Chemical equilibrium composition of air-copper-PA66 mixtures and their effects on dielectric breakdown for low-voltage circuit breaker post-current-zero

2013 Abstracts IEEE International Conference on Plasma Science (ICOPS) Pub Date : 2013-06-16 DOI:10.1109/PLASMA.2013.6633283

V. R. Narayanan, J. Heberlein, Christian Ruempler

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Abstract

Summary form only given. Metallic vapor emanating from the electrodes and plastic vapor from wall ablation on or before current-zero in a low-voltage circuit breaker (LVCB) significantly affect the dielectric recovery characteristics of atmospheric pressure air in the contact gap after current-zero. When the net ionization coefficient becomes positive, dielectric breakdown is said to occur and the reduced electric field (E/N) of this occurrence is termed the critical reduced electric field ((E/N)crit) [1]. In this paper, we analyze the dielectric breakdown behavior for the case of copper being the electrode material and polyamide 6/6 (PA-66) being the plastic wall material. Firstly, the chemical composition is calculated by the minimization of Gibbs free energy and the results are compared for two different methodologies (denoted as M1 [2] and M2 [3], for convenience). Unlike M2, M1 includes the condensed species of copper and carbon (graphite) and it will be shown that below 3500 K, the two methods provide widely different composition results. Secondly, Boltzmann's EEDF equation is solved to obtain the generalized non-Maxwellian electron-energy distribution function (EEDF) [4], with the electron-impact collision cross-sections gathered from literature as input. Using the afore-mentioned inputs, (E/N)crit is calculated and plotted against temperature ranging between 300-6000 K, for different mass-fraction values of air, copper and PA-66. Additionally, it has been observed that the presence of vibrationally- and electronically-excited species enhances the dielectric breakdown by lowering (E/N)crit. This approach is part of an initial attempt towards addressing realistic chemical non-equilibrium conditions involving finite-rate kinetics in an LVCB after current-zero and the numerical results will subsequently be utilized for comparisons with available experimental data.

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空气-铜- pa66混合物的化学平衡组成及其对低压断路器零流后介质击穿的影响

只提供摘要形式。低压断路器在零电流时或零电流前电极产生的金属蒸汽和壁面烧蚀产生的塑料蒸汽对零电流后接触间隙内常压空气的介电恢复特性有显著影响。当净电离系数变为正时，介质击穿发生，这种现象的约简电场(E/N)称为临界约简电场((E/N)临界)[1]。本文分析了以铜为电极材料，聚酰胺6/6 (PA-66)为塑料壁材时的介电击穿行为。首先，通过Gibbs自由能最小化法计算化学成分，并比较两种不同方法(为方便起见，分别记为M1[2]和M2[3])的计算结果。与M2不同，M1包含铜和碳(石墨)的凝聚态，并且将显示在3500k以下，两种方法提供的组成结果差异很大。其次，以文献收集的电子碰撞截面作为输入，求解Boltzmann的EEDF方程，得到广义非麦克斯韦电子能量分布函数(generalized nonmaxwell electron-energy distribution function, EEDF)[4]。使用上述输入，对空气、铜和PA-66的不同质量分数值，在300-6000 K的温度范围内计算并绘制(E/N)临界值。此外，已经观察到振动和电子激发物质的存在通过降低(E/N)临界值来增强介电击穿。该方法是解决零电流后LVCB中有限速率动力学的实际化学非平衡条件的初步尝试的一部分，数值结果随后将用于与现有实验数据进行比较。

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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2013 Abstracts IEEE International Conference on Plasma Science (ICOPS)

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