Abstract
Based on the number of previous studies, this study aims to investigate the effects of process parameters of an Electrochemical Machining process, which are electrolyte concentration, the voltage applied to the machine, feed rate of the electrode, and Inter-Electrode Gap between tool and workpiece. Aluminum samples of 25 mm diameter x 25 mm height and 30mm diameter x 25mm height of the tool is made up of copper with a circular cross-section with 2 mm internal hole. The design of the system is based on the Taguchi method. Here, the signal-to-noise (S/N) model, the analysis of variance (ANOVA) and regression analyses are applied to determine optimal levels and to investigate the effects of these parameters on surface quality. Finally, the experiments that use the optimal levels of machining parameters are conducted to verify the effects of the process parameters on the surface quality of the products. The results pointed out a set of optimal parameters of the ECM process. The Inter-Electrode Gap between the tool and workpiece has extremely effected on these Material Removal rates and surface roughness. The Material Removal Rate increases with diseases in Inter-Electrode Gap, and Ra diseases with diseases in Inter-Electrode Gap. The experimental results show that maximum Material Removal Rate has obtained with electrolyte concentration at 100 g/l, feed rate at 0.0375 mm/min, the voltage at 15V, and Inter-Electrode Gap at 0.5mm. The minimum Ra has obtained with electrolyte concentration at 80 g/l, feed rate at 0.0468 mm/min, the voltage at 10V, and Inter-Electrode Gap at 0.5mm. This result has led to need studies on these parameters in Electrochemical Machining, which are improving productivities and surface roughness of the products.
Highlights
In recent years there are a large of advanced new materials and alloys which have been discovered but they are difficult to machine such as super alloys, alloys steel, tool steel, and stainless steel with conventional machining methods 1
Based on the number of previous studies, this study aims to investigate the effects of process parameters of an Electrochemical Machining process which are electrolyte concentration, voltage applied to the machine, feed rate of the electrode and Inter-Electrode Gap between tool and work - piece
The machinability of Electrochemical Machining (ECM) depends on electrolyte concentration, feed rate, voltage and Inter – Electrode Gap (IEG)
Summary
In recent years there are a large of advanced new materials and alloys which have been discovered but they are difficult to machine such as super alloys, alloys steel, tool steel, and stainless steel with conventional machining methods 1. This demands leads to several problems, and some feasible solutions would be solved in the future. Electrochemical Machining (ECM) is one of the widely used Non - Traditional Machining processes. ECM principle is based on the phenomenon of electrolysis, whose laws were established by Faraday in 1833. The first law states that the amount of electrochemical dissolution or deposition is proportional to amount of charge passed through the electrochemical cell, which may be descried as in (1): m∼Q (1)
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