Abstract
The low productivity of typical 3D printing is a major hurdle for its utilization in large-scale manufacturing. Innovative techniques have been developed to break the limitation of printing speed, however, sophisticated facilities or costly consumables are required, which still substantially restricts the economic efficiency. Here we report that a common stereolithographic 3D printing facility can achieve a very high printing speed (400 mm/h) using a green and inexpensive hydrogel as a separation interface against the cured part. In sharp contrast to other techniques, the unique separation mechanism relies on the large recoverable deformation along the thickness direction of the hydrogel interface during the layer-wise printing. The hydrogel needs to be extraordinarily soft and unusually thick to remarkably reduce the adhesion force which is a key factor for achieving rapid 3D printing. This technique shows excellent printing stability even for fabricating large continuous solid structures, which is extremely challenging for other rapid 3D printing techniques. The printing process is highly robust for fabricating diversified materials with various functions. With the advantages mentioned above, the presented technique is believed to make a large impact on large-scale manufacturing.
Highlights
The low productivity of typical 3D printing is a major hurdle for its utilization in large-scale manufacturing
We present that an extraordinarily soft hydrogel can be utilized as an excellent separation interface to enable rapid printing
Acrylamide (AAm), N,N′-methylenebisacrylamide (BIS), 2-phenoxy ethyl acrylate (2-PEA), isobornyl acrylate (IBOA) were purchased from J&K company. 2-hydroxy-4′-(2-hydroxyethoxy)-2-methylpropiophenone (Irgacure 2959), Sudan III were obtained from Aladdin reagent company
Summary
The low productivity of typical 3D printing is a major hurdle for its utilization in large-scale manufacturing. The hydrogel needs to be extraordinarily soft and unusually thick to remarkably reduce the adhesion force which is a key factor for achieving rapid 3D printing This technique shows excellent printing stability even for fabricating large continuous solid structures, which is extremely challenging for other rapid 3D printing techniques. Hydrogels have shown promises in various bio-related fields due to their high water content and softness which provides excellent compatibility with biological tissues[24,25] These two characteristics, limit their potential for wider applications in particular for non-bio-related manufacturing. Except for the application of the hydrogel interface, the printing process and the facility has no difference with a common technique whereas the printing speed increases by an order of magnitude
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