PD Characteristics of Metal Particle on Epoxy Surface Under AC Superimposed Lightning Impulse in SF6

被引：0

作者：

He C. ^{[1
]}

Li P. ^{[1
]}

Liu B. ^{[1
]}

Li L. ^{[1
]}

Li J. ^{[2
]}

机构：

[1] State Grid Shaanxi Electric Power Company Limited, Xi’an

[2] State Key Laboratory of Electrical Insulation and Power Equipment, Xi’an Jiaotong University, Xi’an

来源：

Gaodianya Jishu/High Voltage Engineering | 2023年 / 49卷 / 04期

基金：

中国国家自然科学基金;

关键词：

AC superimposed lightning impulse; epoxy insulation surface; metal particles; partial discharges; SF6;

D O I：

10.13336/j.1003-6520.hve.20221096

中图分类号：

学科分类号：

摘要：

In order to master the excitation laws of partial discharges(PDs) on the epoxy insulation surface under complex working conditions such as AC superimposed impulse, the characteristics of PDs of metal particle on epoxy insulation surface under AC superimposed lightning impulse(LI) voltage are experimentally investigated in SF6 gas. When the AC voltage is lower than the partial discharge inception voltage(PDIV), the PDs excitation characteristics of metal particles with specific size and position under AC superimposed LI voltage are investigated.Meanwhile, when the AC voltage is greater than the PDIV, the effect of lightning impulse on AC partial discharge is studied. The results show that the PDIV decreases as the length of the metal particles increases, decreases as the diameter of the metal particles decreases, and decreases as the distance between the metal particles and the high-voltage electrode increases. The AC PDs excited by LI is more severe than the AC voltage applied alone. When the AC voltage is lower than the PDIV, the AC PDs excited by the negative LI(NLI) is more severe than that excited by the positive LI (PLI). When the AC voltage is higher than the PDIV, the LI has a negligible effect on the AC PDs. © 2023 Science Press. All rights reserved.

引用

页码：1653 / 1664

页数：11

共 26 条

[1]

HAN X T, GUO R C, SHEN S H, Et al., Study on the combined characteristics of UHF and optical signals induced by partial discharge at spacer surface in GIS, IET Generation, Transmission & Distribution, 14, 16, pp. 3332-3337, (2020)

[2]

CHEN Jiming, XU Chenhang, LI Peng, Et al., Feature extraction method for partial discharge pattern in GIS based on time-frequency analysis and fractal theory, High Voltage Engineering, 47, 1, pp. 287-295, (2021)

[3]

ZHANG L, HAN X T, LI J H., Partial discharge detection and analysis of needle-plane defect in SF6 under negative oscillating lightning impulse voltage based on UHF method, IEEE Transactions on Dielectrics and Electrical Insulation, 24, 1, pp. 296-303, (2017)

[4]

WANG Lijing, NI Hongkun, FANG Ke, Current situation of GIS operating status control and promotion strategy, Journal of State Grid Technology College, 20, 1, pp. 19-23, (2017)

[5]

XU Chenhang, CHEN Jiming, LIU Weinan, Et al., Pattern recognition of partial discharge PRPD spectrum in GIS based on deep residual network, High Voltage Engineering, 48, 3, pp. 1113-1123, (2022)

[6]

ZHANG Guozhi, LU Changyue, ZHOU Hong, Et al., Integrated ultrasonic and UHF sensing technology for partial discharge of power equipmen, High Voltage Engineering, 48, 12, pp. 5090-5101, (2022)

[7]

WANG Zikang, ZHOU Kai, ZHU Guangya, Et al., Effect and mechanism of silicone grease swelling on partial discharge at air-gap defects of XLPE-SiR interface, High Voltage Engineering, 47, 12, pp. 4245-4254, (2021)

[8]

HE Cong, LI Junhao, ZHANG Qian, Et al., Research status on the partial discharge characteristics of electrical equipment under overvoltage, High Voltage Apparatus, 54, 11, pp. 9-19, (2018)

[9]

CAI Jun, YUAN Wenze, ZHANG Xuanrui, Et al., Ultra-high frequency self-sensing detection method for transformer partial discharge, High Voltage Engineering, 47, 6, pp. 2041-2050, (2021)

[10]

JI H X, LI C R, MA G M, Et al., Partial discharge occurrence induced by crack defect on GIS insulator operated at 1 100 kV, IEEE Transactions on Dielectrics and Electrical Insulation, 23, 4, pp. 2250-2257, (2016)

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