Improving Machined Accuracy Under a Constant Feed Speed Vector at the End-Milling Point by Estimating Machining Force in Tool Approach

IF 0.9 Q4 AUTOMATION & CONTROL SYSTEMS International Journal of Automation Technology Pub Date : 2024-05-05 DOI:10.20965/ijat.2024.p0444
Takamaru Suzuki, T. Hirogaki, E. Aoyama
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Abstract

A five-axis machining center (5MC) is capable of synchronous control, which makes it a feasible tool for quickly and accurately machining complicated three-dimensional surfaces, such as propellers and hypoid gears. Recently, the necessity of improving both the machined shape accuracy and the machined surface roughness of free-form surfaces is growing. Therefore, in our previous study, we aimed to maintain the feed speed vector at the end-milling point by controlling two linear axes and a rotary axis of the 5MC to improve the quality of the machined surface. Additionally, we developed a method for maintaining the feed speed vector at the end-milling point by controlling the three axes of the 5MC to reduce the shape error of the machined workpieces (referred to as the shape error herein), considering the approach path of the tool determined via calculation. However, a high machining force at the start of the workpiece cutting was observed and the factor contributing to this phenomenon was not determined, although this phenomenon leads to a shape error to a certain degree according to the machining condition. In this study, the main objective is to suggest a method to reduce the machining force at the start of the workpiece cutting and shape error. Hence, we develop a theoretical method to estimate the machining force by using an instantaneous cutting force model, which considers the synchronized motion of two linear axes and a rotary axis of the 5MC. Subsequently, we determine the most suitable approach path of the tool considering the prediction of the machining force. The results of this study indicate that the machining force can be estimated by applying an instantaneous cutting force using the feed per tooth and machining angle, and that both a high machining force at the start of the workpiece cutting and shape error reduction can be realized by using the proposed approach path of the tool.
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通过估算刀具方法中的加工力提高端铣点恒定进给速度矢量下的加工精度
五轴加工中心(5MC)具有同步控制功能,因此是快速、精确加工螺旋桨和准双曲面齿轮等复杂三维表面的可行工具。近来,提高自由形状表面的加工形状精度和加工表面粗糙度的必要性与日俱增。因此,在之前的研究中,我们的目标是通过控制 5MC 的两个线性轴和一个旋转轴来保持端铣点的进给速度矢量,从而提高加工表面的质量。此外,我们还开发了一种方法,通过控制 5MC 的三个轴来保持铣端点的进给速度矢量,以减少加工工件的形状误差(此处称为形状误差),同时考虑到通过计算确定的刀具接近路径。然而,观察到工件切削开始时的加工力较大,虽然这种现象会根据加工条件在一定程度上导致形状误差,但造成这种现象的因素尚未确定。本研究的主要目的是提出一种减少工件切削开始时的加工力和形状误差的方法。因此,我们开发了一种理论方法,利用瞬时切削力模型估算加工力,该模型考虑了 5MC 两个线性轴和一个旋转轴的同步运动。随后,我们根据加工力的预测结果确定了最合适的刀具进给路径。研究结果表明,通过使用每齿进给量和加工角度来应用瞬时切削力,可以估算出加工力,而且通过使用所建议的刀具进刀路径,可以在工件切削开始时获得较高的加工力并减少形状误差。
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来源期刊
International Journal of Automation Technology
International Journal of Automation Technology AUTOMATION & CONTROL SYSTEMS-
CiteScore
2.10
自引率
36.40%
发文量
96
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