Reinforced FDM

Multi-axis filament alignment with controlled anisotropic strength

Journal Article (2020)
Author(s)

G. Fang (TU Delft - Materials and Manufacturing)

Tianyu Zhang (Chinese University of Hong Kong)

Sikai Zhong (Wayne State University)

Xiangjia Chen (Chinese University of Hong Kong)

Zichun Zhong (Wayne State University)

Charlie Wang (The University of Manchester)

Research Group
Materials and Manufacturing
Copyright
© 2020 G. Fang, Tianyu Zhang, Sikai Zhong, Xiangjia Chen, Zichun Zhong, C.C. Wang
DOI related publication
https://doi.org/10.1145/3414685.3417834
More Info
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Publication Year
2020
Language
English
Copyright
© 2020 G. Fang, Tianyu Zhang, Sikai Zhong, Xiangjia Chen, Zichun Zhong, C.C. Wang
Research Group
Materials and Manufacturing
Issue number
6
Volume number
39
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Abstract

The anisotropy of mechanical strength on a 3D printed model can be controlled in a multi-axis 3D printing system as materials can be accumulated along dynamically varied directions. In this paper, we present a new computational framework to generate specially designed layers and toolpaths of multi-axis 3D printing for strengthening a model by aligning filaments along the directions with large stresses. The major challenge comes from how to effectively decompose a solid into a sequence of strength-aware and collision-free working surfaces. We formulate it as a problem to compute an optimized governing field together with a selected orientation of fabrication setup. Iso-surfaces of the governing field are extracted as working surface layers for filament alignment. Supporting structures in curved layers are constructed by extrapolating the governing field to enable the fabrication of overhangs. Compared with planar-layer based Fused Deposition Modeling (FDM) technology, models fabricated by our method can withstand up to 6.35× loads in experimental tests.

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