Milling is a key machining technology for manufacturing. The correct design of the cutting conditions, together with the appropriate geometry of the cutting tool, can contribute to greater productivity in the milling process. In this study, a two-dimensional finite element (FEM) simulation of the milling process was used to compare the cutting forces obtained by simulation with milling experiments and dynamometer measurements. The results showed that the FEM simulation was able to provide a simplified representation of the complex three-dimensional process, but it provides a clear picture of key phenomena such as stress distribution, temperature evolution, chip formation, and cutting forces. The STFC company DEFORM software is used for the FEM simulation model.

Kyratsis, P., Tzotzis, A., and Davim, J.P. (2023), A Comparative Study Between 2D and 3D Finite Element Methods in Machining 3D FEA Simulations in Machining , Springer International Publishing, pp. 1--12.

Airao, J. and Nirala, C. K. (2022), Finite Element Modeling and Experimental Validation of Tool Wear in Hot-Ultrasonic-Assisted Turning of Nimonic 90, Journal of Vibration Engineering and Technologies.

Hussain, G., Alkahtani, M., Alsultan, M., Buhl, J. and Gupta, M. K. (2022), Chip formation, cutting temperature and forces measurements in hard turning of Gcr15 under the influence of PcBN chamfering parameters, Measurement 204, 112130

Sumesh, C. and Ramesh, A. (2023), Optimization and finite element modeling of orthogonal turning of Ti6Al4V alloys: A comparative study of different optimization techniques, Engineering Solid Mechanics

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