Electrical Field Distribution along HVDC GIL Spacer in SF 6 /N 2 Gaseous Mixture

Electric Power Conversion Pub Date : 2019-03-05 DOI:10.5772/INTECHOPEN.84568

B. Du, Jin Li, Liang Hucheng

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Abstract

Many researchers have proposed a variety of mathematical models to simulate the surface charge accumulation process of DC-GIS/GIL spacers. However, few of them took the gas collision ionization and charge trapping-detrapping process into consideration. This chapter combined the plasma hydrodynamics and charge transport equations and built a modified model. Some conclusions are shown as follows: for the basin-type spacer, the surface charge has the same polarity as the applied voltage on the lower surface but the opposite polarity on the upper surface. For the disc-type spacer, the surface charge has the same polarity as the applied voltage near the shell but the opposite polarity near the conductor under negative voltage. But under positive voltage, negative charge exists almost on the whole surface. The most serious distortion of the electric field occurs at the triple junction of epoxy spacer. Under load condition, there is an obvious temperature rise on the conductor due to joule heating, which has a great influence on the electric field distribution. The application of shielding electrodes has the function of field grading at the triple junction, which can be referred in the DC GIS/GIL design.

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sf6 / n2混合气中沿高压直流GIL间隔层的电场分布

许多研究人员提出了多种数学模型来模拟DC-GIS/GIL隔层的表面电荷积累过程。然而，很少有人考虑到气体碰撞电离和电荷捕获-脱捕过程。本章结合等离子体流体力学和电荷输运方程，建立了修正模型。结果表明:对于盆型间隔片，表面电荷与下表面的外加电压极性相同，而上表面的极性相反;对于圆盘式隔离器，表面电荷在外壳附近具有与施加电压相同的极性，但在负电压下靠近导体时具有相反的极性。但在正电压下，负电荷几乎存在于整个表面。电场畸变最严重的地方是环氧树脂垫片的三连接处。在负载状态下，由于焦耳加热，导体上有明显的温升，这对电场分布有很大的影响。屏蔽电极在三结点处的应用具有现场分级的作用，可为直流GIS/GIL设计提供参考。

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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Electric Power Conversion

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