Magnetic Field Assisted 3D Printing of Limpet Teeth Inspired Polymer Matrix Composite With Compression Reinforcement

Dylan Joralmon, Evangeline A. Amonoo, Yizhen Zhu, Xiangjia Li
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引用次数: 6

Abstract

Lightweight and cost-effective polymer matrix composites (PMCs) with extraordinary mechanical performance will be a key to the next generation of diverse industrial applications such as aerospace, electric automobile, and biomedical devices. Limpet teeth made of mineral-polymer composites have been proved as nature’s strongest material due to the unique hierarchical architectures of mineral fiber alignment. Here, we present an approach to build limpet teeth inspired structural materials with precise control of geometric morphologies of microstructures by magnetic field-assisted 3D printing (MF-3DP). α-Iron (III) oxide-hydroxide nanoparticles (α-FeOOHs) are aligned by the magnetic field during 3D printing and aligned α-FeOOHs bundles are further grown to aligned goethite-based bundles (aGBs) by rapid thermal treatment after printing. The mechanical reinforcement of goethite-based fillers in PMCs can be modulated by adjusting the geometric morphology and alignment of mineral particles encapsulated inside the 3D printed PMCs. In order to identify the mechanical enhancement mechanism, physics-based modeling, simulation, and tests were conducted and the results further guided the design of bioinspired goethite-based PMCs. The correlation of the geometric morphology of self-assembled α-FeOOHs, curing characteristics of α-FeOOHs/polymer composite, and process parameters were identified to establish the optimal design of goethite-based PMCs. The 3D-printed PMCs with aGBs show promising mechanical reinforcement. This study opens intriguing perspectives for designing high strength 3D printed PMCs on the basis of bioinspired architectures with customized configurations.
磁场辅助3D打印帽贝齿启发聚合物基复合材料与压缩增强
具有优异机械性能的轻质、高性价比聚合物基复合材料(pmc)将成为下一代航空航天、电动汽车和生物医学设备等多种工业应用的关键。由矿物-聚合物复合材料制成的帽贝牙齿被证明是自然界最坚固的材料,因为矿物纤维排列的独特层次结构。在这里,我们提出了一种通过磁场辅助3D打印(MF-3DP)精确控制微结构几何形态来构建帽贝齿启发结构材料的方法。在3D打印过程中,α-氧化铁(III) -氢氧化物纳米粒子(α-FeOOHs)在磁场作用下排列,排列好的α-FeOOHs束在打印后通过快速热处理进一步生长为排列的针铁矿基束(aGBs)。通过调整包裹在3D打印pmc内部的矿物颗粒的几何形态和排列,可以调节pmc中针铁矿基填料的机械增强。为了明确针铁矿的力学增强机制,开展了基于物理的建模、仿真和试验,并进一步指导了仿生针铁矿pmc的设计。研究了自组装α-FeOOHs的几何形态、α-FeOOHs/聚合物复合材料的固化特性与工艺参数的相关性,建立了针铁矿基pmc的优化设计。具有agb的3d打印pmc显示出有希望的机械增强。这项研究为设计具有定制配置的生物启发架构的高强度3D打印pmc开辟了有趣的视角。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
10.90
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