Friction wear test evaluation for assembly tool

2016 IEEE 18th Electronics Packaging Technology Conference (EPTC) Pub Date : 2016-11-01 DOI:10.1109/EPTC.2016.7861489

O. Ho, A. Yeo, T. H. Guan, Ng Lay Peng, C. Wai, Lum Chee Choong

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Abstract

Conventional method to define the useful tool life is by punching the actual molded units in trim and form (TNF) machine. Throughout the punch intervals, the punched leadframes were sent for inspection for any side burr observed at the leads. This process might take several days or weeks in order to reach the end of punch tool lifespan. It is quite a manual and time consuming task, if it involves several types of punch tool to be examined. Beside that, this method does not capture the wear rate of the punch tool. This paper demonstrates the friction wear test of punch tool to obtain the wear rate using Bruker Tribolab UMT tester, which is equipped with reciprocating drive. The punch tool is hold stationary at the carriage (z axis), and rub against the dummy molded unit, which oscillated by the reciprocating drive. The volume loss of the punch tool is plotted against the number of reciprocating cycles to determine the wear rate. The wear mode of the punch tool is investigated at end of the test. From the results of this study, it is shown that the punch tool's volume wear vs the reciprocating cycles fit well with the linear line. The wear rate of punch tool is calculated from the slope of the linear line.

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装配工具摩擦磨损试验评定

确定刀具使用寿命的传统方法是通过在切边成形(TNF)机床上冲压实际成型部件。在整个冲孔间隔中，冲孔引线框被送去检查引线处观察到的任何侧毛刺。这个过程可能需要几天或几周的时间才能达到冲床工具的使用寿命。这是一个相当手动和耗时的任务，如果它涉及到几种类型的冲床工具进行检查。除此之外，这种方法不能捕获冲床工具的磨损率。本文介绍了采用Bruker Tribolab UMT试验机对冲模进行摩擦磨损试验，获得冲模的磨损率。将冲床固定在小车(z轴)上，与假模组摩擦，假模组通过往复驱动振荡。冲床工具的体积损失是根据往复循环的次数绘制的，以确定磨损率。在试验结束时，研究了冲孔工具的磨损模式。研究结果表明，冲床体积磨损随往复周期的变化与直线曲线吻合较好。冲床刀具的磨损率由直线的斜率来计算。

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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2016 IEEE 18th Electronics Packaging Technology Conference (EPTC)

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