• 제목/요약/키워드: Stage-scanner synchronization

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3차원 대면적 연속 마이크로 레이저 패터닝을 위한 연구 (Study of 3 dimensional wide area continuous laser micro patterning)

  • 김경한;손현기;이제훈
    • 한국레이저가공학회지
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    • 제18권4호
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    • pp.1-5
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    • 2015
  • For continuous laser micro patterning on three-dimensional free form surface, innovative laser system is developed. The two axis galvanometer is combined with the dynamic focusing unit to increase optical distance. Also, it is synchronized with the 3 axis mechanical system. To determine laser machining sequence, laser CAM system is developed. It can make possible of 3D surface micro patterning under $25{\mu}m$ pattern width. The uniformity of pattern width is about 2.8% and it is validated that focal plane is well conserved by the dynamic focusing unit. Velocity and positional information of 1 axis is stage is fed to the scanner control board by the encoder signal and it makes possible real time synchronization. With this system, possible patterning volume is enlarged from $40{\times}40mm^2$ to $40{\times}120{\times}30mm^3$.

대면적 레이저 가공을 위한 가감속 파라미터가 가공오차에 미치는 영향 (Effects of Acceleration and Deceleration Parameters on the Machining Error for Large Area Laser Processing)

  • 이제훈;윤광호;김경한
    • 한국정밀공학회지
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    • 제31권8호
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    • pp.721-728
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    • 2014
  • In this paper, it is proposed a method of optimizing path parameters for large-area laser processing. On-the-fly system is necessary for large-area laser processing of uniform quality. It is developed a MOTF(Marking On-The-Fly) board for synchronizing the stage and scanner. And it is introduced the change of the error due to the change of parameters and algorithm for large-area laser processing. This algorithm automatically generates stage path and a velocity profile using acceleration and deceleration parameters. Since this method doesn't use a G-code, even if without expert knowledge, it has an advantage that can be accessed easily. Angle of one of the square of $350{\times}350mm$ was changed from $50^{\circ}$ to $80^{\circ}$ and analyzed the error corresponding to the value of Ta. It is calculated the value of Ta of the best with a precision of 20um through measurement of accuracy according to the Ta of each angle near the edge.