An error compensation method for multi-axis machining based on the actual contour measurement

2011 IEEE International Symposium on Assembly and Manufacturing (ISAM) Pub Date : 2011-05-25 DOI:10.1109/ISAM.2011.5942318

Xuewei Li, K. Cao, Wanhua Zhao, B. Lu, Jun Zhang

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引用次数: 2

Abstract

With the application of compensation for geometric error and thermal error, static and quasi-static accuracy of machine tools are significantly improved. Whereas, the accompanied disadvantage is the increased motion control error, especially the motion control accuracy in high-speed and ultra high-speed machining. Based on the actual contour measurement and the study of different control strategies for improving contour machining accuracy, this paper proposes an error compensation method for multi-axis machining. To be specific, a contour error model with different input parameters of the machining process needs to be built, and afterwards to be implemented into an open computer numerical control (CNC) system for real time calculation and compensation. Employing a 2-aix machine tool and base on aforementioned method, circular processing experiments with feed rates ranging from 0.5m/min to 10m/min and radiuses ranging from 10mm to 60mm are performed. The range of average radius error is reduced from 0.1mm to 0.006mm. The results demonstrate that high contour accuracy can be maintained even at high speed machining.

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一种基于实际轮廓测量的多轴加工误差补偿方法

通过对几何误差和热误差进行补偿，可以显著提高机床的静态和准静态精度。然而，伴随而来的缺点是运动控制误差增大，特别是在高速和超高速加工中运动控制精度增大。在实际轮廓测量的基础上，研究了提高轮廓加工精度的不同控制策略，提出了一种多轴加工误差补偿方法。具体而言，需要建立具有不同加工过程输入参数的轮廓误差模型，然后将其实现到开放式计算机数控(CNC)系统中进行实时计算和补偿。利用2-aix机床，在上述方法的基础上，进行了进给量为0.5m/min ~ 10m/min，半径为10mm ~ 60mm的圆加工实验。平均半径误差范围由0.1mm减小到0.006mm。结果表明，在高速加工条件下仍能保持较高的轮廓精度。

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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2011 IEEE International Symposium on Assembly and Manufacturing (ISAM)

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