Surface Morphology Evolution of W-Ni-Fe Alloy Electrode Under Repetitive Pulsed Discharges

2020 IEEE International Conference on High Voltage Engineering and Application (ICHVE) Pub Date : 2020-09-06 DOI:10.1109/ICHVE49031.2020.9280025

Jiawei Wu, R. Han, Manyu Wang, W. Ding

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Abstract

The conduction of the gas switch is accompanied by spark/arc discharge. The high temperature and current density of the plasma channel will cause erosion on the surface of the electrode material. In particular, in repetitive pulsed power systems, electrode erosion has a sizeable influence on the performance of the system. Recent research has proven the superior properties of W-Ni-Fe alloy over traditional W-Cu composites in spark gaps. Not only the resistance of arc erosion, but the operating characteristics were evidently improved when W-Ni-Fe alloy was applied. This paper focus on the erosion morphology evolution of W-Ni-Fe alloy electrodes in a spark gap. In the experiment, the electrodes were tested with 100 kA level pulsed discharges for 10,000 shots (~1.3 C of transferred charge per shot). Surface profiles of 4 pairs of 90WNiFe (90 wt.% of W), 93WNiFe (93 wt.% of W), 97WNiFe (97 wt.% of W), and 90WCu (90 wt.% of W) were measured. A group of parameters has been proposed to characterize the features of surface profiles. Evolution of surface morphology features was therefore analyzed based on those parameters.

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重复脉冲放电对W-Ni-Fe合金电极表面形貌的影响

气体开关的传导伴随着火花/电弧放电。等离子体通道的高温和高电流密度会对电极材料表面造成侵蚀。特别是，在重复脉冲功率系统中，电极侵蚀对系统的性能有相当大的影响。近年来的研究表明，钨镍铁合金在火花隙中的性能优于传统的钨铜复合材料。采用W-Ni-Fe合金不仅能明显改善电弧腐蚀性能，而且能明显改善其工作特性。研究了钨镍铁合金电极在放电间隙中的腐蚀形貌演变。在实验中，对电极进行了100 kA级脉冲放电测试，放电次数为10,000次(每次放电转移电荷约1.3 C)。测量了4对90WNiFe (90% wt.% W)、93WNiFe (93% wt.% W)、97WNiFe (97% wt.% W)和90WCu (90% wt.% W)的表面轮廓。提出了一组参数来表征表面轮廓的特征。因此，基于这些参数分析了表面形貌特征的演变。

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2020 IEEE International Conference on High Voltage Engineering and Application (ICHVE)

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