1. Study on Triggering Characteristics and Induced Breakdown Rules of SF₆ Gap Switch Plasma Jets at Extremely Low Working Voltage.
- Author
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Dong, Bingbing, Zhang, Zelin, Xiang, Nianwen, Zhang, Zhu, Ding, Lijian, and Chen, Weijiang
- Subjects
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PLASMA jets , *LOW voltage systems , *PLASMA materials processing , *HYBRID systems , *ELECTRIC breakdown - Abstract
The SF6 gap switch has obvious advantages in the flexible control very fast switch of the controllable arrester used in hybrid UHVDC system. However, the plasma jet ability in SF6 atmosphere at high pressure is greatly restricted, which is easy to cause trigger failure. The triggering characteristics and induced breakdown mechanism are still unclear during the plasma jet-triggered process of the SF6 gap switch at extremely low working voltage. In this study, a plasma jet-induced breakdown research platform based on two-stage continuous surface-triggered gas gap switch (GGS) was established to investigate time-space distribution evolution characteristics, the critical triggering conditions parameters, and working voltage functioning rules of the SF6 gap. The jet plasma has a high-brightness-like conical shape, and its initial jet velocity can reach more than 2 km/s. Increasing capacitance value and charging voltage of the secondary chamber in SF6 gap switch trigger cavity, its creeping arc current is increased, and the time delay and dispersion will be reduced. Moreover, the geometric characteristics (including jet area, jet radial and axial length, and jet velocity) and electrical parameters of the jet plasma increase gradually. Increasing the working voltage of main gap in SF6 gap switch, the plasma jet velocity lift phenomenon appears at induced breakdown end of SF6 gap switch. With the continuous increase of the working voltage, the lift effect is more significant. The purpose of this study is to solve the key problem of plasma-induced breakdown failure of the SF6 gap switch, which will guide the design of fast self-recovery energy discharge protection switches for hybrid UHVDC transmission systems. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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