Modeling of Cutting Rock: From PDC Cutter to PDC Bit-Modeling of PDC Cutter

The main purpose of this paper is to present our polycrystalline diamond compact (PDC) cutter model and its verification. The PDC cutter model we developed is focused on a PDC cutter cutting a rock in 3D space. The model studies the forces between a cutter and a rock and applies the theory of poroelasticity to calculate the stress state of the rock during the cutting process. Once the stress state of the rock is obtained, the model can then predict rock failure by the modified Lade criterion (Ewy 1999). This work also developed a trial-and-error procedure to predict cutting forces, and the stress state of a rock before cutting process is also considered. A complete verification of the cutter model is conducted. The model results (i.e., predicted cutting forces) are compared with measured cutting forces from cutter tests in multiple published articles. The major influencing factors on cutting forces-backrake angle, side-rake angle, depths of cut, worn depth (or wear flat area), and hydrostatic pressure are all studied and verified. A good agreement between the model results and cutter test data is found, and the overall mean relative error is approximately 15%. The influence of inhomogeneous precut stress state of a rock is also studied. Overall, the cutter model in this paper is complete and accurate. It is ready to be integrated into a PDC bit model.

Automated summary

This paper introduces a complete and accurate polycrystalline diamond compact (PDC) cutter model and its verification process. The model predicts cutting forces by considering factors such as backrake angle, side-rake angle, depths of cut, worn depth, and hydrostatic pressure. Verification of the model shows good agreement with cutter test data, with an average relative error of approximately 15%. The influence of inhomogeneous precut stress state of a rock is also studied in the model.