TY - JOUR
T1 - Development of a grindingdrilling technique for holing optical grade glass
AU - Chen, Shun Tong
AU - Jiang, Zong Han
AU - Wu, Yi Ying
AU - Yang, Hong Ye
N1 - Funding Information:
The authors would like to thank the National Science Council of the Republic of China, Taiwan , for financially supporting this study under Contract no. NSC-98-2221-E-003-002- . A portion of this work is supported by KINIK COMPANY Ltd. Their assistance is gratefully acknowledged.
PY - 2011/2
Y1 - 2011/2
N2 - This study presents the development of a grindingdrilling technique for an innovative bench-top drill that combines micro-EDM with grinding and drilling to fabricate micro-holes in optical grade glass. Firstly, a novel diamond-tool, made with copper-based sintered alloy, is designed and fabricated on-line into a harbor-shaped structure with a hollow shaft and negative back rake-angles. Constructed reverse co-centric micro-hole EDM-drilling and reverse w-EDM facilitate on-line machining of the diamond-tool, which can then be directly utilized to drill micro-holes in optical glass and quartz. Application of a load-cell that detects the drilling force in real-time, providing feedback for fine tuning the feed-rate of the tool is proposed. Experimental results show that excellent geometric and dimensional accuracy of micro-holes can be achieved. The estimated reasonable tool life is determined at a machining number of 30 times. The proposed grindingdrilling technique is simple, cost effective, and can significantly contribute to the precision micromachining industry.
AB - This study presents the development of a grindingdrilling technique for an innovative bench-top drill that combines micro-EDM with grinding and drilling to fabricate micro-holes in optical grade glass. Firstly, a novel diamond-tool, made with copper-based sintered alloy, is designed and fabricated on-line into a harbor-shaped structure with a hollow shaft and negative back rake-angles. Constructed reverse co-centric micro-hole EDM-drilling and reverse w-EDM facilitate on-line machining of the diamond-tool, which can then be directly utilized to drill micro-holes in optical glass and quartz. Application of a load-cell that detects the drilling force in real-time, providing feedback for fine tuning the feed-rate of the tool is proposed. Experimental results show that excellent geometric and dimensional accuracy of micro-holes can be achieved. The estimated reasonable tool life is determined at a machining number of 30 times. The proposed grindingdrilling technique is simple, cost effective, and can significantly contribute to the precision micromachining industry.
KW - Grindingdrilling technique
KW - Reverse co-centric micro-hole EDM-drilling
KW - Reverse micro-EDM
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U2 - 10.1016/j.ijmachtools.2010.12.001
DO - 10.1016/j.ijmachtools.2010.12.001
M3 - Article
AN - SCOPUS:78650713767
SN - 0890-6955
VL - 51
SP - 95
EP - 103
JO - International Journal of Machine Tools and Manufacture
JF - International Journal of Machine Tools and Manufacture
IS - 2
ER -