He Huang, Jicheng Bai, Zesheng Lu, Yongfeng Guo
.
DOI: 10.4236/jemaa.2009.12017   PDF    HTML     10,199 Downloads   19,109 Views   Citations

Abstract

High Speed Drilling Electrical Discharge Machining (HSDEDM) uses controlled electric sparks to erode the metal in a work-piece. Through the years, HSDEDM process has widely been used in high speed drilling and in manufacturing large aspect ratio holes for hard-to-machine material. The power supplies of HSDEDM providing high power applica-tions can have different topologies. In this paper, a novel Pulsed-Width-Modulated (PWM) half-bridge HSDEDM power supply that achieves Zero-Voltage-Switching (ZVS) for switches and Zero-Current-Switching (ZCS) for the dis-charge gap has been developed. This power supply has excellent features that include minimal component count and inherent protection under short circuit conditions. This topology has an energy conservation feature and removes the need for output bulk capacitors and resistances. Energy used in the erosion process will be controlled by the switched IGBTs in the half-bridge network and be transferred to the gap between the tool and work-piece. The relative tool wear and machining speed of our proposed topology have been compared with that of a normal power supply with current limiting resistances.

Keywords

High Speed Drilling Electrical Discharge Machining, Half-Bridge Power Supply, Zero Current Switching, Zero Voltage Switching

Share and Cite:

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	C. M. F. Odulio, L. G. Sison, and M. T. Escoto Jr, “Energy-saving flyback converter for EDM applications,” IEEE Region 10 Annual International Conference Proceedings, pp. 1-6, 2007.
[2]	N. L. Kachhara and K. S. Shah, “The electric discharge machining process.” Journal of the Institution of Engineers (India) -Mechanical Engineering Division, No. 51, pp. 67-73, 1971.
[3]	M. R. Cao, S. C. Yang, S. Q. Yang and Y. T. Qiao, “Experimental research on the process influencing machining velocity to small hole’s EDM,” Modem Manufacture Engineering (in Chinese), Vol. 4, pp. 82-83, 2005.
[4]	R. Casanueva, M. Ochoa, F. J. Azcondo, and S. Bracho, “Current mode controlled LCC resonant converter for electrical discharge machining applications,” Proceedings of the 2000 IEEE International Symposium on Industrial Electronics, Vol. 2, pp. 505-510, 2000.
[5]	G. Hua and F. C. Lee, “Soft-switching techniques in PWM converters,” IEEE Transactions on Industrial Electronics, Vol. 42, pp. 595-603, 1995.
[6]	K. Yoshida and T. Ninomiya, “A novel current resonant ZVS-PWM half-bridge converter,” Electronics & Communications in Japan, Part I: Communications, Vol. 82, pp. 45-55, 1999.
[7]	B. Sen, N. Kiyawat, P. K. Singh, S. Mitra, J. H. Ye, and P. Purkait, “Developments in electric power supply configurations for electrical-discharge-machining (EDM),” The 5th International Conference on Power Electronics and Drive Systems, Vol. 1, pp. 659-664, 2003.
[8]	B. Y. Song, W. S. Zhao, and G. L. Shao, “Current type of electrical discharge machining pulse generator,” China Mechanical Engineering (in Chinese), Vol. 12, pp. 386- 390, 2001.