Thermal Analyses of Electrically Assisted Forming

T. Grimm, L. Mears
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引用次数: 1

Abstract

Electrically assisted manufacturing (EAM) is defined as the direct application of electricity to a workpiece in situ with a manufacturing process. This is commonly used in forming to reduce the flow stress and increase the ductility of metals. Under certain conditions, there seem to be effects of the electricity that occur in addition to the inherent resistive heating in metals. This electroplastic effect is often deduced by estimating temperatures through analytical or numerical simulations and comparing this to the temperatures required to effect thermal stress reductions observed in experimental tests. For tests which utilized pulsed or AC currents, an RMS current value may be used to simplify simulations since current transience can be averaged to a constant representative value. However, there is often no justification of this assumption and it is possible that assumption could lead to erroneous results. Various assumptions applied to EAM research are explicitly explored herein to determine their validity in thermal estimations. It was concluded that AC, square wave, and sawtooth currents at frequencies greater than 1 Hz, or pulses from power supplies with significant ripple, can be approximated with a DC current of similar RMS value to obtain similar thermal estimations. Simulation geometries should incorporate as much of the experimental setup as possible. An example from literature was used to test several other assumptions as well, including the use of analytical simulations, rather than numerical.
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电辅助成形的热分析
电辅助制造(EAM)被定义为在制造过程中直接将电应用于工件。这通常用于成形,以减少流动应力和增加金属的延展性。在某些条件下,除了金属固有的电阻加热外,似乎还会产生电的影响。这种电塑性效应通常是通过分析或数值模拟来估计温度,并将其与实验测试中观察到的影响热应力降低所需的温度进行比较来推断的。对于使用脉冲或交流电流的测试,可以使用均方根电流值来简化模拟,因为电流瞬态可以平均为一个恒定的代表性值。然而,这种假设往往没有理由,而且这种假设有可能导致错误的结果。本文明确探讨了应用于EAM研究的各种假设,以确定它们在热估算中的有效性。结论是,频率大于1hz的交流、方波和锯齿电流,或来自具有显著纹波的电源的脉冲,可以用RMS值相似的直流电流进行近似,从而获得相似的热估计。模拟几何图形应尽可能多地包含实验设置。文献中的一个例子也被用来检验其他几个假设,包括使用分析模拟,而不是数值模拟。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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