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Electro-mechanical characterization of three-dimensionally conductive graphite/epoxy composites under tensile and shear loading
Journal article   Peer reviewed

Electro-mechanical characterization of three-dimensionally conductive graphite/epoxy composites under tensile and shear loading

Riley Sherman, Vijaya Chalivendra, Asha Hall, Mulugeta Haile, Latha Nataraj, Michael Coatney and Yong Kim
Composites communications, Vol.15, pp.30-33
10/01/2019

Abstract

Materials Science Materials Science, Composites Science & Technology Technology
An experimental study was performed to compare the electro-mechanical response of three-dimensionally conductive woven carbon fiber/ epoxy laminated composites under quasi-static uniaxial tensile and in-plane shear loading conditions. Three-dimensional (3D) electrical network was generated in these composites by embedding carbon nanotubes (CNTs) of 0.025 wt% in the epoxy and reinforcing short carbon fibers (150 mu m and 350 mu m long) with a fiber density of 1000 fibers/mm(2) between the laminates using electro-flocking process. CNTs are effectively dispersed in the epoxy matrix using a combination of ultrasonication and shear mixing techniques. A compression molding fabrication technique was employed to fabricate composite materials. For all composite types, in general, the in-situ electrical response showed a trend of initial decrease in resistance and later increase in resistance for tensile loading. However, no noticeable increase in electrical resistance was observed until failure of the composite under shear loading conditions. Both CNTs and short carbon fibers made new contacts with neighboring carbon fiber laminates for entire duration of shear loading even though the composite was undergoing progressive failure.

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