Coupled effect of tool geometry and tool-particle position on diamond cutting of SiCp/Al

The stress state built in the tool-particle contact region plays a dominant role in governing the particle-tool interactions that strongly determine the machinability of SiCp/Al. In the present work, we evaluate the coupled influence of rake angle of cutting tool and tool-particle position on the ultra-precision diamond cutting of SiCp/Al by finite element simulations and corresponding experiments. Specifically, 2D finite element modeling of SiCp/Al cutting with the consideration of the real microstructural characteristics of SiC particles and the mechanical behavior of particle-matrix interface is caried out, and the accuracy of which is verified by corresponding cutting experiments. Simulation results and experimental data jointly reveal different failure modes of SiC particles, as well as their correlations with cutting force, chip profile and machined surface integrity. In particular, the rake angle of cutting tool significantly alters the built stress state in tool-particle contact region, thus leading to a strong coupled effect of rake angle of cutting tool and tool-particle position on the diamond cutting of SiCp/Al. The findings reported in this work provide a theoretical basis for the rational selection of geometrical parameters of cutting tool for promoting the machinability of SiCp/Al.

Automated summary

This study investigates the coupled influence of rake angle of cutting tool and tool-particle position on the ultra-precision diamond cutting of SiCp/Al through finite element simulations and corresponding experiments. The results reveal different failure modes of SiC particles and their correlations with cutting force, chip profile, and machined surface integrity. The findings emphasize the significant role of the rake angle of the cutting tool in altering the stress state in the tool-particle contact region and its strong coupled effect with the tool-particle position on the diamond cutting of SiCp/Al.