多尺度蜂窝芯连续纤维增强聚合物复合材料夹层结构的增材制造

Zhenhu Wang , Yaohui Wang , Jian He , Ke Dong , Guoquan Zhang , Wenhao Li , Yi Xiong
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摘要

具有蜂窝芯的复合材料夹层结构由于其优异的能量吸收能力而在轻质设计中普遍使用。然而,目前的制造工艺,如热压成型和模压,需要多个步骤和复杂的工具,从而限制了对先进夹层结构设计的探索。本研究报告了一种新的多材料增材制造(AM)工艺,该工艺允许一步生产具有多尺度蜂窝芯的连续纤维增强聚合物复合材料(CFRPC)夹层结构。具体而言,CFRPC-AM和原位泡沫AM工艺的集成提供了具有复杂设计的CFRPC面板和多尺度蜂窝芯的有效和高效制造。蜂窝核心设计跨越三个层次:微蜂窝、单元蜂窝和分级结构。制作了一套不同单元设计的夹层结构,即菱形、方形、蜂窝和凹入式蜂窝,并对其弯曲性能进行了实验研究。结果表明,菱形芯设计的夹层结构具有最高的抗弯刚度、强度和比能量吸收。此外,还考察了单元组合对CFRP复合材料夹层结构抗弯性能的影响。所提出的设计和制造方法为构建具有多尺度蜂窝芯的新型高性能CFRPC结构开辟了新的途径,而使用现有方法无法获得这些结构。
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Additive Manufacturing of Continuous Fiber-Reinforced Polymer Composite Sandwich Structures with Multiscale Cellular Cores

The use of composite sandwich structures with cellular cores is prevalent in lightweight designs owing to their superior energy-absorbing abilities. However, current manufacturing processes, such as hot-press molding and mold pressing, require multiple steps and complex tools, thus limiting the exploration of advanced sandwich structure designs. This study reports a novel multi-material additive manufacturing (AM) process that allows the single-step production of continuous fiber-reinforced polymer composite (CFRPC) sandwich structures with multiscale cellular cores. Specifically, the integration of CFRPC-AM and in situ foam AM processes provides effective and efficient fabrication of CFRPC panels and multiscale cellular cores with intricate designs. The cellular core design spans three levels: microcellular, unit-cell, and graded structures. Sandwich structures with a diverse set of unit-cell designs, that is, rhombus, square, honeycomb, and re-entrant honeycomb, were fabricated and their flexural behaviors were studied experimentally. The results showed that the sandwich structure with a rhombus core design possessed the highest flexural stiffness, strength, and specific energy absorption. In addition, the effect of the unit-cell assembly on the flexural performance of the CFRP composite sandwich structure was examined. The proposed design and fabrication methods open new avenues for constructing novel and high-performance CFRPC structures with multiscale cellular cores that cannot be obtained using existing approaches.

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