Micromachines (Dec 2023)

Investigation of Surface Integrity Induced by Ultra-Precision Grinding and Scratching of Glassy Carbon

  • Kirk Jahnel,
  • Robert Michels,
  • Dennis Patrick Wilhelm,
  • Tim Grunwald,
  • Thomas Bergs

DOI
https://doi.org/10.3390/mi14122240
Journal volume & issue
Vol. 14, no. 12
p. 2240

Abstract

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Glassy carbon provides material characteristics that make it a promising candidate for use as a mould material in precision glass moulding. However, to effectively utilize glassy carbon, a thorough investigation into the machining of high-precision optical surfaces is necessary, which has not been thoroughly investigated. This research analyses the process of material removal and its resulting surface integrity through the use of nano-scratching and ultra-precision grinding. The nano-scratching process begins with ductile plastic deformation, then progresses with funnel-shaped breakouts in the contact zone, and finally concludes with brittle conchoidal breakouts when the cutting depth is increased. The influence of process factors and tool-related parameters resulting from grinding has discernible impacts on the ultimate surface roughness and topography. Enhancing the cutting speed during cross-axis kinematic grinding results in improved surface roughness. Increasing the size of diamond grains and feed rates leads to an increase in surface roughness. An achievable surface roughness of Ra < 5 nm together with ductile-regime grinding behaviour meet optical standards, which makes ultra-precision grinding a suitable process for optical surface generation.

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