TY - JOUR
T1 - Microgroove grinding of monocrystalline diamond using medium-frequency vibration-assisted grinding with self-sensing grinding force technique
AU - Chen, Shun Tong
AU - Chen, Yuan Yu
N1 - Publisher Copyright:
© 2020 Elsevier B.V.
PY - 2020/8
Y1 - 2020/8
N2 - This study presents an approach to extra-hard material removal using “medium-frequency vibration-assisted grinding with self-sensing grinding force” for producing a microgroove array on monocrystalline diamond (MCD). Vibration mode at nano-amplitude is employed to vibrate the MCD workpiece against the polycrystalline composite diamond (PCD) wheel-tool during grinding. This approach is used to break the covalent atomic bonds of diamond, creating a “nanocracked subsurface layer” thereby reducing grinding resistance during material removal. The PZT stage's grinding system is designed with a low center of gravity, bilateral symmetry, and an in-situ co-shaft grinding devise. This setup provides a well-defined nanoscale depth of grinding. Expentmental results show that a highly consistent, smooth crisscross microgroove array can be successfully produced on MCD with no apparent burrs and chipping. It is confirmed that “medium-frequency vibration-assisted grinding with self-sensing grinding force” remarkably reduces grinding resistance and improves the surface finish on a MCD workpiece. In addition, these experiements prove that diamond's innate charateristic of “thin-brittle resistance” self-generates a “nanocrack growth resistance boundary” stopping further crack expansion. Using a “self-sensing grinding force” design allows the system to determine whether the “nanocracked subsurface layer” has been completely removed. This ensures high quality grinding, which produces a flat, solid microgroove surface on MCD. Furthermore, detailed discussions are conducted for the following aspects: effects of dressing using spark erosion, influences of amplitude and grinding mode, geometry and topography of microgrooves, PCD wheel tool wear, and an assesment criterion for available nasal-tip radius.
AB - This study presents an approach to extra-hard material removal using “medium-frequency vibration-assisted grinding with self-sensing grinding force” for producing a microgroove array on monocrystalline diamond (MCD). Vibration mode at nano-amplitude is employed to vibrate the MCD workpiece against the polycrystalline composite diamond (PCD) wheel-tool during grinding. This approach is used to break the covalent atomic bonds of diamond, creating a “nanocracked subsurface layer” thereby reducing grinding resistance during material removal. The PZT stage's grinding system is designed with a low center of gravity, bilateral symmetry, and an in-situ co-shaft grinding devise. This setup provides a well-defined nanoscale depth of grinding. Expentmental results show that a highly consistent, smooth crisscross microgroove array can be successfully produced on MCD with no apparent burrs and chipping. It is confirmed that “medium-frequency vibration-assisted grinding with self-sensing grinding force” remarkably reduces grinding resistance and improves the surface finish on a MCD workpiece. In addition, these experiements prove that diamond's innate charateristic of “thin-brittle resistance” self-generates a “nanocrack growth resistance boundary” stopping further crack expansion. Using a “self-sensing grinding force” design allows the system to determine whether the “nanocracked subsurface layer” has been completely removed. This ensures high quality grinding, which produces a flat, solid microgroove surface on MCD. Furthermore, detailed discussions are conducted for the following aspects: effects of dressing using spark erosion, influences of amplitude and grinding mode, geometry and topography of microgrooves, PCD wheel tool wear, and an assesment criterion for available nasal-tip radius.
KW - Medium-frequency vibration-assisted grinding
KW - Nanocrack growth resistance boundary
KW - Nanocracked subsurface layer
KW - Self-sensing grinding force
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U2 - 10.1016/j.jmatprotec.2020.116686
DO - 10.1016/j.jmatprotec.2020.116686
M3 - Article
AN - SCOPUS:85083183478
SN - 0924-0136
VL - 282
JO - Journal of Materials Processing Technology
JF - Journal of Materials Processing Technology
M1 - 116686
ER -