• Title/Summary/Keyword: GAC(Geometric Adaptive Control)

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Machine Tool Error Compensation by using Measuring Plates (측정플레이트를 이용한 공작기계 오차보정)

  • 양종태;정성종
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 1993.10a
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    • pp.187-192
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    • 1993
  • Thermal deformation causes large amount of machine tool errors. In order to compensate for thermal and geometric errors of the machine tool an off-line geometric adaptive control (GAC) scheme was developed. THe GAC method was realized by using a measuring plate made of precision spheres. Error vectors and volumetric errors were measured by the measuring plate. Error compensation models were obtained from error vectors and a kinematic chain of machine tools. Reliability of the GAC system of thermal and geometric errors were confrimed by large amount of experiments.

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Development of Shaft Straightening Machine with Springback Observer (스프링백 관측기를 이용한 축교정기 개발)

  • 안중용
    • Journal of the Korean Society of Manufacturing Technology Engineers
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    • v.5 no.3
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    • pp.22-30
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    • 1996
  • In order to compensate for out-of-straightness of shafts, an automatic straightening process composed of an automatic measuring module, an automatic control unit and operating softwares was developed with a hydraulic press. The out-of-sraightness of each shaft was measured automatically in the measuring stage. An optimal pressure point was determined to minimize TIR value of the shaft according to press count of 3-points bending process. In the geometric adaptive control procedure, punch stroke and springback of the shaft were predicted by an observer using on-line measured values of press force and deflection amount I each press count. An automatic straightening machine was realized with the measuring module, the GAC module, PLD, IBM-PC and the operating software on the hydraulic press. the validity of the proposed straightening process was confirmed through a series of experiments with cam shafts.

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보상 제어의 정밀공학에의 응용

  • 문의준
    • Journal of the KSME
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    • v.24 no.6
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    • pp.422-427
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    • 1984
  • 최근의 높은 생산성을 향한 NC 혹은 CNC 공작기계를 이용한 기계가공의 자동화 및 작업 공간 내부에서의 오차측정이라는 시대적 조류와 함께, 기계가공 오차의 보상 제어, 혹은 형상 및 치 수의 적응 제어(Geometric Adaptive Control, GAC)는 이미 여러 선진국가에서 주목을 받아 왔고, 병기 공학을 포함한 여러 분야에서 정밀도의 향상에 대한 요구는 높아만 가고 있어 이 방향에 대한 계속적인 연구가 요망된다. 더군다나 전자 및 광전자적인 계측 제어 기구의 발달과, 저렴 하고 높은 성능의 마이크로 컴퓨터의 등장으로 GAC를 통한 정밀도 향상은 더욱 가능하여졌다.

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Identification of guideway errors in the end milling machine using geometric adaptive control algorithm (기하학적 적응제어에 의한 엔드밀링머시인의 안내면 오차 규명)

  • 정성종;이종원
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.12 no.1
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    • pp.163-172
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    • 1988
  • An off-line Geometric Adaptive Control Scheme is applied to the milling machine to identify its guideway errors. In the milling process, the workpiece fixed on the bed travels along the guideway while the tool and spindle system is fixed onto the machine. The scheme is based on the exponential smoothing of post-process measurements of relative machining errors due to the tool, workpiece and bed deflections. The guideway error identification system consists of a gap sensor, a, not necessarily accurate, straightedge, and the numerical control unit. Without a priori knowledge of the variations of the cutting parameters, the time-varying parameters are also estimated by an exponentially weighted recursive least squares method. Experimental results show that the guideway error is well identified within the range of RMS values of geometric error changes between machining passes disregarding the machining conditions.

Adaptive Control of End Milling Machine to Improve Machining Straightness (직선도 개선을 위한 엔드밀링머시인 의 적응제어)

  • 김종선;정성종;이종원
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.9 no.5
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    • pp.590-597
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    • 1985
  • A recursive geometric adaptive control method to compensate for machining straightness error in the finished surface due to tool deflection and guideway error generated by end milling process is developed. The relationship between the tool deflection and the feedrate is modeled by a modified Taylor's tool life equation. Without a priori knowledge on the variations off cutting parameters, time varying parameters are then estimated by an exponentially windowed recursive least squares method with only post-process measurements of the straightness error. The location error is controlled by shifting the milling bed in the direction perpendicular to the finished surface and adding a certain amount of feedrate with respect to the tool deflection model before cutting. The waviness error is compensated by adjusting the feedrate during machining. Experimental results show that location error is controlled within a range of fixturing error of the bed on the guideway and that about 60% reduction in the waviness error can be achieved within a few steps of parameter adaption under wide operating ranges of cutting conditions even if the parameters do not converge to fixed values.