Electrochemical oxidation assisted micromachining of glassy carbon substrate

Wonkyun Lee; Eunseok Nam; Chan Young Lee; Kyung In Jang; Byung Kwon Min

doi:10.1007/s12541-015-0057-6

Electrochemical oxidation assisted micromachining of glassy carbon substrate

Wonkyun Lee, Eunseok Nam, Chan Young Lee, Kyung In Jang, Byung Kwon Min

Department of Robotics and Mechatronics Engineering

Yonsei University

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Glassy carbon (GC) has merits to be used as mold material for glass molding press because of its superior chemical and thermal properties. However, it is difficult to machine GC mechanically because of its brittleness and hardness. Undesired fractures and cracks are frequently generated on the machined surfaces. A novel micromachining process for precision machining of GC that combines mechanical micromachining and electrochemical oxidation has been developed. In the proposed process, an oxide layer is generated on the GC surface and removed mechanically. In the contact area between the tool and workpiece, the generation and removal of the oxide layer are repeated. A number of experimental results are presented to investigate the machining characteristics and to show the feasibility of the proposed process.

Original language	English
Pages (from-to)	419-422
Number of pages	4
Journal	International Journal of Precision Engineering and Manufacturing
Volume	16
Issue number	3
DOIs	https://doi.org/10.1007/s12541-015-0057-6
State	Published - Mar 2015

Bibliographical note

Publisher Copyright:
© 2015, Korean Society for Precision Engineering and Springer-Verlag Berlin Heidelberg.

Keywords

Difficult-to-machine material
Hybrid machining
Non-traditional machining

Access to Document

10.1007/s12541-015-0057-6

Cite this

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title = "Electrochemical oxidation assisted micromachining of glassy carbon substrate",

abstract = "Glassy carbon (GC) has merits to be used as mold material for glass molding press because of its superior chemical and thermal properties. However, it is difficult to machine GC mechanically because of its brittleness and hardness. Undesired fractures and cracks are frequently generated on the machined surfaces. A novel micromachining process for precision machining of GC that combines mechanical micromachining and electrochemical oxidation has been developed. In the proposed process, an oxide layer is generated on the GC surface and removed mechanically. In the contact area between the tool and workpiece, the generation and removal of the oxide layer are repeated. A number of experimental results are presented to investigate the machining characteristics and to show the feasibility of the proposed process.",

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T1 - Electrochemical oxidation assisted micromachining of glassy carbon substrate

AU - Lee, Wonkyun

AU - Nam, Eunseok

AU - Lee, Chan Young

AU - Jang, Kyung In

AU - Min, Byung Kwon

PY - 2015/3

Y1 - 2015/3

N2 - Glassy carbon (GC) has merits to be used as mold material for glass molding press because of its superior chemical and thermal properties. However, it is difficult to machine GC mechanically because of its brittleness and hardness. Undesired fractures and cracks are frequently generated on the machined surfaces. A novel micromachining process for precision machining of GC that combines mechanical micromachining and electrochemical oxidation has been developed. In the proposed process, an oxide layer is generated on the GC surface and removed mechanically. In the contact area between the tool and workpiece, the generation and removal of the oxide layer are repeated. A number of experimental results are presented to investigate the machining characteristics and to show the feasibility of the proposed process.

AB - Glassy carbon (GC) has merits to be used as mold material for glass molding press because of its superior chemical and thermal properties. However, it is difficult to machine GC mechanically because of its brittleness and hardness. Undesired fractures and cracks are frequently generated on the machined surfaces. A novel micromachining process for precision machining of GC that combines mechanical micromachining and electrochemical oxidation has been developed. In the proposed process, an oxide layer is generated on the GC surface and removed mechanically. In the contact area between the tool and workpiece, the generation and removal of the oxide layer are repeated. A number of experimental results are presented to investigate the machining characteristics and to show the feasibility of the proposed process.

KW - Difficult-to-machine material

KW - Hybrid machining

KW - Non-traditional machining

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JO - International Journal of Precision Engineering and Manufacturing

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Electrochemical oxidation assisted micromachining of glassy carbon substrate

Abstract

Bibliographical note

Keywords

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