Investigation and FEM-based simulation of tool wear in turning operations with uncoated carbide tools

This paper deals with tool wear in turning using uncoated carbide tools. The main purpose of this work is to define a FEM-based procedure for forecasting tool wear progression during cutting operations. Deform 3D FEM software was used to simulate the cutting process and a suitable subroutine was implemented into the software in order to evaluate the tool wear and to update the tool geometry. The tool wear
value is estimated according to well-known analytical models. Previous performed researches showed
some problems in the correct identification of crater depth and position when using analytical tool wear
models based only on abrasive or diffusive tool wear mechanisms. A new analytical tool wear model,
taking into account the influence of both abrasive and diffusive tool wear mechanisms for overcoming
these limits, was set-up and implemented by the authors. Experimental tests, performed turning AISI
1045 steel bars with ISO P40 uncoated tools, were used to calibrate and validate the FEM model. The
comparison between FEM and experimental results showed good agreement. Once validated, the FEM
model was used for analysing the influence of tool wear on the actual tool rake angle and on the tool
stresses.