Laser Additive Manufacturing of Bio-inspired Metallic Structures

Jiankai Yang , Dongdong Gu , Kaijie Lin , Yicha Zhang , Meng Guo , Luhao Yuan , Han Zhang , Hongmei Zhang
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引用次数: 25

Abstract

High-performance/multifunctional metallic components primarily determine the service performance of equipment applied in the aerospace, aviation, and automobile industries. Organisms have developed structures with specific properties over millions of years of natural evolution, thereby providing inspiration for the design of high-performance structures to satisfy the increasing demands of modern industries. From the perspective of manufacturing, the ability of conventional processing technologies is inadequate for fabricating these complex structural configurations. By contrast, laser additive manufacturing (AM) is an effective method for fabricating complex metallic bio-inspired structures owing to its layer-by-layer deposition advantage. Herein, recent developments in the laser AM of bio-inspired cellular, plate, and truss structures, as well as the materials used in laser AM for bio-inspired printing are briefly reviewed. The organisms being imitated include butterfly, Norway spruce, mantis shrimp, beetle, and water spider, which expand the diversity of multifunctional structures for laser AM. The mechanical properties and functions of laser-AM-processed bio-inspired structures are discussed. Additionally, the challenges, possible outcomes, and directions of utilizing laser AM technology to fabricate high-performance/multifunctional metallic bio-inspired structures in the future are outlined.

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仿生金属结构的激光增材制造
高性能/多功能金属部件主要决定了应用于航空航天、航空和汽车工业的设备的服务性能。生物在数百万年的自然进化中已经发展出具有特定性能的结构,从而为高性能结构的设计提供了灵感,以满足现代工业日益增长的需求。从制造的角度来看,传统加工技术的能力不足以制造这些复杂的结构构型。相比之下,激光增材制造(AM)由于其逐层沉积的优势,是制造复杂金属仿生结构的有效方法。本文简要介绍了仿生细胞、板和桁架结构的激光增材制造的最新进展,以及用于仿生打印的激光增材制造材料。被模拟的生物包括蝴蝶、挪威云杉、螳螂虾、甲虫和水蜘蛛,这扩大了激光AM多功能结构的多样性。讨论了激光am加工仿生结构的力学性能和功能。此外,概述了未来利用激光增材制造技术制造高性能/多功能金属仿生结构的挑战、可能的结果和方向。
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