Manufacturing Technology 2024, 24(6):865-870 | DOI: 10.21062/mft.2024.094

Analysis of the Torsional Strength of Selected Photopolymers Additively Manufactured Using Polyjet Technology

Jacek Bernaczek ORCID..., Mariusz Dębski ORCID..., Małgorzata Gontarz-Kulisiewicz ORCID...
Faculty of Mechanical Engineering and Aeronautics, Rzeszów University of Technology. Al. Powstańców War-szawy 12, 35-959 Rzeszów, Poland

PolyJet technology, based on the printing and photopolymerization of model material, is currently, along with stereolithography or 3SP (Scan, Spin and Selectively Photocure), the most commonly used rapid prototyping method based on optically active resin. The article presents the results of torsional strength tests of samples made of optically active resins VeroDentPlus-MED690, VeroClear-RGD810, and Rigur-RGD450 by Stratasys in PolyJet technology. The samples were prepared in HQ (High Quality) mode with a layer height 0.016 [mm]. The tests included a static torsion test using a specialized research stand by the Department of Mechanical Engineering of the Rzeszów University of Technology. The scope of research significantly expanded the standard procedure, which complements the material data available with significant functional parameters due to the use of models. The results of the torsional strength analysis determined in the research process can be used to define the potential application area of the materials in question - optically active resins and their processing techniques for the production of parts subject to complex loads, i.e. machine shafts, clutches, and gear hubs.

Keywords: PolyJet Technology, Rapid Prototyping, Optically Active Resin, Strength Parameters, Torsional Strength

Received: July 12, 2024; Revised: November 11, 2024; Accepted: November 26, 2024; Prepublished online: December 6, 2024; Published: December 21, 2024  Show citation

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Bernaczek J, Dębski M, Gontarz-Kulisiewicz M. Analysis of the Torsional Strength of Selected Photopolymers Additively Manufactured Using Polyjet Technology. Manufacturing Technology. 2024;24(6):865-870. doi: 10.21062/mft.2024.094.
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