基于PZT激励同步压缩放电通道的微细电火花加工技术

›› 2013, Vol. 49 ›› Issue (9): 184-189.

基于PZT激励同步压缩放电通道的微细电火花加工技术

杜连明;张勤河;张建华;张亚

山东大学机械工程学院;济南大学机械工程学院;山东大学高效洁净机械制造教育部重点试验室

发布日期:2013-05-05

Discharge Channel Compressed Micro-EDM Techniques Based on PZT Excitation

DU Lianming;ZHANG Qinhe;ZHANG Jianhua;ZHANG Ya

School of Mechanical Engineering, Shandong University School of Mechanical Engineering, University of Jinan Key Laboratory of High Efficiency and Clean Mechanical Manufacture of Ministry of Education, Shandong University

Published:2013-05-05

摘要/Abstract

摘要： 针对微细电火花加工效率低，排屑困难，放电状态不稳定的问题，基于压电陶瓷(Piezoelectric ceramic, PZT)的逆压电效应，采用火花放电与PZT激励同步脉冲电源，提出PZT激励同步压缩放电通道的微细电火花加工的新方法。对其系统构成和加工原理进行了详细阐述，并结合试验对该加工系统的加工机理进行了分析，试验研究证明采用PZT同步压缩放电通道过程中能够改善放电间隙的状态，提高加工效率和加工质量，促进排屑，进而提高了微细电火花的加工稳定性。利用自行开发的加工系统成功加工出直径67 μm的微细孔，加工过程稳定，表明该技术在微细加工方面具有广阔的应用前景。

关键词: 同步压缩放电通道, 微细电火花, 压电陶瓷

Abstract: In micro-EDM, the debris generated in machining process is difficult to be moved from the discharging gap, the discharge state is instability, and the material removal rate is low. A new method of piezoelectric ceramic (PZT) incentive synchronous compression discharge channel micro-EDM is presented based on the inverse piezoelectric effect of PZT piezoelectric ceramics, using a spark discharge and PZT sync pulse power. The system composition and machining principles are described, and its machining mechanism is analyzed in terms of the experiments. By the experiments, it is certificated that on the process of PZT sync compressing discharge channel machining, the state of discharge gap, the machining efficiency and quality can be improved, the throw out of debris makes easier, and then the stability of micro-EDM process is raised. A micro-hold is produced diameter in 67 μm with stable machining process by using a self-developed machining system, which indicates that this new technology has wide application prospect in the field of micro manufacturing.

Key words: Discharge channel compressed, Micro-EDM, Piezoelectric ceramic

中图分类号:

TG661

杜连明;张勤河;张建华;张亚. 基于PZT激励同步压缩放电通道的微细电火花加工技术[J]. , 2013, 49(9): 184-189.

DU Lianming;ZHANG Qinhe;ZHANG Jianhua;ZHANG Ya. Discharge Channel Compressed Micro-EDM Techniques Based on PZT Excitation[J]. , 2013, 49(9): 184-189.

[1]	黄瑞宁, 熊小刚, 朱二磊. 基于液相电极的微细电火花加工方法研究[J]. 机械工程学报, 2019, 55(9): 176-182.
[2]	刘自超, 潘伟, 路长厚, 张永涛. 基于压电型薄膜式差动节流阀的静压主轴轴心轨迹理论研究与仿真^*[J]. 机械工程学报, 2016, 52(21): 71-77.
[3]	俞军涛;焦宗夏;吴帅. 基于液压微位移放大结构的新型压电陶瓷直接驱动阀设计及仿真[J]. , 2013, 49(2): 151-158.
[4]	付秀琢;张勤河;张建华;朱玉杰;包广华. 压电自适应微细电火花加工系统特性分析[J]. , 2011, 47(9): 164-168.
[5]	王光庆;沈润杰;郭吉丰. 压电陶瓷对超声波电动机定子特性的影响[J]. , 2010, 46(4): 8-14.
[6]	魏阳杰;吴成东;董再励. 基于亚像素图像块匹配方法的压电陶瓷驱动特性测量[J]. , 2010, 46(17): 151-158.
[7]	田桂中;侯丽雅;章维一. 数字化进退针装置的设计与试验[J]. , 2008, 44(10): 234-238.
[8]	陈立国;荣伟彬;汝长海;张国平;孙立宁. 基于电流控制的压电陶瓷驱动电源及其试验研究[J]. , 2006, 42(3): 179-183.
[9]	崔玉国;董维杰;孙宝元;杨志欣. 压电微动工作台的位移复合控制[J]. , 2006, 42(3): 156-161.
[10]	刘建芳;杨志刚;赵宏伟;程光明;刘国嵩. 内箝位型压电精密步进旋转驱动器[J]. , 2006, 42(11): 103-108.
[11]	狄士春;黄瑞宁;迟关心;赵万生. 微细电火花线切割加工关键技术[J]. , 2006, 42(1): 221-226.
[12]	党选举;谭永红. 在Preisach模型框架下的似对角动态神经网络压电陶瓷迟滞模型的研究[J]. , 2005, 41(4): 7-12.
[13]	张勇;王振龙;李志勇;杨洋;贾宝贤;胡富强;赵万生. 微细电火花加工装置关键技术研究[J]. , 2004, 40(9): 175-179.
[14]	刘曙;尹剑波;唐宏;王允韬;赵晓鹏. 自耦合电流变阻尼器及其性能[J]. , 2004, 40(4): 131-134.
[15]	张建军;高峰;陈玉龙;赵辉. 基于压电陶瓷驱动的并联微动机器人静力学及其微动平台的静刚度分析[J]. , 2004, 40(11): 82-87.