Effect of grounded electrode's width on electrical characteristics of nanosecond-pulse surface DBD

2013 Annual Report Conference on Electrical Insulation and Dielectric Phenomena Pub Date : 2013-10-01 DOI:10.1109/CEIDP.2013.6747419

Hui Jiang, T. Shao, Cheng Zhang, P. Yan, Zheng Niu, Yixiao Zhou

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引用次数: 6

Abstract

Surface dielectric barrier discharges with five different grounded electrode's widths are produced in order to investigate the effect of grounded electrode's width on electrical characteristics. The electrical parameters including applied voltage, total discharge current and transported charges are measured and calculated, respectively. Results show that the total discharge current has two obvious spikes. The first current spike of the total current has a peak which results in some fluctuations of transported charges in V-Q Lissajous figures, but the peak of the first current spike hardly changes with the electrode's width. The second spike peak value increases with the electrode's width, and reaches its maximum at an optimum width. All the V-Q loops at different electrode's widths are “almond-shape”, and the transported charges and energy per pulse increase with the electrode's width. The main plasma action area increases with the electrode's width, but keeps relatively constant when the grounded electrode's width is larger than the optimum width. In addition, the grounded electrode's width has no obvious influence on the plasma light intensity.

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接地电极宽度对纳秒脉冲表面DBD电学特性的影响

为了研究接极宽度对电特性的影响，制备了五种不同接极宽度的表面介质阻挡放电。分别测量和计算了施加电压、总放电电流和输送电荷等电学参数。结果表明，总放电电流有两个明显的尖峰。总电流的第一个电流尖峰有一个峰值，导致V-Q利萨约图中输运电荷的波动，但第一个电流尖峰的峰值几乎不随电极宽度的变化而变化。第二尖峰值随电极宽度增大而增大，并在最佳宽度处达到最大值。不同电极宽度下的V-Q环均呈“杏仁形”，且每脉冲输运的电荷和能量随电极宽度的增加而增加。主等离子体作用面积随着电极宽度的增大而增大，但当接地电极宽度大于最佳宽度时，主等离子体作用面积保持相对恒定。此外，接地电极的宽度对等离子体光强没有明显影响。

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 Annual Report Conference on Electrical Insulation and Dielectric Phenomena

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