Abstract
The paper presents a mechanistic cutting force model of serrated end mill to predict cutting forces. Geometric model of serrated end mill is established, which covers variable helix end mill geometries. In this model, the serration of helical cutting flutes is expressed spatially and the wave of serration is defined to be a sine wave. The spatial vector is applied to define chip thickness so as to enhance the spatial expressiveness of the model, which is perpendicular to the curvature of each flute. Each helical flute is scatted into a series of infinitesimal cutting edges. The infinitesimal cutting forces depend on three cutting force coefficients and three edge force coefficients in the tangential, radial, and axial directions at every cutting element. By integrating the infinitesimal cutting forces along each cutting edge, the milling forces with serrated end mill can be predicted. The model feasibility of the serrated end mill is verified by comparing the predicted and measured cutting forces. Moreover, the model is also verified such that it can also predict cutting forces with other types of end mills, such as variable helix serrated end mill, variable helix end mill, and regular end mill.
Highlights
Nowadays, the manufacturing industry demands high productivity because of the competitiveness environment
The chip thickness is explained in geometry, which is perpendicular to the curvature of each flute
The average milling force method proposed by Altintas et al [19] was used to calibrate the cutting force coefficients
Summary
The manufacturing industry demands high productivity because of the competitiveness environment. By analyzing the milling process, Martelloti [3] presented a force model which firstly expressed the cutting thickness with the geometric method. Grabowski et al [15] presented a method to predict milling forces and studied the stability of complex tools. Sultan and Okafor [17] established a cutting force prediction model of wavy-edge bull-nose helical end mill. It is significant to study the force model with special end mills, which can be utilized to optimize the cutting parameters, design the cutting tools, and analyze the stability during the milling process. The paper establishes a mechanistic cutting force model to predict cutting forces with serrated end mill during end milling process It establishes a geometric model of serrated end mill considering pitch angles and helix angles in each helical cutting flute. Compared with previous works, this model has more expensive application in milling, especially in the condition of rough milling
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