Identification of Friction Behavior Variation in the Minor Flank of Square Shoulder Milling Cutters under Vibration

Identification of Friction Behavior Variation in the Minor Flank of Square Shoulder Milling Cutters under Vibration

In the milling process, the friction and wear of the tooth minor flank of the square shoulder milling cutter directly affects the machined surface quality and the cutter’s life. The friction of the minor flank of the cutter tooth presents a nonlinear distribution, and its variation cannot be reveale...

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Bibliographic Details
Published in:Applied sciences Vol. 12; no. 8; p. 4038
Main Authors: Jiang, Bin, Li, Weiheng, Zhao, Peiyi, Fan, Lili, Sun, Meng
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-04-2022
Subjects:
Atomic excitations
Coefficient of friction
Distribution functions
Dynamic characteristics
Energy consumption
Experiments
Friction
friction coefficient
friction energy consumption
friction speed
Identification methods
Mechanical properties
Milling cutters
minor flank of cutter tooth
Potential energy
square shoulder milling cutter
Stress
Surface properties
Teeth
Titanium alloys
Variables
Velocity
Vibration
Workpieces
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Summary:In the milling process, the friction and wear of the tooth minor flank of the square shoulder milling cutter directly affects the machined surface quality and the cutter’s life. The friction of the minor flank of the cutter tooth presents a nonlinear distribution, and its variation cannot be revealed by using a single parameter. It is difficult to identify the dynamic characteristics of the friction of the minor flank of the cutter tooth. In this work, the friction velocity model for the cutter tooth minor flank was developed by using the relative motion relationship between the flank area element and the workpiece transition surface. In accordance with the atomic excitation theory developed under the potential energy field at the friction interface of the cutter, the model for friction energy consumption under the friction velocity and thermal-stress coupling field on the minor flank of the cutter tooth was developed. Based on the mechanism of the interfacial atomic thermal vibration, the model for the friction coefficient under thermal-stress mechanical coupling was developed. Using the instantaneous friction coefficient and normal stress, the instantaneous friction distribution function of the flank was obtained. Finally, an identification method for the friction dynamic characteristics of the shoulder milling cutter tooth flank under vibration was proposed and verified by experiments.
ISSN:2076-3417
2076-3417
DOI:10.3390/app12084038