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Improvement of Mechanical Properties of UV-curable Resin for High-aspect Ratio Microstructures Fabricated in Microstereolithography  

Lee, Su-Do (부산대학교 대학원 지능기계공학부)
Choi, Jae-Won (부산대학교 기계기술연구소)
Park, In-Beak (부산대학교 대학원 지능기계공학부)
Ha, Chang-Sik (부산대학교 고분자공학과)
Lee, Seok-Hee (부산대학교 기계공학부)
Publication Information
Journal of the Korean Society for Precision Engineering / v.24, no.12, 2007 , pp. 119-127 More about this Journal
Abstract
Recently, microstructures fabricated using microstereolithography technology have been used in the biological, medical and mechanical fields. Microstereolithography can fabricate real 3D microstructures with fine features, although there is presently a limited number of materials available for use in the process. Deformation of the fine features on a fabricated microstructure remains a critical issue for successful part fabrication, and part deformation can occur during rinsing or during fabrication as a result of fluid flow forces that occur during movement of mechanical parts of the system. Deformation can result in failure to fabricate a particular feature by breaking the feature completely, spatial deflection of the feature, or attaching the feature to neighboring microstructures. To improve mechanical strength of fabricated microstructures, a clay nanocomposite can be used. In particular, a high-aspect ratio microstructure can be fabricated without distortion using photocurable liquid resin containing a clay nanocomposite. In this paper, a clay nanocomposite was blended with a photocurable liquid resin to solve the deformation problem that occurs during fabrication and rinsing. An optimal mixture ratio of a clay nanocomposite was found through tensile testing and the minimal allowable distance between microstructures was found through fabrication experimentation. Finally, using these results, high-aspect ratio microstructures were fabricated using a clay nanocomposite resin without distortion.
Keywords
microstereolithography; high aspect ratio structure; clay nanocomposite; mechanical strength;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
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