Sensing of Damage in Glass Fiber Composites by Adding Carbon Nanotubes

Li Min Gao; Xin Lin Qing

doi:10.4028/www.scientific.net/AMM.330.68

Paper Titles

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Bamboo, Thermoplastic, Thermosets, and their Composites: A Review
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Precursor Preparation for Ti-Al-V-Y Alloy via FFC Cambridge Process
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Sensing of Damage in Glass Fiber Composites by Adding Carbon Nanotubes
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Moisture Effects on Cellulose Fiber Reinforced Concrete Properties
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Potential of Marine Clay as Raw Material inGeopolymer Composite
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Machinability Index Evaluation: A Case Study of Carbide Inserts
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Experimental Investigations for Statistically Controlled Vacuum Moulding Solutions of Al-SiC MMC
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 330Sensing of Damage in Glass Fiber Composites by...

Sensing of Damage in Glass Fiber Composites by Adding Carbon Nanotubes

Abstract:

Advanced fiber-reinforced polymer composites are known to possess outstanding specific strength and stiffness and their use in structural applications continues to expand. Most structural composites are susceptible to the formation of micro-scale damage in polymer matrix under adverse conditions which has significant implications on the durability and performance of fiber composites. Thus, it is imperative to detect the initiation and evolution of damage in composites long before their catastrophic failure. In this report, our recent research in sensing of micro-crack in matrix in situ and in real time for glass fiber composites was reviewed. Carbon nanotubes were dispersed into glass fiber composites by three roll mill technique. A resistance parameter was utilized to quantitatively characterize damage initiation and propagation. Damage mechanisms and development were investigated under tension, fatigue loadings. This research demonstrates the feasibility and benefits of electrical resistance measurements in the sensing of micro-scale damage for fiber composites using carbon nanotubes and offers the potential for in-service health monitoring of composite structures.