MULTI-RESPONSES OPTIMIZATION OF DRY MILLING OF SKD61 FOR LOW CUTTING POWER AND SURFACE ROUGHNESS

Abstract

Optimized process parameters play a significant role in improving the energy efficiency and machined part quality. This paper systematically investigates the nonlinear relationships between machining parameters and responses, including cutting power P_c and surface roughness R_a of the dry milling (DM) using the response surface model (RSM). Three process parameters considered include the spindle speed S, depth of cut a_p, and feed rate f_z. A set of physical experiments was carried out with SKD61 steel on a CNC milling machine using the wiper insert. The target of the current complex optimization is to find the low cutting power and surface roughness. Finally, an evolutionary algorithm entitled non-dominated sorting genetic algorithm II (NSGA-II) was used to generate a set of feasible optimal solutions and determine the best machining conditions. The results show that an appropriate trade-off solution can be drawn with regard to the low cutting power and surface roughness. Furthermore, the integration of RSM model and NSGA-II can be considered as a powerful approach for modeling and optimizing dry milling processes.