Stress-driven infill mapping for 3D-printed continuous fiber composite with tunable infill density and morphology

Liu, Tong1; Yuan, Shangqin1,2,3; Wang, Yaohui4; Xiong, Yi4; Zhu, Jihong2,3; Lu, Lu1,2; Tang, Yunlong1,5,6

2023-01-25

10.1016/j.addma.2022.103374

Additive Manufacturing   影响因子和分区

2214-8604

2214-7810

Continuous fiber composite via additive manufacturing is an emerging field that extends the design freedom of composite structure as well as integrates with the digital fabrication approach. The path planning for continuous fiber is highly freedom to achieve tunable and desirable lightweight performance. Herein, a wave projection function is proposed to design the infill morphology and control the infill ratio corresponding to a specific vector field. The infill ratio and path orientation are simultaneously mapped with mechanical stress field distribution. The path planning algorithm via solving the traveling salesman problem (TSP) is employed to generate continuous fiber trajectories with minimized cutting points. As fabricated composite structure shows outstanding performance over these with conventional Zig-Zag infill pattern, which possesses identical infill ratio. The proposed infill approach can integrate with the topology optimized structure to concurrently optimize the infill fiber path and structural configuration. This generative design for composite structure is a typical AM-driven approach, which exhibits strong advantages to create adaptive infill patterns with complex geometry.

Continuous fiber composite via additive  manufacturing Path planning Stress-driven design 3D printing of composite

SCI ; EI

英语

其他

National Key R & D Program of China[CQYC201903241] ; CAST talent fund[2022YFB4602001] ; Key laboratory fund for equipment preresearch[2022YFB3402200] ; null[2021QNRC001]

Engineering ; Materials Science

Engineering, Manufacturing ; Materials Science, Multidisciplinary

WOS:000926884200001

ELSEVIER

20230213379665

Additives ; Fibers ; Infill drilling ; Morphology ; Motion planning ; Stress concentration ; Structure (composition) ; Traveling salesman problem

Oil Field Production Operations:511.1 ; Printing Equipment:745.1.1 ; Chemical Agents and Basic Industrial Chemicals:803 ; Operations Research:912.3 ; Optimization Techniques:921.5 ; Physical Properties of Gases, Liquids and Solids:931.2 ; Materials Science:951

Web of Science

1.Northwestern Polytech Univ, Unmanned Syst Res Inst, Xian 710072, Shaanxi, Peoples R China
2.Northwestern Polytech Univ, State IJR Ctr Aerosp Design & Addit Mfg, Sch Mech Engn, MIIT China, Xian 710072, Shaanxi, Peoples R China
3.Northwestern Polytech Univ, NPU QMUL Joint Res Inst, Key Lab Met High Performance Addit Mfg & Innovat D, Xian 710072, Peoples R China
4.Southern Univ Sci & Technol, Sch Syst Design & Intelligent Mfg, Shenzhen 518055, Peoples R China
5.Monash Univ, Mech & Aerosp Engn Dept, Melbourne 3800, Australia
6.Monash Univ, Mat Sci & Engn Dept, Melbourne 3800, Australia

Liu, Tong,Yuan, Shangqin,Wang, Yaohui,et al. Stress-driven infill mapping for 3D-printed continuous fiber composite with tunable infill density and morphology[J]. Additive Manufacturing,2023,62.

Liu, Tong.,Yuan, Shangqin.,Wang, Yaohui.,Xiong, Yi.,Zhu, Jihong.,...&Tang, Yunlong.(2023).Stress-driven infill mapping for 3D-printed continuous fiber composite with tunable infill density and morphology.Additive Manufacturing,62.

Liu, Tong,et al."Stress-driven infill mapping for 3D-printed continuous fiber composite with tunable infill density and morphology".Additive Manufacturing 62(2023).