Helical wire electrochemical discharge machining on large-thickness Inconel 718 alloy in low-conductivity salt-glycol solution

Wire electrochemical machining (WECM) is a flexible and effective method for machin-ing complex-shaped metal components, but the ability to machine large-thickness workpieces is hampered by the difficulty of transporting electrolytic products in the narrow machining gap. This paper proposes a novel hybrid machining technique that combines the characteristics of WECM and wire electric discharge machining(WEDM), namely, helical wire electrochemical discharge machining. The formation mechanism of electrical discharge in salt-glycol solution was elucidated. Experiments and simulation were conducted to verify the machining mechanism and investigate the performance of the proposed technique. The results show that as the recast layer can be removed by electrochemical action during the proposed process, the surface quality is effectively improved. Minimum surface roughness of the slit sidewall after machining reaches Ra = 0.12 & mu;m. Minimum standard deviation of the slit after machining reaches 5 & mu;m. Moreover, the existence of the dis-charges significantly improves the transport of the electrolytic products, thus ensuring high machin-ing efficiency. In the experiments, the maximum feed rate of the helical wire electrochemical discharge machining reaches 7 & mu;m/s (12.6 mm2/min). Finally, mortise structures of Inconel 718 with good machining accuracy and surface quality are fabricated with a feed rate of 5 & mu;m/s (9 mm2/min), demonstrating that electrical discharge assisted helical wire ECM is a promising technique for machining large-thickness hard metal materials.& COPY; 2023 Production and hosting by Elsevier Ltd. on behalf of Chinese Society of Aeronautics and Astronautics. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/ licenses/by-nc-nd/4.0/).

Automated summary

This paper presents a novel hybrid machining technique called helical wire electrochemical discharge machining, which combines wire electrochemical machining with wire electric discharge machining. Experimental results show that the proposed technique can effectively remove the recast layer and improve surface quality. The existence of electrical discharges significantly enhances the transport of the electrolytic products, ensuring high machining efficiency. The technique is demonstrated to be promising for machining large-thickness hard metal materials, as exemplified by the fabrication of mortise structures of Inconel 718 with good machining accuracy and surface quality.