Investigation on the modelling and characterization of top edge burr formation in slotting finned tube

Abstract

In this study, a three-dimensional finite element model is utilized to analyse the top edge burr formation in orthogonal slotting copper finned tubes. To describe the top edge burr generation, a conceptual model is developed to explain the material shear failure. The normalized Cockroft-Latham criterion is employed for a general understanding of the plastic behaviour and burr formation, and the critical damage value is obtained to qualify the burr geometries by tensile tests. Based on material side flow and the progressive deformation behaviour, the characteristics and mechanism of top edge burr formation are further investigated. The results show that the top edge burr is formed by a combination of material tear and sideward flow. The top edge burr formation process can generally be divided into three phases: the initiation of the deformation bulge, the development of the deformation bulge, and tear formation. The characteristics of the top edge burr also consist of three parts: basal deformation area, tensile area, and top tear area. The three parts of the burr characteristics correspond to the three phases of the burr formation process. Additionally, the influences of rake face, feed rate, and cutting speed on the burr size are studied based on a quantitative method. The study provides a basis for the minimization of top edge burr formation and optimization of machining parameters.