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Strain and damage sensing in additively manufactured CB/ABS polymer composites
Journal article   Peer reviewed

Strain and damage sensing in additively manufactured CB/ABS polymer composites

Md Fazlay Rabbi and Vijaya Chalivendra
Polymer testing, Vol.90, p.106688
10/01/2020

Abstract

Materials Science Materials Science, Characterization & Testing Physical Sciences Polymer Science Science & Technology Technology
In this study, an experimental investigation is performed to observe the electromechanical response of CB (carbon black)/Acrylonitrile butadiene styrene (ABS) additive manufactured composite under quasi-static (tensile, shear, and mode-I fracture) and dynamic (mode-I fracture) loading conditions for the potential damage sensing applications. Dog bone tensile, double v-notch shear, and single edge notch bending (SENB) specimen printed with three different configurations (0 degrees/90 degrees, +45 degrees/-45 degrees, and 0 degrees) are considered for the quasi-static condition. A modified split Hopkinson pressure bar along with high-speed video camera is used for dynamic fracture experiments. Four-point probe technique coupled with a high-resolution data acquisition system is employed to obtain the real-time electrical response. In the case of tensile loading, +45/-45 degrees printed specimens show a nonlinear change of electrical resistance due to unique failure mode. Under the shear loading, electrical resistance remains unchanged during the elastic deformation. After the damage evolution, +45/-45 degrees printed specimens exhibit a higher rate of change in electrical resistance due to alignment of the filaments along the maximum principle shear stress direction. For both static and dynamic fracture loading, a minimal change of electrical resistance is observed before crack initiation. However, after the crack initiation, a sharp change of electrical resistance for 0/90 degrees printed specimens indicates a faster crack propagation as compared to the +45 degrees/-45 degrees printed specimens.
url
https://doi.org/10.1016/j.polymertesting.2020.106688View
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