Examination of adhesive force and the model’s dimension in continuous and conventional printing using the oxygen inhibition effect

In constrained surface vat photopolymerization, the adhesive force between the formed layer of the model and the bottom of the resin container restricts the printing capability. This research investigates the adhesive forces in digital light processing (DLP) and continuous digital light processing (...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science Journal of mechanical engineering science, 2024-11, Vol.238 (22), p.10733-10743
Main Authors: Manzour, Amir Hasan, Zamani, Jamal
Format: Article
Language:English
Subjects:
Adhesives
Containers
Evaluation
Oxygen
Permeability
Photopolymerization
Printing
Resins
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Summary:In constrained surface vat photopolymerization, the adhesive force between the formed layer of the model and the bottom of the resin container restricts the printing capability. This research investigates the adhesive forces in digital light processing (DLP) and continuous digital light processing (CDLP), focusing on how the oxygen inhibition effect, resin container membrane, and model geometries affect these forces. This study tested four distinct resin vats, with particular attention given to oxygen-permeable vats, to evaluate their role in reducing adhesive forces. A permeable vat that reduced the separation force by 52% using the oxygen inhibition layer was assessed for continuous printing. The influence of model geometry on the adhesive force in DLP and CDLP was evaluated using a permeable vat. Moreover, an inverse relationship was identified between resin absorbance and both curing depth and printing speed. It was observed that as the model’s cross-sectional area increased, so did the adhesion force in continuous printing. These findings prove that continuous printing can achieve faster build times in CDLP than in DLP, with a maximum speed of 288 mm/h.
ISSN:0954-4062
2041-2983
DOI:10.1177/09544062241264599