Hopping Light Vat Photopolymerization for Multiscale Fabrication

3D objects with features spanning from microscale to macroscale have various applications. However, the fabrication of such objects presents challenges to additive manufacturing (AM) due to the tradeoffs among manufacturable feature resolution, maximum build area, and printing speed. This paper presents a projection-based AM process called hopping light vat photopolymerization (HL-VPP) to address this critical barrier. The key idea of HL-VPP is to synchronize linear scanning projection with a galvo mirror's rotation. The projector moves continuously at a constant speed while periodically rotating a one-axis galvo mirror to compensate for the projector's linear movement so synchronized hopping motion can be achieved. By this means, HL-VPP can simultaneously achieve large-area (over 200 mm), fast-speed (scanning speed of 13.5 mm s(-1)), and high-resolution (10 mu m pixel size) fabrication. The distinguishing characteristic of HL-VPP is that it allows for hundreds of times lower refresh rates without motion blur. Thus, HL-VPP decouples the fabrication efficiency limit imposed by the refresh rate and will enable super-fast curing in the future. This work will significantly advance VPP's use in applications that require macroscale part size with microscale features. The process has been verified by fabricating multiple multiscale objects, including microgrids and biomimetic structures.

Automated summary

This paper presents a projection-based AM process called hopping light vat photopolymerization (HL-VPP) to address the challenges of fabricating 3D objects with features spanning from microscale to macroscale. HL-VPP achieves large-area, fast-speed, and high-resolution fabrication by synchronizing linear scanning projection with a galvo mirror's rotation. The distinguishing characteristic of HL-VPP is its ability to achieve super-fast curing without motion blur, significantly advancing VPP's use in applications that require macroscale part size with microscale features.