The chemical electrolytes are widely used in electrochemical machining(ECM)and have a significant effect on both the material removal rate(MRR)and the surface finish(Ra)of the workpiece.The process parameters of ECM,s...The chemical electrolytes are widely used in electrochemical machining(ECM)and have a significant effect on both the material removal rate(MRR)and the surface finish(Ra)of the workpiece.The process parameters of ECM,such as current density,electrolyte composition,and feed rate,are vital for optimizing machining performance.Research has indicated that high current density can create localized non-conductive passivating films,which impede metal dissolution.In this study,the aqueous solution of sodium nitrate(NaNO_(3))combined with gold nanoparticles(AuNPs)has been used as a novel electrolyte to evaluate the machining performance of the 20MnCr5 steel alloy.The inclusion of AuNPs in the NaNO_(3) solution enhanced local surface effects and promoted low-valence metal dissolution.The results demonstrated that the MRR and average surface roughness of the 20MnCr5 workpiece improved by 19.6%and 35.5%,respectively,when AuNPs were utilized compared to the alone NaNO_(3) electrolytic system.The experimental results also showed that the MRR increased within the current density range of 5.5 A/cm^(2) to 15.8 A/cm^(2),but declined in the range of 15.8 A/cm^(2) to 32.5 A/cm^(2).This decrease in the MRR at higher current densities can be attributed to the formation of non-conductive metal oxide passive layers.The oxygen evolution reaction(OER)was observed with the NaNO_(3) electrolyte at higher current densities,resulting in the formation of numerous micropores on the surface of the workpiece.In contrast,when the electrolyte was combined with AuNPs,these micropores ruptured quickly,creating new sites for the re-dissolution of metal ions.The microstructural changes on the machining surfaces under different operating conditions were analyzed using field emission scanning electron microscopy(FESEM),and the results are presented.Possible surface reactions,such as the formation of metal oxides and the release of oxygen gas,are discussed based on energy-dispersive X-ray(EDX)analysis and cyclic voltammetry(CV)studies.展开更多
文摘The chemical electrolytes are widely used in electrochemical machining(ECM)and have a significant effect on both the material removal rate(MRR)and the surface finish(Ra)of the workpiece.The process parameters of ECM,such as current density,electrolyte composition,and feed rate,are vital for optimizing machining performance.Research has indicated that high current density can create localized non-conductive passivating films,which impede metal dissolution.In this study,the aqueous solution of sodium nitrate(NaNO_(3))combined with gold nanoparticles(AuNPs)has been used as a novel electrolyte to evaluate the machining performance of the 20MnCr5 steel alloy.The inclusion of AuNPs in the NaNO_(3) solution enhanced local surface effects and promoted low-valence metal dissolution.The results demonstrated that the MRR and average surface roughness of the 20MnCr5 workpiece improved by 19.6%and 35.5%,respectively,when AuNPs were utilized compared to the alone NaNO_(3) electrolytic system.The experimental results also showed that the MRR increased within the current density range of 5.5 A/cm^(2) to 15.8 A/cm^(2),but declined in the range of 15.8 A/cm^(2) to 32.5 A/cm^(2).This decrease in the MRR at higher current densities can be attributed to the formation of non-conductive metal oxide passive layers.The oxygen evolution reaction(OER)was observed with the NaNO_(3) electrolyte at higher current densities,resulting in the formation of numerous micropores on the surface of the workpiece.In contrast,when the electrolyte was combined with AuNPs,these micropores ruptured quickly,creating new sites for the re-dissolution of metal ions.The microstructural changes on the machining surfaces under different operating conditions were analyzed using field emission scanning electron microscopy(FESEM),and the results are presented.Possible surface reactions,such as the formation of metal oxides and the release of oxygen gas,are discussed based on energy-dispersive X-ray(EDX)analysis and cyclic voltammetry(CV)studies.
