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基于模板的电泳辅助微超声加工微通道机床的设计及其加工实验

Design of a Template-Based Electrophoretically Assisted Micro-Ultrasonic Machining Micro-Channel Machine Tool and Its Machining Experiment.

作者信息

Lian Haishan, Zhang Linpeng, Chen Xiaojun, Deng Cuiyuan, Mo Yuandong

机构信息

School of Mechanical and Electrical Engineering, Lingnan Normal University, Zhanjiang 524048, China.

School of Mechanical and Electrical Engineering, Guangdong University of Technology, Guangzhou 510006, China.

出版信息

Micromachines (Basel). 2023 Jun 30;14(7):1360. doi: 10.3390/mi14071360.

DOI:10.3390/mi14071360
PMID:37512671
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10386278/
Abstract

In order to achieve the high-precision and high-efficiency machining of micro-channels for hard and brittle materials, the authors innovatively proposed a new technology called template-based electrophoretically assisted micro-ultrasonic machining (TBEPAMUSM). This technology transfers the micro-channel shape punch-pin to the workpiece material through micro-ultrasonic machining to form a micro-channel. At the same time, it uses the electrophoretic properties of ultra-fine abrasive particles to ensure the existence of abrasive particles in the machining area by applying a DC electric field. According to the new technology machining principle, a machine tool of TBEPAMUSM was designed and developed. The machine tool hardware adopts a C-shaped structure, including a marble platform, an ultrasonic vibration system, a micro three-dimensional motion platform, a working fluid tank, and a pressure sensor. The machine tool intelligent control system is developed based on LabVIEW, including the initialization module, fast positioning module, constant force tool setting module, constant force control machining module, and real-time coordinate display module. Micro-channels with different structures are machined on single-crystal silicon and soda-lime glass using the designed machine tool and the developed control system. The results show that: when electrophoresis assistance is applied in machining, the edge chipping phenomenon of the micro-channel is significantly reduced, the surface roughness is reduced by about 20%, and the machining efficiency is increased by about 4%.

摘要

为实现硬脆材料微通道的高精度、高效率加工,作者创新性地提出了一种基于模板的电泳辅助微超声加工(TBEPAMUSM)新技术。该技术通过微超声加工将微通道形状冲针转移到工件材料上形成微通道。同时,利用超细磨粒的电泳特性,通过施加直流电场确保加工区域内磨粒的存在。根据新技术加工原理,设计开发了一台TBEPAMUSM机床。机床硬件采用C形结构,包括大理石平台、超声振动系统、微三维运动平台、工作液箱和压力传感器。机床智能控制系统基于LabVIEW开发,包括初始化模块、快速定位模块、恒力对刀模块、恒力控制加工模块和实时坐标显示模块。利用所设计的机床和开发的控制系统在单晶硅和钠钙玻璃上加工了不同结构的微通道。结果表明:加工中施加电泳辅助时,微通道的边缘崩裂现象显著减少,表面粗糙度降低约20%,加工效率提高约4%。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5707/10386278/0e8b5ccdc557/micromachines-14-01360-g017.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5707/10386278/85fd127347e3/micromachines-14-01360-g019.jpg
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