Application of the Coupled Eulerian-Lagrangian (CEL) method to the modeling of orthogonal cutting

Abstract

Abstract Numerical modeling of metal cutting is a complex problem involving many nonlinear and coupled phenomena (high speed, large strains, large strain-rates, heat generation, etc.). Due to the large deformations, the mesh of the workpiece is often highly distorted. When it does not ends prematurely the computing, it slows it down and decreases the confidence in the results. Many formalisms are encountered in the literature to model the orthogonal cutting process, each with their pros and cons, more or less significant. This paper introduces the Coupled Eulerian-Lagrangian (CEL) formulation, in which the workpiece is described by the Eulerian formulation and the tool by the Lagrangian one. The comparison with experimental results and an Arbitrary Lagrangian-Eulerian (ALE) model with pure Lagrangian boundaries shows that the chip morphology and the cutting forces are well predicted by that new model. The absence of mesh deformation in the part does not decrease the stable time increment and therefore does not slow down the computing, which is competitive compared to the reference ALE model. This also increases confidence in the results given by the CEL model and opens new possibilities in the modeling of metal cutting.