Machining is a complex process in which many variables can modify and interfere with the desired result. Productivity, as a measure of the milling operation efficiency, must follow both the technological elements of the machining process but also the geometrical elements - ways of removing the material and the trajectory of the tool. This paper approaches productivity growth using methods that improve the technological elements of machining. Selection by performance criteria in the field of productivity increase for the milling operation on machines with numerical control ensures an intensive economic growth, desired for any modern society.

Adam G., Rehorn J. J., Peter E. O. State-of-the-art methods and results in tool condition monitoring: a review, Int J Adv Manuf Technol 26: 693–710, DOI 10.1007/s00170-004-2038-2, 2005

Kalinski K., Kucharski T., Computer prediction of the tool-workpiece vibration surveillance in modern milling operations, Advances in Technology of the Machines and Equipment, vol. 23, no 3, p. 17-42, 1999.

Liao Y.S., Young Y.C., A new on-line spindle speed regulation strategy for chatter control, International Journal of Machine Tools and Manufacture, Volume 36, Issue 5, May 1996, Pages 651-660

Zhou C., Yang B., Guo K., Liu J., Sun J., Song G., Zhu S., Sun C., Jiang Z., Vibration singularity analysis for milling tool condition monitoring, International Journal of Mechanical Sciences, 166, 2020

Yue C., Gao H., Liu X., Liang S. Y., Wang L., A review of chatter vibration research in milling, Chinese Journal of Aeronautics, 32, 215–242, 2019

Gelmereanu C, Morar L., Bogdan S., Productivity and Cycle Time Prediction Using Artificial Neural Network, Procedia Economics and Finance, vol.15, pages 1563 – 1569, 2014.

Bodi Ş., Dragomir M., Banyai D., Dragomir D., Process Improvements Using Simulation Software and Quality Tools, Applied Mechanics and Materials, Volume 808, pages 376-381, https://doi.org/10.4028/www.scientific.net/amm.808.376, 2015

Abrudan I., Candea C., Manual de inginerie economica: ingineria si managementul sistemelor de productie, Cluj-Napoca, Editura Dacia, 2002

Budak E., Improving productivity and part quality in milling of titanium based impellers by chatter suppression and force control, Ann CIRP vol. 49(1):31–36, 2000

Elemente privind dinamica automatizării industriale şi a creşterii performanţelor de flexibilitate şi de progres tehnologic, http://www.management.ase.ro/reveconomia/2000/11.pdf, accessed 22.11.2019

Niu J, Ding Y, Zhu LM, Ding H., Stability analysis of milling processes with periodic spindle speed variation via the variablestep numerical integration method, J Manuf Sci E-T ASME, vol. 138(11):114501–11, 2016.

Jin G, Qi H, Li Z, Han J., Dynamic modeling and stability analysis for the combined milling system with variable pitch cutter and spindle speed variation, Commun Nonlinear Sci, vol. 63, pages 38–56, 2018.

Gelmereanu C., Contribuţii privind proiectarea şi elaborarea unui stand de cercetare CNC, PhD. Thesis, Cluj-Napoca, Universitatea Tehnică din Cluj-Napoca, 2013