Optimization and Simulation of Electrochemical Machining of Cooling Holes on High Temperature Nickel-Based Alloy

To improve the electrochemical machining (ECM) precision and machining efficiency of aeroengine turbine blade cooling holes, taking the lateral gap and material removal rate as performance evaluation indicators, the machining accuracy and machining efficiency of ECM cooling holes as a function of the machining voltage, electrode feed rate and electrolyte concentration were explored through orthogonal experiments and single-factor experiments. The results show that among the three process parameters, the electrode feed rate is an important factor affecting the side clearance, and the processing voltage is an important factor affecting the material removal rate, which provides guidance for the optimization of ECM process parameters. Based on the cooling hole samples obtained from basic experiments, the influence of three process parameters on the distribution of the pressure field in the ECM region was analysed by computational fluid dynamics (CFD) simulations. Combined with those in the basic experiments, the optimal process parameters were obtained: machining voltage U=10 V, electrode feed rate f =0.66 mm/min, and electrolyte concentration zeta = 11%.