Cutting Forces in Peripheral Up-Milling of Particleboard

An analysis of forces acting in the peripheral up-milling of particleboard is presented. First, a novel method of high-frequency piezoelectric force signal treatment is proposed and used to separate the original force signal from the vibrations of the previous cutting iteration. This allows for the analysis of single chip cutting force courses during industrial CNC (Computer Numerical Control) milling. The acting forces are compared with the theoretical, instantaneous, uncut chip thickness. The results show that, for a range of 40-60 m/s, the higher the cutting speed used, the higher the resultant and principal cutting forces. The method of cutting thrust force used was similar to that observed in solid wood milling, i.e., first using a pushing action, followed by a pulling action. The obtained average specific principal cutting forces for particleboard peripheral up-milling are equal to 32.0 N/mm(2) for slow and 37.6 N/mm(2) for fast milling. The specific cutting thrust force decreases with the increase in instantaneous uncut chip thickness.

Automated summary

The study introduces a novel method for processing high-frequency piezoelectric force signals to analyze single chip cutting force courses in industrial CNC milling. Results indicate that higher cutting speeds lead to higher cutting forces. The cutting thrust force in peripheral up-milling of particleboard is similar to that observed in solid wood milling.