We have determined in which conditions we have a regenerative vibration cases (chatter). We have used the simulation of a machining system dynamic behaviour. A cutting force law was obtained by an indirect method, by comparing between simulation results and experimental ones.

During manufacturing process of mechanical parts, the method of material remove by cutting tools have a significant importance, according to the matter of the part manufacturing process and to its raw elaboration method. On one hand, the characteristics of machining operations depend on the “studies office” choices during the part conception (the shape, the material, ...). On the other hand, they also depend on the “methods office” choices (machining gamut, choice of: machines, tools, cutting parameters, and tools paths, ...). For the “methods office”, some bad choices of cutting forces could change the final quality of the machined part. In this order, we have studied the dynamic cutting law evaluation problem. This consists in developing a simplified phenomenological cutting force model, in a case of turning under orthogonal machining conditions in presence of vibrations.

The simulation of the global Part-Tool-Machine-System (PTMS) dynamic behaviour during cutting is one of the validation procedures used to prepare a machining process. Various objectives could be reached when using simulation and this depends on the user who could be the machine-tool designer, the tool designer or the machinist. Two kinds of mathematical models, in order to develop simulation programs, are suggested for the (PTMS) modelling: the first one describes the (PTMS) as a mechanical structure and the second one describes the interaction between a tool and a worked part. In our study, we are interested in the second mathematical model and we must firstly establish a dynamic cutting force law, including different parameters and a damping term. The aim of this research paper is to suggest an identification method for the dynamic cutting force law parameters, calling (CDFC), by using a dynamometer in the case of an orthogonal cutting process.