Abstract
In the present work, an explicit finite element (FE) model was developed for predicting cutting forces and chip morphologies of polymers from the true stress–strain curve. A dual fracture process was used to simulate the cutting chip formation, incorporating both the shear damage failure criterion and the yield failure criterion, and considering the strain rate effect based on the Johnson–Cook formulation. The frictional behaviour between the cutting tool and specimen was defined by Coulomb’s law. Further, the estimated cutting forces and chip thicknesses at different nominal cutting depths were utilized to determine the fracture toughness of the polymer, using an existing mechanics method. It was found that the fracture toughness, cutting forces, and chip morphologies predicted by the FE model were consistent with the experimental results, which proved that the present FE model could effectively reflect the cutting process. In addition, a parametrical analysis was performed to investigate the effects of cutting depth, rake angle, and friction coefficient on the cutting force and chip formation, which found that, among these parameters, the friction coefficient had the greatest effect on cutting force.
Highlights
IntroductionOrthogonal cutting is one of the most widely used machining methods for materials
Orthogonal cutting is one of the most widely used machining methods for materials.During a cutting process, material is removed from a workpiece in the form of continuous or discontinuous chips, to obtain a designed geometry and surface finish
Predictions of the cutting force and chip morphology are important for improving cutting efficiency
Summary
Orthogonal cutting is one of the most widely used machining methods for materials. Material is removed from a workpiece in the form of continuous or discontinuous chips, to obtain a designed geometry and surface finish. Merchant [1,2] presented a shear-angle model to describe the cutting process with a continuous chip. Numerical methods [13,14,15,16,17] have increasingly been used to investigate the complicated mechanisms involved with orthogonal metal-cutting, due to their high efficiency and low cost. Movahhedy et al [13] developed an arbitrary Lagrangian–Eulerian FE model to simulate the metal cutting process. Wan et al [14]
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