TY - JOUR
T1 - Reconditioning of diamond dicing blades via electrolytic dressing
AU - Chen, Shun Tong
AU - Guo, Jin Ping
N1 - Publisher Copyright:
© 2022 Elsevier B.V.
PY - 2023/1
Y1 - 2023/1
N2 - In this study, the process of “co-axial rotational electrolytic dressing reclaiming” is proposed to explore the possibility of reclaiming an electroformed diamond dicing blade by dressing, and thinning. The dicing blade was rotated slowly in an electrolysis tank controlled by a negative plate design and electrolysis conditions. The nickel atoms on the dicing blade surface were gradually and evenly dissolved and the grinding debris in the chip pockets were able to escape effortlessly, thus exposing fresh diamond grains. Whether dressing or thinning, the time required was only about 300 s, and the dicing blade was restored to an equivalent grinding force. After dressing, grinding current was reduced from 0.82 A to 0.21 A, increasing grinding length by at least 5.5 m, while die edge chipping was very little. It was also experimentally proven that thinning reduces the width of the grinding lane from 66 µm to 45 µm and extended the length of grinding up to an additional 4.5 m. The experiments showed that dressing and thinning with high-accuracy and -concentricity could be rapidly realized even for a very thin dicing blade, since there was no mechanical or thermal stress. This proves that ‘co-axial rotational electrolytic dressing reclaiming’ facilitates rapid reclaiming of an electroformed diamond dicing blade without deformation. It prolongs service life and produces narrower lanes between dies.
AB - In this study, the process of “co-axial rotational electrolytic dressing reclaiming” is proposed to explore the possibility of reclaiming an electroformed diamond dicing blade by dressing, and thinning. The dicing blade was rotated slowly in an electrolysis tank controlled by a negative plate design and electrolysis conditions. The nickel atoms on the dicing blade surface were gradually and evenly dissolved and the grinding debris in the chip pockets were able to escape effortlessly, thus exposing fresh diamond grains. Whether dressing or thinning, the time required was only about 300 s, and the dicing blade was restored to an equivalent grinding force. After dressing, grinding current was reduced from 0.82 A to 0.21 A, increasing grinding length by at least 5.5 m, while die edge chipping was very little. It was also experimentally proven that thinning reduces the width of the grinding lane from 66 µm to 45 µm and extended the length of grinding up to an additional 4.5 m. The experiments showed that dressing and thinning with high-accuracy and -concentricity could be rapidly realized even for a very thin dicing blade, since there was no mechanical or thermal stress. This proves that ‘co-axial rotational electrolytic dressing reclaiming’ facilitates rapid reclaiming of an electroformed diamond dicing blade without deformation. It prolongs service life and produces narrower lanes between dies.
KW - Die separation
KW - Electrolytic dressing
KW - Electrolytic thinning
KW - Wheel tool reclaiming
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U2 - 10.1016/j.jmatprotec.2022.117801
DO - 10.1016/j.jmatprotec.2022.117801
M3 - Article
AN - SCOPUS:85140432630
SN - 0924-0136
VL - 311
JO - Journal of Materials Processing Technology
JF - Journal of Materials Processing Technology
M1 - 117801
ER -