The Influence of Electric Field Inhomogeneity on Repetitive Performance of a Corona-Stabilized Switch

Li, Longjie; Huang, Zongze; Yang, Yan

doi:10.1109/access.2020.3033327

Cited by 4 publications

(6 citation statements)

References 58 publications

(56 reference statements)

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“…As mentioned in [21], the application of the corona stabilized electrode reduces the breakdown delay. It also reduces the jitter of the generator.…”

Section: Corona-stabilized Electrode Designmentioning

confidence: 92%

“…Since the corona phenomena occur before the complete breakdown of the gap, the corona stabilization effect will act on any of the subsequent breakdowns during the PRF operation. Therefore, an improvement in the insulation recovery performance of the interelectrode gas and a reduction of the breakdown voltage jitter are both expected, as detailed in [21]. Preliminary testing of the 13-stage Marx generator proved that, after setting the optimum positions for all the corona-stabilized electrodes, it has a very stable operation even in atmospheric air.…”

Section: Corona-stabilized Electrode Designmentioning

confidence: 93%

“…To overcome this disadvantage, corona-stabilized electrodes were installed in the SGSs in stages from 2 to 10. The application of this technique allows to improve the stability of the SGS operation and increases the PRF of the generator [21].…”

Section: Corona-stabilized Electrode Designmentioning

confidence: 99%

“…A few electrons can hardly cause an electron avalanche when their position is too far from the corona stabilizing electrode to be accelerated enough to obtain sufficient kinetic energy. A critical volume is defined here as a region close to the highly stressed corona stabilized electrode, where the presence of just a few electrons will lead to an electron avalanche [21]. Ionization in atmospheric air starts when the field strength exceeds 26 kV/cm [23].…”

Section: Corona-stabilized Electrode Designmentioning

confidence: 99%

See 3 more Smart Citations

Development and Test of a 500-kV Compact Marx Generator Operating at 100-Hz PRF

Zhabin

Lavrinovich

Ferron

et al. 2022

IEEE Trans. Plasma Sci.

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This article presents the electrical and mechanical design of a compact 13-stage 0.5-MV Marx generator operating at a pulse repetition frequency (PRF) of 100 Hz. The fast-switching process of the generator is based on spark gaps, operated under pressurized air and leading to the generation of an output pulsed voltage with a peak of 0.5 MV and a rise time of 15 ns when operated on a 300-load. Corona-stabilized electrodes are installed near the main gap of the switches to improve their operational stability and increase the PRF. To ensure compactness, the Marx generator is housed in a cylindrical metal vessel with a height of 92 cm and an outer diameter of 34 cm, having a total volume of 74 L. A highly accurate simulation using both PSpice and CST software packages was used to predict the impulse waveform at the output of the generator and to help in optimizing the generator design. The tests show a good agreement between the experimental data and the theoretical predictions.

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“…As mentioned in [21], the application of the corona stabilized electrode reduces the breakdown delay. It also reduces the jitter of the generator.…”

Section: Corona-stabilized Electrode Designmentioning

confidence: 92%

Section: Corona-stabilized Electrode Designmentioning

confidence: 93%

Section: Corona-stabilized Electrode Designmentioning

confidence: 99%

Section: Corona-stabilized Electrode Designmentioning

confidence: 99%

See 2 more Smart Citations

Development and Test of a 500-kV Compact Marx Generator Operating at 100-Hz PRF

Zhabin

Lavrinovich

Ferron

et al. 2022

IEEE Trans. Plasma Sci.

View full text Add to dashboard Cite

show abstract

“…Numerous studies have explored gas discharge shock waves, investigating the attributes of shock waves generated by various gases such as air and argon [12][13][14]. Extensive research has been conducted on the shock waves produced by SF 6 gas discharges in SF 6 circuit breakers [5,[15][16][17], primarily aimed at informing the internal structure design of these circuit breakers. For instance, in [15], simulations were employed to analyse the propagation characteristics of shock waves resulting from arc discharges in SF 6 circuit breakers.…”

Section: Introductionmentioning

confidence: 99%

Investigating the characteristics of internal discharge shock waves in gas‐insulated switchgear under varied gap configurations

Jia,

Haochu,

Zhao

et al. 2024

IET Generation Trans & Dist

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Gas‐insulated switchgears (GIS) are crucial components of high‐voltage power transmission and distribution systems. Internal discharges within GIS have garnered significant attention in the field of power engineering. This study investigates the characteristics of internal discharge shock waves in GIS under an air pressure of 0.3 MPa and three different discharge gap conditions: 1, 1.5, and 2 mm. High‐speed shadowing techniques are used to analyse the propagation speed, morphology, and post‐wave parameters. The study findings reveal that although the characteristics of internal discharge shock waves in GIS noticeably change with the gap size, they also exhibit a consistent trend: as the gap size increases, the initial shock wave accelerates, intensifying the discharge. Simultaneously, the rate of attenuation rises, with the shock wave becoming weaker after ≈30 µs. Furthermore, the post‐wave parameters follow a similar pattern, with an increase in gap size leading to higher parameter values but also a faster decay rate. The parameters decay more rapidly between 10 and 20 µs, slow down between 20 and 30 µs, and ultimately stabilize after around 30 µs. The results of this study hold significant theoretical and practical implications for the monitoring, diagnosis, and prevention of internal discharges in GIS.

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Mechanisms for insulation recovery during repetitive breakdowns in gas gaps

Li,

Chen,

et al. 2023

Physics of Plasmas

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The insulation recovery during repetitive breakdowns in gas gaps is a fundamental scientific issue in both traditional and emerging electrical technology fields, which has received extensive attention over the years. This paper provides a systematic review of research methods for insulation recovery in repetitive breakdowns of gas gaps, progress made in understanding the thermal–hydrodynamic processes involved in this recovery (dissipation of deposited energy and restoration of neutral gas density), as well as the memory effect resulting from repetitive discharges and breakdowns (dominant factors and their underlying mechanisms). Based on current results, it is proposed that the insulation recovery of repetitive gas gaps breakdowns results from the synergistic effect between post-breakdown thermal-hydrodynamic processes and memory effects. This review aims to clarify the boundary and interplay between hydrodynamic processes and memory effects, as well as reveal their coupling relationship and synergistic mechanism. It also seeks to overcome barriers between related research fields, ultimately facilitating a resolution to the issue.

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The Influence of Electric Field Inhomogeneity on Repetitive Performance of a Corona-Stabilized Switch

Cited by 4 publications

References 58 publications

Development and Test of a 500-kV Compact Marx Generator Operating at 100-Hz PRF

Development and Test of a 500-kV Compact Marx Generator Operating at 100-Hz PRF

Investigating the characteristics of internal discharge shock waves in gas‐insulated switchgear under varied gap configurations

Mechanisms for insulation recovery during repetitive breakdowns in gas gaps

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