• Title/Summary/Keyword: Micro-Machining

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Micro Electrochemical Machining Using a Multi-Function Electrode (복합기능 전극을 이용한 미세 전해가공)

  • Shin, Hong-Shik;Kim, Bo-Hyun;Kim, Gyu-Man;Chung, Do-Kwan;Chu, Chong-Nam
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.33 no.5
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    • pp.496-501
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    • 2009
  • In micro electrochemical machining(micro-ECM), it is important to measure and control the potential of a tool electrode and a workpiece electrode because electrochemical reaction rate depends on the potential of the electrodes. When the electrode potential was measured against a reference electrode, the error of measured electrode potential could be minimized by proper tool electrode design. In this paper, multi-function electrodes consisting of a tool electrode and a reference electrode was fabricated by micro fabrication techniques. The machining conditions in micro-ECM using multi-function electrodes, such as pulse voltage parameters and electrode potential, were investigated.

Distortion of the Bottom Surface in Micro Cavity Machining Using MEDM (미세 캐비티 방전 가공에서 바닥면 형상 왜곡)

  • 임종훈;류시형;제성욱;주종남
    • Journal of the Korean Society for Precision Engineering
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    • v.20 no.12
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    • pp.191-197
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    • 2003
  • As mechanical components are miniaturized, the demand on micro die and mold is increasing. Micro mechanical components usually have high hardness and good conductivity. So micro electrical discharge machining (MEDM) is an effective way to machine those components. In micro cavity fabrication using MEDM, it is observed that the bottom surface of cavity is distorted. Electric charges tend to be concentrated at the sharp edge. At the center of the bottom surface, debris can not be drawn off easily. These two phenomena make the bottom surface of the electrode and workpiece distort. As machining depth increases, the distorted shape of electrode approaches hemisphere. This process is affected by capacitance and the size of electrode. By using a smaller electrode than the desired cavity size and appropriate tool movement, bottom shape distortion can be prevented.

Analysis of cutting characteristics in micro machining using cutting force coefficient (절삭력 계수를 통한 마이크로 가공의 절삭 특성 분석)

  • Lee H.U.;Cho D.W.;Park J.K.
    • Proceedings of the Korean Society of Machine Tool Engineers Conference
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    • 2005.05a
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    • pp.483-488
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    • 2005
  • The complex three-dimensional miniature components are needed for a wide range of applications from the aerospace to the biomedical industries. To manufacture these products, micro machining that can make a high aspect ratio part and has good accuracy is widely researched. In this paper, cutting characteristics were analyzed in micro machining using cutting force coefficients, which are the specific cutting force for normal and frictional direction of rake surface. From measured cutting force in micro end milling, cutting condition independent cutting force coefficients were determined and used for analysing the characteristics of micro cutting. Using the cutting force coefficient, 써써써.

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Distortion of the Bottom Surface in Micro Cavity Machining Using MEDM

  • Lim Jong Hoon;Je Sung Uk;Ryu Shi Hyoung;Chu Chong Nam
    • International Journal of Precision Engineering and Manufacturing
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    • v.6 no.4
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    • pp.44-48
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    • 2005
  • As mechanical components are miniaturized, the demands on micro die/mold are increasing. Micro mechanical components usually have high hardness and good conductivity. Micro electrical discharge machining (MEDM) can thus be an effective way to machine those components. In micro cavity fabrication using MEDM, it is observed that the bottom surface of the cavity is distorted. Electric charges tend to be concentrated at the sharp edge, and debris cannot be drawn off easily at the center of the bottom surface. These two phenomena make the bottom surface of electrode and workpiece distort. As machining depth increases, the distorted shape of the electrode approaches hemisphere. This process is affected by both capacitance and the size of electrode. By using a smaller electrode than the desired cavity size and appropriate tool movement, bottom shape distortion can be prevented.

Element Technology of the Ultra-Precision Machine Tools for Machining the Large Surface Micro Features (대면적 미세형상 복합 가공기의 요소기술)

  • Song C.K.;Park C.H.;Hwang J.H.;Kim B.S.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.10a
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    • pp.86-93
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    • 2005
  • In this paper, we discuss the merits of mechanical machining to generate micro features on large surfaces. An overseas technology trend related to the micro machining and dedicated machinery is also presented. We provide an overview of what characteristics the machinery is required to have to generate micro features on large surfaces and what kind of technical barriers need to be overcome to put the technology to practical use.

