Analytical model and experimental verification of Poisson burr formation in ductile metal machining

Previous investigations on the theoretical model to predict burr dimensions have normally been confined to a single geometric model, and the findings that have been proposed rarely take into account the influence of multiphysics factors on burr formation in the complex machining process. This paper proposes an analytical model to reveal subsurface plastic deformation behavior in machining of ductile material. This model is developed based on coupled thermo-mechanical factors. More importantly, the material property and tool edge arc are taken into consideration. According to the proposed model, the two approaches are presented to predict Poisson burr height and root thickness. Moreover, the material flow and burr formation mechanism are further investigated at great length. The effects of machining parameters and material properties on burr formation are analyzed and discussed in terms of plastic deformation behavior. The results show that this proposed model can describe burr morphology and predict burr size accurately. Poisson burr generation has a great sensitivity to machining parameters, as well as material property, and the transition of burr morphology is caused by severe lateral material flow owing to material softening effect at high temperature. There is the synchronous interaction between machining parameters and material property influencing burr formation. As a result, this study provides a valuable theoretical reference and basis for the deburring energy minimization, high surface quality, and machining parameters optimization.

Automated summary

Previous studies on predicting burr dimensions have been limited to a single geometric model, neglecting the influence of multiphysics factors. This paper proposes an analytical model to reveal subsurface plastic deformation behavior during machining ductile material, taking into account material properties and tool edge arc. The proposed model accurately predicts burr size and morphology, showing that burr generation is sensitive to machining parameters and material properties, with the transition of burr morphology caused by material softening at high temperatures.