Visualization of dynamic fiber-matrix interfacial shear debonding

To visualize the debonding event in real time for the study of dynamic crack initiation and propagation at the fiber–matrix interface, a modified tension Kolsky bar was integrated with a high-speed synchrotron X-ray phase-contrast imaging setup. In the gage section, the pull-out configuration was ut...

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Veröffentlicht in:	Journal of materials science 2017-10, Vol.53 (8)
Hauptverfasser:	Chu, Jou -Mei, Claus, Benjamin, Parab, Niranjan, O’Brien, Daniel, Sun, Tao, Fezzaa, Kamel, Chen, Wayne
Format:	Artikel
Sprache:	eng
Schlagworte:	high-speed synchrotron x-ray interfacial shear stress Kolsky bar MATERIALS SCIENCE phase contrast imaging pull-out technique
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creator	Chu, Jou -Mei Claus, Benjamin Parab, Niranjan O’Brien, Daniel Sun, Tao Fezzaa, Kamel Chen, Wayne
description	To visualize the debonding event in real time for the study of dynamic crack initiation and propagation at the fiber–matrix interface, a modified tension Kolsky bar was integrated with a high-speed synchrotron X-ray phase-contrast imaging setup. In the gage section, the pull-out configuration was utilized to understand the behavior of interfacial debonding between SC-15 epoxy matrix and S-2 glass fiber, tungsten wire, steel wire, and carbon fiber composite Z-pin at pull-out velocities of 2.5 and 5.0 m s–1. The load history and images of the debonding progression were simultaneously recorded. Both S-2 glass fiber and Z-pin experienced catastrophic interfacial debonding whereas tungsten and steel wire experienced both catastrophic debonding and stick–slip behavior. Even though S-2 glass fiber and Z-pin samples exhibited a slight increase and tungsten and steel wire samples exhibited a slight decrease in average peak force and average interfacial shear stress as the pull-out velocities were increased, no statistical difference was found for most properties when the velocity was increased. Furthermore, the debonding behavior for each fiber material is similar with increasing pull-out velocity. Thus, the debonding mechanism, peak force, and interfacial shear stress were rate insensitive as the pull-out velocity doubled from 2.5 to 5.0 m s–1. In conclusion, scanning electron microscope imaging of recovered epoxy beads revealed a snap-back behavior around the meniscus region of the bead for S-2 glass, tungsten, and steel fiber materials at 5.0 m s–1 whereas those at 2.5 m s–1 exhibited no snap-back behavior.
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Even though S-2 glass fiber and Z-pin samples exhibited a slight increase and tungsten and steel wire samples exhibited a slight decrease in average peak force and average interfacial shear stress as the pull-out velocities were increased, no statistical difference was found for most properties when the velocity was increased. Furthermore, the debonding behavior for each fiber material is similar with increasing pull-out velocity. Thus, the debonding mechanism, peak force, and interfacial shear stress were rate insensitive as the pull-out velocity doubled from 2.5 to 5.0 m s–1. 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subjects	high-speed synchrotron x-ray interfacial shear stress Kolsky bar MATERIALS SCIENCE phase contrast imaging pull-out technique
title	Visualization of dynamic fiber-matrix interfacial shear debonding
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