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The effect of nanoparticle enhanced sizing on the structural health monitoring sensitivity and mechanical properties of carbo...

by Christopher C Bowland, Ngoc A Nguyen, Amit K Naskar
Publication Type
Conference Paper
Journal Name
SPIE Proceedings
Book Title
Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XII
Publication Date
Volume
10599
Publisher Location
Denver, Colorado, United States of America
Conference Name
SPIE Smart Structures + Nondestructive Evaluation
Conference Location
Denver, Colorado, United States of America
Conference Sponsor
The international society for optics and photonics
Conference Date
-

With current carbon composites being introduced into new commercial market sectors, there is an opportunity to develop multifunctional composites, which are poised to be the next generation of composites that will see future commercial applications. This multifunctional attribute can be achieved via integrated nanomaterials, which are currently under-utilized in real-world applications despite significant research efforts focused on their synthesis. This research utilizes a simple, scalable approach to integrate various nanomaterials into carbon fiber composites by embedding the nanomaterials in the epoxy fiber sizing. Illustrated in this work is the effect of silicon carbide nanoparticle concentrations and dimensions on the structural health monitoring sensitivity of unidirectional carbon fiber composites. Additionally, the nanoparticles contribute to the overall damping property of the composites thus enabling tunable damping through simple variations in nanoparticle concentration and size. Not only does this nanoparticle sizing offer enhanced sensitivity and tunable damping, but it also maintains the mechanical integrity and performance of the composites, which demonstrates a truly multifunctional composite. Therefore, this research establishes an efficient route for combining nanomaterials research with real-world multifunctional composite applications using a technique that is easily scalable to the commercial level and is compatible with a wide range of fibers and nanomaterials.