• Title/Summary/Keyword: 극대 세장비

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A Proton Beam Shaping using an Extreme Aspect Ratio Micro-hole (극대세장비 마이크로 홀을 이용한 양성자 빔 집적 응용)

  • Kim, Jin-Nam;Kwon, Won-Tae;Lee, Seong-Gyu
    • Journal of the Korean Society for Precision Engineering
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    • v.29 no.7
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    • pp.737-744
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    • 2012
  • EDM is the manufacturing process that uses the thermal energy to machine electrically conductive part. Despite a lot of research has been conducted for decades, the best aspect ratio of the micro hole using micro-EDM has not been over 30, yet. In the present study, new fabrication scheme was introduced to increase the aspect ratio of micro hole dramatically. Micro holes with less than 10 aspect ratio were aligned and welded together to manufacture a micro hole with extreme aspect ratio. Alignment of the micro hole with over 380 aspect ratio was conducted by the home-made apparatus installed with microscope and laser beam. The micro hole with extreme aspect ratio was used to shape pencil beam from proton beam generated from MC-50 cyclotron. The pencil beam was utilized to machine test specimen whose result was compared with GEANT4 computer simulation. It was shown that the experimental and simulation result were closer as the aspect ratio of the micro hole was bigger.

Manufacturing of Three-dimensional Micro Structure Using Proton Beam (양성자 빔을 이용한 3차원 마이크로 구조물 가공)

  • Lee, Seonggyu;Kwon, Won Tae
    • Transactions of the Korean Society of Mechanical Engineers B
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    • v.39 no.4
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    • pp.301-307
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    • 2015
  • The diameter of a proton beam emanating from the MC-50 cyclotron is about 2-3 mm with Gaussian distribution. This widely irradiated proton beam is not suitable for semiconductor etching, precise positioning, and micromachining, which require a small spot. In this study, a beam cutting method using a microhole is proposed as an economical alternative. We produced a microhole with aspect ratio, average diameter, and thickness of 428, $21{\mu}m$, and 9 mm, respectively, for cutting the proton beam. By using this high-aspect-ratio microhole, we conducted machinability tests on microstructures with sizes of tens of ${\mu}m$. Additionally, the results of simulation using GEANT4 and those of the actual experiment were compared and analyzed. The outcome confirmed the possibility of implementing a micro process technology for the fabrication of three-dimensional microstructures of 20 micron units using the MC-50 cyclotron with the microhole.