The geometric errors and structural thermal deformation are factors that influence the machining accuracy of Computer Numerical Control (CNC) machining center. Therefore, researchers pay attention to thermal error compensation technologies on CNC machine tools. Some real-time error compensation techniques have been successfully demonstrated in both laboratories and industrial sites. The compensation results still need to be enhanced. In this research, the neural-fuzzy theory has been conducted to derive a thermal prediction model. An IC-type thermometer has been used to detect the heat sources temperature variation. The thermal drifts are online measured by a touch-triggered probe with a standard bar. A thermal prediction model is then derived by neural-fuzzy theory based on the temperature variation and the thermal drifts. A Graphic User Interface (GUI) system is also built to conduct the user friendly operation interface with Insprise C++ Builder. The experimental results show that the thermal prediction model developed by neural-fuzzy theory methodology can improve machining accuracy from 80 mum to 3 mum. Comparison with the multi-variable linear regression analysis the compensation accuracy is increased from +/-10 mum to +/-3 mum.
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机译:几何误差和结构热变形是影响计算机数控(CNC)加工中心加工精度的因素。因此,研究人员关注数控机床的热误差补偿技术。一些实时误差补偿技术已在实验室和工业现场成功演示。补偿结果仍然需要增强。在这项研究中,已经进行了神经模糊理论来推导热预测模型。 IC型温度计已用于检测热源温度变化。热漂移可以通过带有标准杆的触发式探针在线测量。然后,基于温度变化和热漂移,通过神经模糊理论导出热预测模型。还构建了图形用户界面(GUI)系统,以使用Insprise C ++ Builder进行用户友好的操作界面。实验结果表明,采用神经模糊理论方法建立的热预测模型可以将加工精度从80μm提高到3μm。与多变量线性回归分析相比,补偿精度从+/- 10微米增加到+/- 3微米。
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