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A Study on the Electrochemical Micro-machining for Fabrication of Micro Grooves (미세 홈 형성을 위한 마이크로 전해가공에 관한 연구)

  • Park, Jeong-Woo;Lee, Eun-Sang;Moon, Young-Hun
    • Journal of the Korean Society for Precision Engineering
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    • v.19 no.4
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    • pp.101-108
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    • 2002
  • A specially-built EMM (Electrochemical Micro Machining) / PECM (Pulse Electrochemical Machining) cell, a electrode tool filled with non-conducting material, a electrolyte flow control system and a small & stable gap control unit are developed to achieve accurate dimensions of recesses. Two electrolytes, aqueous sodium nitrate and aqueous sodium chloridc arc applied in this study. The farmer electrolyte has better machine-ability than the latter one because of its appropriate changing to the transpassive state without pits on the surface of workpiece. It is easier to control the machining depth precisely by micrometer with pulse current than direct current. This paper also presents an identification method for the machining depth by in-process analysis of machining current and inter electrode gap size. The inter electrode gap characteristics, inc1uding pulse current, effective volumetric electrochemical equivalent and electrolyte conductivity variations, are analyzed based on the model and experiments.

A Study on Compensation for tool deformation machining errors in micro end-milling (마이크로 엔드밀링에서 공구변형 가공오차 보상에 관한 연구)

  • Jong-In Son;Byeong-Uk Song
    • Design & Manufacturing
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    • v.17 no.4
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    • pp.24-32
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    • 2023
  • In this study, we introduce research aimed at minimizing machining errors without compromising productivity by compensating for the machining errors caused by tool deformation. Our approach experimentally establishes the direct correlation between cutting depth and machining error, and creates predictive models using mathematical functions. This method allows for the prediction of compensated cutting depths to obtain the desired cutting profiles, thereby maximizing the compensation of machining errors in the cutting process.

A Study on the Real-time Micro Control of WEDM Process for the Improvement of Discharging Stability (WEDM 프로세스의 방전 안정성 향상을 위한 실시간 미세제어에 관한 연구)

  • Kwon Shin;Nam Sung-Ho;Yang Min-Yang
    • Journal of the Korean Society for Precision Engineering
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    • v.22 no.4
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    • pp.27-36
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    • 2005
  • Some studies have shown that unstable factors are inherent in WEDM process, causing the instability of the discharging pulse to reach about 40∼60% in normal machining. Transient stability is an important subject in WEDM process since there is a close relationship between stability and machining performance, such as the characteristics of a machined surface, machining speed and problem of instability like wire rupture phenomenon. Among the many machining parameters affecting WEDM machining state, three specific parameters (Vr, Ip, off time ) are major controllable variables that can be applied in transient stability control. And, this research investigates the implementation and analysis of real-time micro control of the discharging stability of WEDM (Wire Electric Discharge Machining) process.

Machining Process for Micro Pyramid Pattern Mold (미세 피라미드 패턴 금형 가공공정 연구)

  • Je, T.J.;Shin, Y.J.;Lee, E.S.;Choi, D.S.;Hong, S.M.;Kang, Y.H.
    • Proceedings of the Korean Society for Technology of Plasticity Conference
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    • 2007.05a
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    • pp.55-59
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    • 2007
  • Technologies of super-precision micro pattern mold machining and high-performance optical films manufacturing using thereof forms the basis of recent display industries which have developed remarkably. Especially, it is the light guide plates and high luminous intensity prism sheets at BLU or FLU in LCD and lenses at virtual keyboard's display to be manufactured by micro machining technology. One way the industry requires to do that is by developing high-performance light guide plates or films which are existing light guide plates, diffusion films and luminance enhancement prism films all in one. In this research effort, basic processing of the micro pyramid structure by shaping method is proposed. Experiments of mold machining of pitch $20{\mu}m$ tetrahedral pyramid and pitch $100{\mu}m$ trihedral pyramid using a $90^{\circ}$ diamond tool were conducted to identify a variety of machining features, such as cutting forces, conditions of the surface, shapes of chips, and influence of materials.

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Micro Electrical Discharge Milling Using Deionized Water (탈이온수를 이용한 미세 방전 밀링)

  • Chung Do-Kwan;Chu Chong-Nam;Kim Bo-Hyun
    • Journal of the Korean Society for Precision Engineering
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    • v.23 no.3 s.180
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    • pp.69-75
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    • 2006
  • In this paper, micro electrical discharge milling using deionized water as dielectric fluid was investigated. In EDM, dielectric fluid is an important factor which affects machining characteristics. When deionized water was used as dielectric fluid, machining characteristics were investigated according to voltage, capacitance, and resistivity of deionized water. Machining gap increased with increasing voltage and capacitance. As the resistivity of deionized water decreased, the machining gap increased. The wear of a tool electrode and machining time can be reduced by using deionized water instead of EDM oil. Surface roughness was also improved when deionized water was used.