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Continuous Volumetric 3D Printing: Xolography in Flow

Stüwe, Lucas ; Geiger, Matthias ; Röllgen, Franz ; Heinze, Thorben ; Reuter, Marcus ; Wessling, Matthias ; Hecht, Stefan ; Linkhorst, John (2023)
Continuous Volumetric 3D Printing: Xolography in Flow.
In: Advanced Materials
doi: 10.1002/adma.202306716
Article, Bibliographie

Abstract

Additive manufacturing techniques continue to improve in resolution, geometrical freedom, and production rates, expanding their application range in research and industry. Most established techniques, however, are based on layer-by-layer polymerization processes, leading to an inherent trade-off between resolution and printing speed. Volumetric 3D printing enables the polymerization of freely defined volumes allowing the fabrication of complex geometries at drastically increased production rates and high resolutions, marking the next chapter in light-based additive manufacturing. This work advances the volumetric 3D printing technique xolography to a continuous process. Dual-color photopolymerization is performed in a continuously flowing resin, inside a tailored flow cell. Supported by simulations, the flow profile in the printing area is flattened, and resin velocities at the flow cell walls are increased to minimize unwanted polymerization via laser sheet-induced curing. Various objects are printed continuously and true to shape with smooth surfaces. Parallel object printing paves the way for up-scaling the continuous production, currently reaching production rates up to 1.75 mm3s-1\^3\textbackslash,\textbackslash rm s\^-1\textbackslash for the presented flow cell. Xolography in flow provides a new opportunity for scaling up volumetric 3D printing with the potential to resolve the trade-off between high production rates and high resolution in light-based additive manufacturing. This article is protected by copyright. All rights reserved

Item Type: Article
Erschienen: 2023
Creators: Stüwe, Lucas ; Geiger, Matthias ; Röllgen, Franz ; Heinze, Thorben ; Reuter, Marcus ; Wessling, Matthias ; Hecht, Stefan ; Linkhorst, John
Type of entry: Bibliographie
Title: Continuous Volumetric 3D Printing: Xolography in Flow
Language: English
Date: 2023
Publisher: Wiley
Journal or Publication Title: Advanced Materials
DOI: 10.1002/adma.202306716
Abstract:

Additive manufacturing techniques continue to improve in resolution, geometrical freedom, and production rates, expanding their application range in research and industry. Most established techniques, however, are based on layer-by-layer polymerization processes, leading to an inherent trade-off between resolution and printing speed. Volumetric 3D printing enables the polymerization of freely defined volumes allowing the fabrication of complex geometries at drastically increased production rates and high resolutions, marking the next chapter in light-based additive manufacturing. This work advances the volumetric 3D printing technique xolography to a continuous process. Dual-color photopolymerization is performed in a continuously flowing resin, inside a tailored flow cell. Supported by simulations, the flow profile in the printing area is flattened, and resin velocities at the flow cell walls are increased to minimize unwanted polymerization via laser sheet-induced curing. Various objects are printed continuously and true to shape with smooth surfaces. Parallel object printing paves the way for up-scaling the continuous production, currently reaching production rates up to 1.75 mm3s-1\^3\textbackslash,\textbackslash rm s\^-1\textbackslash for the presented flow cell. Xolography in flow provides a new opportunity for scaling up volumetric 3D printing with the potential to resolve the trade-off between high production rates and high resolution in light-based additive manufacturing. This article is protected by copyright. All rights reserved

Uncontrolled Keywords: continuous printing, flow profile shaping, volumetric 3D printing, xolography
Divisions: 16 Department of Mechanical Engineering
16 Department of Mechanical Engineering > Chair for Process Engineering of Electrochemical Systems
Date Deposited: 13 Sep 2023 11:13
Last Modified: 13 Sep 2023 11:13
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