3D printing of a continuous fiber-reinforced composite based on a coaxial Kevlar/PLA filament

Trenton Cersoli, B. Yelamanchi, E. MacDonald, J. G. Carrillo, P. Cortes
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引用次数: 6

Abstract

Additive manufacturing has allowed for the production of complex and mass customized geometries, but often at the expense of mechanical performance, a penalty which can be in part mitigated with the fabrication of composite parts. Thermoplastic structures fabricated with material extrusion additive manufacturing stand to be improved in terms of fracture toughness with the integration of continuous fibers. The present research program has investigated the production of a continuously reinforced filament to be used in open-source fused filament fabrication systems. Three different volume fractions of Kevlar fibers were incorporated into a polylactic acid (PLA) thermoplastic filament. It was observed that a 20% fiber volume fraction resulted in a doubling of the tensile strength relative to the unreinforced PLA parts. High-velocity impact tests were also performed on the reinforced printed thermoplastic material, and it was observed that the composite with the highest fiber volume fraction provided an impact energy resistance improved by a factor of four, relative to the plain PLA. The reinforced fibers have shown to restrain the penetration of the projectile at velocities similar to those that perforated the unreinforced PLA. The present work has demonstrated the production of printed composites without the need of modifying the extruding systems of a commercial 3D printer. This approach could represent an alternate and feasible process for producing continuously reinforced 3D-printed thermoplastic parts with utility for high-velocity impact applications.
基于同轴凯夫拉/PLA长丝的连续纤维增强复合材料的3D打印
增材制造允许生产复杂和大规模定制的几何形状,但通常以牺牲机械性能为代价,这种损失可以通过复合材料部件的制造部分减轻。材料挤压增材制造的热塑性结构在断裂韧性方面有待于与连续纤维的集成来提高。本研究计划研究了用于开源熔丝制造系统的连续增强长丝的生产。将三种不同体积分数的凯夫拉纤维掺入聚乳酸(PLA)热塑性长丝中。观察到,20%的纤维体积分数导致相对于未增强的PLA部件的抗拉强度增加一倍。对增强印刷热塑性材料也进行了高速冲击试验,观察到纤维体积分数最高的复合材料的抗冲击能量提高了四倍,相对于普通PLA。增强纤维已经显示出抑制弹丸的穿透速度类似于那些穿孔未增强PLA。目前的工作已经证明了生产印刷复合材料,而不需要修改商业3D打印机的挤出系统。这种方法可以代表一种替代和可行的工艺,用于生产连续增强的3d打印热塑性塑料部件,用于高速冲击应用。
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