Litcius/Paper detail

A low-cost and high-strength basalt/carbon fiber reinforced polymer improved by imitating tree-root micro/nano aramid short fiber

Guangming Yang, Yanan LYU, Fei Cheng, Jiaxin He, Shihao Zuo, Wenyi Huang, Yunsen Hu, Xiaozhi Hu, Xi Chen

2024Chinese Journal of Aeronautics13 citationsDOIOpen Access PDF

Abstract

The high-strength Basalt Carbon Fiber Reinforced Polymer (BCFRP) composites had been manufactured by guiding Imitating Tree-root Micro/Nano Aramid Short Fiber (IT-MNASF) into the interlayer of Basalt Fiber (BF) and Carbon Fiber (CF) plies to form thin interleaving, and various mass proportions of IT-MNASF were designed to discuss the reinforcing effect on the BCFRP heterogeneous composites. The results of three points bending tests showed that flexural strength and energy absorption of 4 wt% IT-MNASF reinforced BCFRP heterogeneous composites had been improved by 32.4% and 134.4% respectively compared with that of unreinforced specimens. The 4 wt% IT-MNASF reinforced BCFRP specimens showed both a greater strength and a lower cost (reduced by 31% around) than that of plain CFRP composites. X-ray micro-computed tomography scanning results exhibited that the delamination-dominated failure of plain BCFRP composites was changed into multi-layer BF and CF fabrics damage. The reinforcing mechanism revealed that the introduced IT-MNASF could construct quasi-vertical fiber bridging, and it was used as “mechanical claws” to grasp adjacent fiber layers for creating a stronger mechanical interlocking, and this effectively improved resin-rich region and interfacial transition region at the interlayers. The simple and effective IT-MNASF interleaving technique was very successful in low-cost and high-strength development of BCFRP heterogeneous composites.

Topics & Concepts

Materials scienceComposite materialFlexural strengthBasalt fiberAramidFiberDelamination (geology)SubductionPaleontologyBiologyTectonicsFiber-reinforced polymer compositesNatural Fiber Reinforced CompositesTribology and Wear Analysis