纤维增强复合材料晶格材料的设计、制造和动态力学响应

IF 3.4 Q1 ENGINEERING, MECHANICAL 国际机械系统动力学学报(英文) Pub Date : 2023-09-14 DOI:10.1002/msd2.12085
Jian Xiong, Cheng Gong, Qianqian Wu, Li Ma, Jinshui Yang, Linzhi Wu
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引用次数: 0

摘要

纤维增强复合材料是一种流行的轻质材料,由于其诱人的机械性能,可用于航空航天、建筑、汽车和海洋建筑等各种工程应用。由纤维增强复合材料构建晶格材料是开发具有优异机械性能和多功能优势的超轻结构系统的有效方法。与波纹、泡沫和蜂窝芯材不同,复合格构材料可采用各种建筑设计制造,如编织、网格和特拉斯芯材。此外,与传统的闭孔蜂窝和泡沫结构相比,具有开孔拓扑结构的晶格材料具有多功能优势,因此非常适合开发航空航天系统、高超音速飞行器、远程火箭和导弹、船舶和海军结构以及防护系统。本研究的目的是回顾和分析不同研究人员在复合晶格材料领域的动态力学行为,并突出未来研究的主题。
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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Design, fabrication, and dynamic mechanical responses of fiber-reinforced composite lattice materials

Fiber-reinforced composites are a popular lightweight materials used in a variety of engineering applications, such as aerospace, architecture, automotive, and marine construction, due to their attractive mechanical properties. Constructing lattice materials from fiber-reinforced composites is an efficient approach for developing ultra-lightweight structural systems with superior mechanical properties and multifunctional benefits. In contrast to corrugated, foam, and honeycomb core materials, composite lattice materials can be manufactured with various architectural designs, such as woven, grid, and truss cores. Moreover, lattice materials with open-cell topology provide multifunctional advantages over conventional closed-cell honeycomb and foam structures and are thus highly desirable for developing aerospace systems, hypersonic vehicles, long-range rockets and missiles, ship and naval structures, and protective systems. The objective of this study is to review and analyze dynamic mechanical behavior performed by different researchers in the area of composite lattice materials and to highlight topics for future research.

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