基于包络近似法的非滚珠刀具带宽-最大值雕刻表面制造优化刀具运动对称性

Symmetry Pub Date : 2024-09-13 DOI:10.3390/sym16091207
Kaihong Zhou, Haixu Liu, Shu Li
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引用次数: 0

摘要

将使用非球头铣刀通过带宽最大化加工复杂曲面的问题表述为一种曲面拟合问题,其中刀具曲面包络特征线近似于运动变换下的设计曲面。提出了曲面包络逼近理论,作为非球端面铣刀单接触带宽最大化加工雕刻曲面时优化刀具运动的一般方法。基于表面运动框架,推导出刀具相对于工件运动的速度方程和变换矩阵,这些方程和矩阵由刀具表面和设计表面的运动不变参数描述。用于优化刀具位置的函数极值模型可确保刀具相对于工件的连续对称运动,从而实现最高的加工效率和精度。最后,一个基于 Matlab 的仿真实例验证了包络逼近理论的加工效率和精度。
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Optimized Tool Motion Symmetry for Strip-Width-Max Mfg of Sculptured Surfaces with Non-Ball Tools Based on Envelope Approximation
The problem of machining complex surfaces with non-ball-end cutters by strip-width-maximization machining is formulated as a kind of surface fitting problem in which the tool surface envelope feature line approximates the design surface under the movement transform. The theory of surface envelope−approximation is proposed as a general method for optimizing tool movement in single-contact strip-width-maximization machining of sculptured surfaces with non-ball-end cutters. Based on the surface moving frame, the velocity equations and transformation matrices for the tool motion relative to the workpiece, described by the motion-invariant parameters of the tool surface and design surface, are derived. A functional extremum model for optimizing the tool position ensures continuous and symmetrical motion relative to the workpiece to achieve the highest machining efficiency and accuracy. Finally, a Matlab-based simulation example verifies the machining efficiency and accuracy of the envelope approximation theory.
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