Geometric limitations of 3D printed continuous flax-fiber reinforced biocomposites cellular lattice structures

被引:15
作者
Fruleux, Thomas [1 ]
Castro, Mickael [1 ]
Correa, David [2 ]
Wang, Kui [3 ]
Matsuzaki, Ryosuke [4 ]
Le Duigou, Antoine [1 ]
机构
[1] Ctr Rech Christian Huygens, Inst Rech Dupuy Lame IRDL UMR CNRS 6027, Bion Grp, Rue St Maude, F-56100 Lorient, France
[2] Univ Waterloo, Sch Architecture, 7 Melville St 5, Cambridge, ON N1S 2H4, Canada
[3] Cent South Univ CSU, Sch Traff & Transportat Engn, Changsha, Peoples R China
[4] Tokyo Univ Sci, Noda Campus 2641, Noda, Chiba 2788510, Japan
来源
COMPOSITES PART C: OPEN ACCESS | 2022年 / 9卷
关键词
3D printing; Natural fiber reinforced materials; Geometric limitations; Lattice; CONTINUOUS CARBON-FIBER; COMPOSITE;
D O I
10.1016/j.jcomc.2022.100313
中图分类号
TB33 [复合材料];
学科分类号
摘要
3D-printing of biocomposites using continuous natural fiber composites is emerging as a relevant manufacturing method to develop highly tailorable materials. These are materials with high performance characteristics, whose capabilities have been achieved through the controlled design of the mesostructure via the 3D printing process. However, the development of 3D printing using continuous natural fiber composites is so recent that no geometric limitations have yet been investigated. The present article has established the printability and design window of several cellular lattice structures by investigating and discussing a comparative analysis of the difference between the programmed and actual trajectories of pure polylactic acid (PLA), short flax fiber biocomposite (FF/PLA) and continuous flax fiber/PLA biocomposites (cFF/PLA) for a specific set of printing and slicing parameters. It is expected that the presented findings will support the ongoing development of improved design methods and optimized technical deposition approaches that can expand the design space for cFF/PLA 3D printed biocomposites with multi-layered periodic cellular lattice patterns.
引用
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页数:5
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