while compressive failure occurs by shear-banding. Fracture toughness measurements coupled with SEM evidence how bundles considerably toughen the composite by complex failure mechanisms. This analysis can guide the optimisation of recycling processes and support the development of design methods for recycled CFRP; it also provides insight on the mechanical response of other multiphase short-fibre reinforced materials.

Original language	English
Pages (from-to)	1713-1725
Number of pages	13
Journal	Composites Science and Technology
Volume	70
Issue number	12
DOIs	https://doi.org/10.1016/j.compscitech.2010.06.017
Publication status	Published - Oct 2010
Externally published	Yes

Keywords

A. Recycling
B. Fracture toughness
B. Mechanical properties
C. Damage mechanics
Multiscale composites

ASJC Scopus subject areas

Ceramics and Composites
General Engineering

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10.1016/j.compscitech.2010.06.017

Cite this

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title = "Mechanical analysis and toughening mechanisms of a multiphase recycled CFRP",

abstract = "The mechanical response of a recycled CFRP is investigated experimentally. A complex multiscale microstructure is revealed, with both dispersed fibres (with fractured-sections) and fibre-bundles. The specific properties of the recyclate compare favourably with those of aluminium and glass-fibre composites. Micromechanical studies show that tensile failure follows the pre-existing fractured-sections on the dispersed-fibres, while compressive failure occurs by shear-banding. Fracture toughness measurements coupled with SEM evidence how bundles considerably toughen the composite by complex failure mechanisms. This analysis can guide the optimisation of recycling processes and support the development of design methods for recycled CFRP; it also provides insight on the mechanical response of other multiphase short-fibre reinforced materials.",

keywords = "A. Recycling, B. Fracture toughness, B. Mechanical properties, C. Damage mechanics, Multiscale composites",

author = "Soraia Pimenta and Pinho, {Silvestre T.} and Paul Robinson and Wong, {Kok H.} and Pickering, {Stephen J.}",

note = "Funding Information: The funding from Portuguese Foundation for Science and Technology (Project No. SFRH/BD/44051/2008) is acknowledged. ",

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doi = "10.1016/j.compscitech.2010.06.017",

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journal = "Composites Science and Technology",

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AU - Pimenta, Soraia

AU - Pinho, Silvestre T.

AU - Robinson, Paul

AU - Wong, Kok H.

AU - Pickering, Stephen J.

N1 - Funding Information: The funding from Portuguese Foundation for Science and Technology (Project No. SFRH/BD/44051/2008) is acknowledged.

PY - 2010/10

Y1 - 2010/10

N2 - The mechanical response of a recycled CFRP is investigated experimentally. A complex multiscale microstructure is revealed, with both dispersed fibres (with fractured-sections) and fibre-bundles. The specific properties of the recyclate compare favourably with those of aluminium and glass-fibre composites. Micromechanical studies show that tensile failure follows the pre-existing fractured-sections on the dispersed-fibres, while compressive failure occurs by shear-banding. Fracture toughness measurements coupled with SEM evidence how bundles considerably toughen the composite by complex failure mechanisms. This analysis can guide the optimisation of recycling processes and support the development of design methods for recycled CFRP; it also provides insight on the mechanical response of other multiphase short-fibre reinforced materials.

AB - The mechanical response of a recycled CFRP is investigated experimentally. A complex multiscale microstructure is revealed, with both dispersed fibres (with fractured-sections) and fibre-bundles. The specific properties of the recyclate compare favourably with those of aluminium and glass-fibre composites. Micromechanical studies show that tensile failure follows the pre-existing fractured-sections on the dispersed-fibres, while compressive failure occurs by shear-banding. Fracture toughness measurements coupled with SEM evidence how bundles considerably toughen the composite by complex failure mechanisms. This analysis can guide the optimisation of recycling processes and support the development of design methods for recycled CFRP; it also provides insight on the mechanical response of other multiphase short-fibre reinforced materials.

KW - A. Recycling

KW - B. Fracture toughness

KW - B. Mechanical properties

KW - C. Damage mechanics

KW - Multiscale composites

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U2 - 10.1016/j.compscitech.2010.06.017

DO - 10.1016/j.compscitech.2010.06.017

M3 - Article

AN - SCOPUS:77955842862

SN - 0266-3538

VL - 70

SP - 1713

EP - 1725

JO - Composites Science and Technology

JF - Composites Science and Technology

IS - 12

ER -

Mechanical analysis and toughening mechanisms of a multiphase recycled CFRP

Abstract

Keywords

ASJC Scopus subject areas

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