Using data from x-ray high speed imaging of arc lengthening under capacitor discharge

IF 1.3 Q3 ORTHOPEDICS Plasma Research Express Pub Date : 2020-07-23 DOI:10.1088/2516-1067/aba69d

L. Millière, P. Lavaud

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引用次数: 1

Abstract

Although the fuse is one of oldest components of electrical engineering, its operating remains very complex because of the extreme rapidity of the phenomena and the fact that they take place in an opaque environment. Until now, engineers and researchers have only studied the fuse operation by indirect method, simulation or post mortem fuse state. But, a collaboration between mixed research units with the European Synchrotron for Research Facilities allowed filming the fuse operating by x-ray imaging. The method specification is to record the sequence with 5 million frames per second. The conductive material is thus observed to pass from a solid-liquid phase to an initiation of the plasma, thereby establishing the initial conditions of the arcing phase. The high speed films also permit to observe the lengthening of the arc in a few microseconds. The images can be synchronized with the voltage and the current, which makes it possible to return to the calculation of the electric field in function of time. Data analysis has been compared with simulation models and the separation of the curves prove the lack of knowledge of arc ignition phase due to the plasma which is out of its thermodynamic equilibrium.

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利用电容器放电下电弧延长的x射线高速成像数据

虽然保险丝是电气工程中最古老的部件之一，但由于这种现象发生的速度极快，而且它们发生在不透明的环境中，因此它的操作仍然非常复杂。到目前为止，工程师和研究人员仅通过间接方法、模拟或事后保险丝状态来研究保险丝的运行。但是，混合研究单位与欧洲同步加速器研究设施之间的合作允许通过x射线成像拍摄保险丝的操作。方法规范是以每秒500万帧的速度记录序列。因此，观察到导电材料从固-液相过渡到等离子体的起始，从而建立起弧相的初始条件。高速薄膜还允许在几微秒内观察到弧的延长。图像可以与电压和电流同步，从而使电场的计算回归到时间函数。数据分析与仿真模型进行了比较，曲线的分离证明了由于等离子体处于热力学平衡状态，对引弧相位缺乏认识。

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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来源期刊

Plasma Research Express Energy-Nuclear Energy and Engineering

CiteScore

2.60

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0.00%

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