Research on processing technology of grinding aspheric workpiece in the five-axis machine tool

Q3 Engineering

International Journal of Nanomanufacturing Pub Date : 2020-04-07 DOI:10.1504/ijnm.2020.10028301

Liu Jianfeng, Lin Sun, Changsheng Li, Xingyuan Long, Xudong Fang, Chen Zhaoxiang, Zhuangde Jiang

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引用次数: 1

Abstract

Aspheric optical components have been widely used recently because of their unique advantages. Thus, it is necessary to investigate processing technology of such aspheric parts. In this paper, an aspherical mirror is ground with cup wheel in five-axis computer numerical control (CNC) machine tool and corresponding processes were investigated. To improve machining efficiency and reduce tool wear, the workpiece is firstly ground to be a spherical mirror, and then it is ground to be the aspheric contour. The best fitting spherical mathematical equation is derived by the axisymmetric quadratic aspheric generatrix equation. A ∅90 mm aspheric mirror was ground with cup wheel with five-axis computer numerical control (CNC) machine tool. The aspheric curve is processed into a paraboloid shape. The experimental results show that the surface profile of the aspherical lens is consistent with the designed profile, and the peak value (PV) value of the error is 4.77μm. Such results can be accepted in consideration of working allowance for polishing. According to the experimental results, the cause of the error was analysed and methods for improving precision were proposed.

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五轴机床磨削非球面工件的加工工艺研究

非球面光学元件以其独特的优点得到了广泛的应用。因此，有必要对此类非球面零件的加工工艺进行研究。研究了在五轴数控机床上用杯形砂轮磨削非球面反射镜的工艺过程。为提高加工效率和减少刀具磨损，将工件先磨削成球面反射镜，再磨削成非球面轮廓。利用轴对称二次非球面母线方程推导出最佳拟合的球面数学方程。采用五轴数控机床采用杯形砂轮磨削φ 90 mm非球面镜。将非球面曲线加工成抛物面形状。实验结果表明，非球面透镜的表面轮廓与设计轮廓一致，误差的峰值PV值为4.77μm。考虑到抛光的工作余量，这样的结果是可以接受的。根据实验结果，分析了误差产生的原因，提出了提高精度的方法。

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来源期刊

International Journal of Nanomanufacturing Engineering-Industrial and Manufacturing Engineering

CiteScore

0.60

自引率

0.00%

发文量