多丸片固着磨料研磨高精密光学元件的参数优化

为了增强固结磨料研磨去除的可控性和确定性，提高光学元件的研磨加工精度和效率，以高精度光学元件为研究对象，分析了行星转动加工方式的多丸片固结磨料研磨的去除特性及参数优化。首先基于Preston方程分析了在研磨接触区域的相对速度、接触时间，并在利用ANSYS求得应力分布规律的基础上建立了多丸片固结磨料研磨的材料去除函数模型；引入趋近因子概念，通过对比去除函数归一化图形，对6种抛光盘模型的运动偏心比和速度比参数进行了优化，获得了多丸片固结磨料抛光盘的最大去除深度和去除量。

Parameter optimization for multi-distribution fixed abrasive pellets used in the grinding of high precision optical components

In order to enhance the controllability of fixed abrasive grinding, we propose a new way of grinding high precision optical components with multi-distribution fixed abrasive diamond pellets leading to improved precision and efficiency of the grinding of these components. The process is based on the Preston equation, and involves an analysis of the relative velocity and contact time in the grinding contact area. After acquiring the stress distribution by means of the mechanical simulation software ANSYS, a multi-distribution fixed abrasive pellet grinding model was constructed. The eccentricity ratio and velocity ratio were optimized for six different models by introducing the concept of a reaching factor and comparison with the normalized plot of the removal function. We were able to obtain values of the removal depth and the maximum amount of multi-distribution fixed abrasive pellets. These results provide a theoretical basis for the application and promotion of fixed abrasive pellets in fixed abrasive technology, which should lead to improved efficiency in the grinding of high precision optical components.