High Accurate Robotic Machining based on Absolute Part Measuring and On-Line Path Compensation

2019 International Conference on Electrical Drives & Power Electronics (EDPE) Pub Date : 2019-09-01 DOI:10.1109/EDPE.2019.8883912

Tomas Kubela, Ales Pochyly, V. Singule

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引用次数: 4

Abstract

Industrial 6 DOF robots is a platform for various machining processes due to its universality. A machining robot can perform any type of movement in space, the working space is relatively large and can be even extended based on a linear track (7th axis of the robot). Robotic milling is also a flexible and easily reconfigurable system and compared to conventional CNC machines, it is also a cost-saving alternative. However, there is still one main limitation concerned with a lower absolute robot accuracy, in comparison with CNC machines, caused mainly by a lower stiffness of the robot's serial kinematics and/or a backlash error resulting from robot's drives reversion. In this paper, we mostly present experimental results (milling) in order to demonstrate real limitations of robotic machining based on a Leica Laser Tracker system and a measuring arm CimCore. There is also described an approach for online robot path compensation based on the Laser Tracker absolute measurements in real-time where we reached the accuracy of finished products to be from tenths of mm to hundreds of mm.

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基于绝对零件测量和在线路径补偿的高精度机器人加工

工业六自由度机器人具有通用性，是实现各种加工工艺的平台。加工机器人可以在空间中进行任何类型的运动，工作空间相对较大，甚至可以基于线性轨迹(机器人的第7轴)进行扩展。机器人铣削也是一种灵活且易于重新配置的系统，与传统的数控机床相比，它也是一种节省成本的选择。然而，与数控机床相比，仍然存在一个主要的限制，即机器人的绝对精度较低，这主要是由机器人的串行运动学和/或机器人驱动器反转引起的间隙误差的较低刚度引起的。在本文中，我们主要展示了实验结果(铣削)，以证明基于徕卡激光跟踪系统和测量臂CimCore的机器人加工的真正局限性。还描述了一种基于激光跟踪仪实时绝对测量的在线机器人路径补偿方法，我们达到了成品精度从十分之一毫米到数百毫米。

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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2019 International Conference on Electrical Drives & Power Electronics (EDPE)

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