Uniformity, Periodicity and Symmetry Characteristics of Forces Fluctuation in Helical-Edge Milling Cutter

Under most processing conditions, the milling force is expected to be stable and not to fluctuate, in order to improve the processing quality. This study focuses on analyzing the force fluctuation characteristics under conditions of different processing and cutter parameters. An original model is pr...

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Bibliographic Details
Published in:Applied sciences 2021-03, Vol.11 (6), p.2693
Main Authors: Meng, Boyang, Liu, Xianli, Li, Maoyue, Liang, Steven Y., Wang, Lihui, Wang, Zhixue
Format: Article
Language:English
Subjects:
Accuracy
cutting force
Cutting parameters
force fluctuation characteristics
helical-edge cutter
Influence
Periodicity
side milling
Symmetry
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Summary:Under most processing conditions, the milling force is expected to be stable and not to fluctuate, in order to improve the processing quality. This study focuses on analyzing the force fluctuation characteristics under conditions of different processing and cutter parameters. An original model is proposed to predict the force fluctuation during the milling process of a helical-edge cutter. At the same time, three force fluctuation characteristics related to the axial cutting depth and cutter parameters are determined: uniformity, periodicity and symmetry. The corresponding mathematical derivation and proof method are given for the first time through a force transformation of projecting the superposition chip thickness on a virtual cutting edge. On this basis, a fast estimation method and an accurate simulation method for force fluctuation prediction are established to quantify the intensity of force fluctuations under different parameters. Both two prediction methods and the experimental cutting tests validate the proposed theory effectively. The result shows a high potential of the proposed theory for studying the force behavior under different milling parameters or cutter parameters and at least 75% of the test workload can be reduced.
ISSN:2076-3417
2076-3417
DOI:10.3390/app11062693