电化学电弧加工的理论分析

J. McGeough, H. Rasmussen
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引用次数: 8

摘要

电化学电弧加工(ECAM)涉及通过水电解质和电解溶解产生的放电产生的侵蚀从阳极极化工件上去除金属。推导了该工艺的理论模型,并对两种具体应用进行了分析,即细孔钻孔和通过光滑其最初粗糙的表面对部件进行精加工。在第二个例子中,用摄动法求近似解;所建立的模型包含了电流密度对电流效率的影响,电流密度对电流效率的影响是由实验电化学加工(ECM)研究得出的,它会影响平滑的速率和方式。对于ECAM钻小孔,分析预测电极间隙宽度随施加电压的增加而增加,与机械驱动阳极的平方根成反比。在平滑的情况下,ECAM被发现以更快的速度去除表面不规则性,并且比单独使用ECM更低的金属损失,当电解质(如氯化钠溶液)用于后一种工艺时,电流效率为100%。分析表明,如果ECM的母材损耗接近ECAM,则需要具有电流密度相关电流效率的电解质溶液,即使这样,后者的加工速度仍然要快得多。注意被吸引到实验证据,以支持这些预测的ECAM行为。最后,利用该模型的结果验证了电解加工对电火花加工留下的零件表面进行快速精加工的实际应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A theoretical analysis of electrochemical arc machining
Electrochemical arc machining (ECAM) involves the removal of metal from an anodically polarized workpiece by both erosion arising from discharges produced in an aqueous electrolyte and electrolytic dissolution. A theoretical model is derived for the process and analysed for two specific applications, fine-hole drilling and the finishing of components by smoothing of their initially rough surfaces. In the second of these examples, a perturbation procedure for obtaining approximate solutions is used; the model so developed encorporates the effects of current density on current efficiency which are known from experimental electrochemical machining (ECM) studies to influence the rate and mode of smoothing. For fine-hole drilling by ECAM, the analysis predicts that the interelectrode gap width increases with the applied voltage and inversely with the square root of the mechanically driven anode. In the case of smoothing, ECAM is found to remove the surface irregularities at a much faster rate and with lower loss of stock metal than ECM alone, when electrolytes such as sodium chloride solution yielding 100% current efficiency are used for the latter process. The analysis shows that an electrolyte solution with a current density-dependent current efficiency is needed if parent metal loss by ECM is to approach that of ECAM, and even then, machining by the latter is still much faster. Attention is drawn to experimental evidence in support of these predictions of ECAM behaviour. Finally, results from the model are used to verify the practical use of ECM for rapid finishing of the surfaces of components left rough by electrodischarge machining.
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