Influence Analysis on Defects in Bushing Core at Grid Side of Converter Transformer

2021 International Conference on Advanced Electrical Equipment and Reliable Operation (AEERO) Pub Date : 2021-10-15 DOI:10.1109/AEERO52475.2021.9708235

Qingsong Wu, Lilan Liu, Tianxi Xie, X. Ning, Peng Liu, Zongren Peng

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Abstract

The high voltage bushing on the grid side of UHV converter transformer is located at the connection position between the grid side winding of converter transformer and the AC side system, which is the key equipment of UHVDC transmission system. In actual operation, the bushing will bear high temperature, large load current and additional load for a long time. In addition, due to the limitation of process level. During the rolling process of bushing capacitor core, there are inevitably some defects such as plate wrinkle, plate offset and unreliable grounding of the end plate. Under the long-term action of electricity, heat and stress, small defects are likely to develop into larger defects or even cause faults. Therefore, it is of great significance to study the influence of different defects on the electric field distribution in the bushing core and the partial discharge initial voltage (PDIV) of the bushing. On the basis of 550kV capacitive bushing, this paper designed and manufactured four scaled models. The rated working voltage of scaled models are 31.8kV. And the corresponding finite element simulation models are also established. The simulation results show that the wrinkle defect and offset defect will cause serious electric field distortion, resulting in a sharp increase of electric field at the defect. Ungrounded defects will completely change the distribution of electric field in the bushing, making the electric field concentrated in the insulating oil between the flange and the end plate. The measurement of PDIV shows that the wrinkle defect and offset defect can significantly reduce the PDIV which makes the bushing prone to PD at a lower voltage level and lead to fault. The initial voltage drop of ungrounded partial discharge is less, but the discharge amount is large. Therefore, the research of this paper has guiding significance for timely finding the original defects of bushing, preventing the development of defects, and solving the problem of frequent failure of converter bushing.

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换流变压器电网侧套管铁心缺陷的影响分析

特高压换流变压器电网侧高压套管位于换流变压器电网侧绕组与交流侧系统的连接位置，是特高压直流输电系统的关键设备。在实际运行中，套管将长期承受高温、大负载电流和附加负载。此外，由于工艺水平的限制。套管式电容器铁芯在轧制过程中，不可避免地存在板起皱、板偏置、端板接地不可靠等缺陷。在长期的电、热、应力作用下，小的缺陷很可能发展成较大的缺陷，甚至引起故障。因此，研究不同缺陷对衬套铁心电场分布和衬套局部放电初始电压(PDIV)的影响具有重要意义。本文以550kV容性套管为基础，设计制造了4种比例模型。比例模型的额定工作电压为31.8kV。并建立了相应的有限元仿真模型。仿真结果表明，褶皱缺陷和偏置缺陷会引起严重的电场畸变，导致缺陷处电场急剧增大。不接地缺陷会彻底改变套管内电场的分布，使电场集中在法兰与端板之间的绝缘油中。PDIV的测量结果表明，褶皱缺陷和偏置缺陷可以显著降低PDIV，使套管在较低电压水平下容易发生局部放电而导致故障。不接地局部放电的初始电压降较小，但放电量较大。因此，本文的研究对于及时发现换流器衬套的原始缺陷，防止缺陷的发展，解决换流器衬套频繁失效的问题具有指导意义。

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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2021 International Conference on Advanced Electrical Equipment and Reliable Operation (AEERO)

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