轻量化异构三维点阵融合设计及界面力学性能分析

doi:10.16080/j.issn1671-833x.2022.14.110

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Abstract The fusion design method based on multi-lattice is expected to bring a new approach to weight reduction and increase performance of aerial structures. The existing design methods of multi-lattice structure have some problems, such as very small rod diameter, topology discontinuity and weak bearing capacity. An optimal design strategy of multi-lattice transition interface based on substructure parameter regulation was proposed. By adjusting the connectivity of transition region of different lattice configurations, the geometric high-order continuous optimization of multi-lattice transition boundary was realized. On this basis, the inflfluence of difffferent arrangement modes on deformation behavior and load-bearing capacity of multi-lattice structure was further analyzed, and the theoretical prediction model of geometric parameters-performance of multi-lattice structure was established. Experimental results show that compared with the traditional multi-lattice design method, the structural strength of the proposed method is improved by 52.2%. In addition, reasonable interface morphology can effffectively transfer load and avoid catastrophic failure of the structure at the interface.

Key words： Multi-lattice structure Interface optimization Boundary fusion Numerical simulation Mechanical property

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	Articles by authors
	LIU Tingting
	LIANG Zhuoheng
	REN Fangxi
	LIAO Wenhe
	ZHANG Changdong
	LI Dawei

Cite this article:

LIU Tingting,LIANG Zhuoheng,REN Fangxi, et al. Design of Lightweight Multi-Lattice Structure and Mechanical Property Analysis of Transition Boundaries[J]. Aeronautical Manufacturing Technology, 2022, 65(14): 110-117.

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https://www.amte.net.cn/EN/10.16080/j.issn1671-833x.2022.14.110 OR https://www.amte.net.cn/EN/Y2022/V65/I14/110