基于参数映射的叶轮粗加工椭圆摆线轨迹优化

doi:10.3969/j.issn.1004-132X.2024.03.006

摘要/Abstract

摘要： 为了提高复杂曲面叶轮流道开槽加工效率，提出了一种曲面粗加工摆线轨迹规划方法。首先确定流道的可加工区域并进行参数化;然后在该参数域建立以最小加工时间为优化目标的椭圆摆线轨迹关键参数的数学模型，通过区间缩小法求解出满足加工要求的最佳椭圆短半轴长度与行距，从而获得参数域摆线轨迹;最后将参数域的轨迹映射至物理域来获取走刀路径。为了验证所提轨迹规划方法的高效性和有效性，以某叶轮为对象，计算了流道椭圆摆线开粗加工轨迹，并将所提方法的计算时间与传统行切法轨迹计算时间进行对比，发现计算效率提高了19.4%。此外，摆线流道开粗和行切法流道开粗的仿真加工对比结果证明，相同参数设置下所提方法的加工效率比传统行切法的加工效率高22.4%。实际摆线铣削开粗结果表明，叶轮流道切痕形状与摆线轨迹一致，表面残留满足粗加工要求，证明所提方法是有效可行的。

关键词: 参数映射, 叶轮流道, 椭圆摆线, 刀具轨迹优化, 走刀路径

Abstract: In order to improve the opening groove processing efficiency of complex curved blade passages, a cycloid tool path planning method for surface rough machining was proposed. Firstly, the processable area of the passages was parameterized. Then, a mathematical model of key parameters for elliptical cycloid tool path, with the optimization goal of minimizing machining time, was established in the parameter domain. The best short-axis length of the ellipse and the cycloid step that satisfied the machining requirements were solved by the interval narrowing method, then the cycloid tool path could be determined in the parameter domain accordingly. Afterwards, the trajectory of the parameter domain was mapped to the physical domain to obtain the cutting path. Finally, the efficiency of the proposed trajectory planning method was evaluated with an example of calculation of elliptical cycloidal open rough machining trajectory for an impeller, whose calculation time is 19.4% faster than the traditional line cutting method. In addition, the simulation results of cycloidal channel opening and line cutting show that the machining efficiency of the proposed method is 22.4% higher than that of the traditional line cutting method under the same parameter setting. The practical results of cycloidal milling show that the shape of impeller runner cut is consistent with the cycloidal track, whose surface residue meets the rough machining requirements. This paper provides a new trajectory planning method for rough machining of impeller flow channels to improve the machining efficiency, which is a substitution for the traditional line cutting method.

Key words: parameter mapping, impeller channel, elliptical cycloid, tool path optimization, cutting path

中图分类号:

V263.11

韩飞燕, 顾志成, 赵一鹏, 张传伟. 基于参数映射的叶轮粗加工椭圆摆线轨迹优化[J]. 中国机械工程, 2024, 35(03): 438-444，456.

HAN Feiyan, GU Zhicheng, ZHAO Yipeng, ZHANG Chuanwei. Elliptic Cycloid Tool Path Optimization of Impeller Rough Machining Based on Parameter Mapping[J]. China Mechanical Engineering, 2024, 35(03): 438-444，456.

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