Exposure Time Variation Method Using DMD for Microstereolithography
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概要
- 論文の詳細を見る
In stereolithography, parts are fabricated by curing photopolymeric resins with light. The application of stereolithography can now be extended to a very small scale. The process, called microstereolithography, can fabricate parts on a microscale without any further consideration of geometry complexity. In particular, projection-type microstereolithography can perform quite rapid fabrication that cures a specific cross section in one exposure to light without movement. However, in the case where the light source has a nonuniform intensity or an aberration caused by its optics, the part might have some distortion, and this is commonly the case. Because the material experiences shrinkage when it is cured, the light intensity over the entire cross section should be uniform. This study utilizes a Dynamic Mirror Device, which is mainly used for beam shaping, to control the beam intensity also. This control makes the beam intensity profile flat and reduces the distortion to a great degree. This paper presents the concept of an exposure time control method that makes the beam intensity uniform, and it also presents some experimental results.
著者
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Lee In-hwan
School Of Advanced Materials Engineering And Research Center For Advanced Materials Development Chon
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LEE In-Hwan
School of Mechanical Engineering, Chungbuk National University
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KO Tae-Jo
School of Mechanical Engineering, Yeungnam University
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YOON Hae-Ryong
Department of Mechanical and Automotive Engineering, Andong National University
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KIM Ho-chan
Department of Mechanical and Automotive Engineering, Andong National University
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