Actuator design for vibration assisted machining of high performance materials with ultrasonically modulated cutting speed

Philipp M. Rinck, Sebastian Sitzberger, M. F. Zaeh
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引用次数: 5

Abstract

In vibration assisted machining, an additional high-frequency oscillation is superimposed on the kinematics of the conventional machining process. This generates oscillations on the cutting edge in the range of a few micrometers, thereby causing a high-frequency change in the cutting speed or the feed. Consequently, a reduction of cutting forces, an increase of the tool life as well as an improvement of the workpiece quality can be achieved. In milling and grinding it has been shown that these effects are already partially present in the case of a vibration excitation in axial direction relative to the workpiece, which is perpendicular to the cutting direction. Further improvements of the process results can be achieved by superimposing a vibration in cutting direction and thus modifying the cutting speed at high frequency. The presented work shows the design of an ultrasonic actuator that enables vibration-assisted milling and grinding with ultrasonically modulated cutting speed. The actuator system superimposes a longitudinal torsional ultrasonic oscillation to the milling or grinding tool. It uses a bolt clamped Langevin transducer and a helically slotted horn, which degenerates the longitudinal vibration into a combined longitudinal torsional (L-T) vibration at the output surface. A finite element analysis is used to determine the vibration resonance frequency and mode shapes to maximize the torsional output. Afterwards, the simulation has been experimentally validated.
用于超声调制切削速度的高性能材料振动辅助加工的驱动器设计
在振动辅助加工中,一个附加的高频振荡叠加在传统加工过程的运动学上。这在切削刃上产生几微米范围内的振荡,从而引起切削速度或进给的高频变化。因此,可以减少切削力,增加刀具寿命以及改善工件质量。在铣削和磨削中,已经表明,在相对于工件垂直于切削方向的轴向振动激励的情况下,这些影响已经部分存在。通过在切削方向上叠加振动,从而在高频处改变切削速度,可以进一步改善加工结果。所提出的工作展示了超声驱动器的设计,使振动辅助铣削和磨削超声调制的切割速度。执行器系统将纵向扭转超声振荡叠加到铣削或磨削工具上。它采用螺栓夹紧的朗格万换能器和螺旋开槽的喇叭,在输出表面将纵向振动退化为组合纵向扭转(L-T)振动。采用有限元分析确定振动共振频率和模态振型,使扭转输出最大化。然后,对仿真结果进行了实验验证。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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