持续电压下环氧灌封绝缘界面缺陷危害性分析

doi:10.19595/j.cnki.1000-6753.tces.250720

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摘要材料内部缺陷产生的局部放电是导致环氧灌封电力设备绝缘失效的常见诱因,而传统局部放电诊断方法难以准确评估缺陷部位放电对设备绝缘的危害程度。该文制备了贴真的环氧树脂气泡、裂纹和脱层缺陷样品,选取最大放电幅值、放电频次和平均放电幅值作为放电强度的评估指标,研究了交流工况下不同缺陷局部放电强度随时间的变化规律,结合实验分析了局部放电对缺陷内部初始有效电子产生速度的影响。结果表明,在持续交流电压的作用下,裂纹缺陷的放电强度发展最快,分层缺陷次之,气泡缺陷最慢。持续的局部放电会削弱缺陷内部气体的自然电离,进而可能导致放电信号消失。依据放电能否持续可进一步划分不同尺度气泡缺陷的危险等级,从高到低依次为：裂纹缺陷、脱层缺陷、可持续放电的气泡缺陷以及不可持续的气泡缺陷。研究结果有助于评估材料内部局部放电对设备绝缘的危害程度。

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关键词 ：环氧树脂灌封绝缘, 自然微缺陷, 局部放电, 放电强度发展速度, 绝缘评估

Abstract：Epoxy resin is widely used in the manufacturing of insulation components for various power equipment due to its excellent properties. Currently, the vacuum degassing process is usually adopted to avoid air gaps. However, some tiny defects still cannot be totally avoided. Partial discharge (PD) generated at internal defects in materials is a common cause of insulation failure in epoxy-potted power equipment. It should be noted that the appearance of PD signals does not necessarily mean that the equipment has lost its normal operation capability. However, traditional PD diagnostic techniques often fail to precisely evaluate the insulation hazard level caused by discharge activities. In response to this situation, this article deeply explores the discharge intensity development speed of three epoxy resin micro-defects under continuous PD. Based on the differences in the discharge intensity development speed, the hazard levels of different defects to the insulation are classified.
Firstly, a new method for preparing epoxy potting defects, including bubble, crack, and delamination defects, was adopted. The simulated defects prepared by this method were very similar to the actual defects in terms of defect scale and other aspects. The method for assessing the hazard level of defects was as follows: First, compare whether there are macroscopic changes in the defect samples before and after the experiment; Second, analyze the variation of the discharge intensity over time. Three parameters, namely maximum discharge magnitude, discharge frequency, and average discharge magnitude, were selected as quantitative indicators to assess PD intensity. It was found that the crack defect samples exhibited dielectric breakdown within 30 minutes under sustained AC voltage. However, both bubble and delamination defect samples showed no significant macroscopic changes after 150 minutes of continuous voltage application. The relationship between discharge intensity and time was statistically analyzed, and the results showed that under sustained AC voltage, the discharge intensity of bubble defects weakened with time, while that of the delamination defects strengthened with time. Moreover, it was observed that the discharge intensity of some bubble defects first weakened and then basically stabilized, whereas that of another group of bubble defects gradually weakened until it disappeared. Therefore, semi-enclosed bubble defect samples were prepared for research. Based on the discharge sustainability, the hazard level of bubble defects to insulation could be further classified.
The following conclusions can be drawn from the experiment analysis: (1) Under sustained AC voltage, significant macroscopic changes are observed in the crack defects before and after the experiment, whereas the bubble and delamination defects exhibit no comparable macroscopic variations. Therefore, the hazard level of the crack defect is higher than that of the bubble and delamination defects. (2) Under sustained AC voltage, the discharge intensity of the delamination defect shows an increasing trend with time. By contrast, the bubble defect demonstrates a gradual attenuation in discharge intensity over time. Therefore, the hazard level of the delamination defect is higher than that of the bubble defect. (3) Continuous PD will suppress the natural ionization of the gas inside the defect, which may lead to the disappearance of the discharge signal. Based on the continuity of discharge, the hazard level of the bubble defect can be further classified. That is, bubble defects with persistent discharge are more hazardous than those with non-persistent discharge.

Key words： Epoxy resin potting insulation natural micro-defects partial discharge discharge intensity development speed insulation assessment

收稿日期: 2025-04-30

PACS:

TM85

基金资助:国家重点研发计划资助项目（2023YFB2406900）

通讯作者: 任明男,1987年生,教授,博士生导师,研究方向为电力设备故障诊断及高电压试验新技术等。E-mail：renming@mail.xjtu.edu.cn

作者简介: 王腾腾男,2001年生,硕士研究生,研究方向为环氧灌封电力设备局部放电检测与状态评估技术。E-mail：20230201@stu.xjtu.edu.cn

引用本文:

王腾腾, 李旭东, 周沁昱, 刘润宇, 任明. 持续电压下环氧灌封绝缘界面缺陷危害性分析[J]. 电工技术学报, 2026, 41(7): 2510-2520. Wang Tengteng, Li Xudong, Zhou Qinyu, Liu Runyu, Ren Ming. Analysis of the Hazard of Interface Defects in Epoxy Encapsulation Insulation under Sustained Voltage. Transactions of China Electrotechnical Society, 2026, 41(7): 2510-2520.

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https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.250720 https://dgjsxb.ces-transaction.com/CN/Y2026/V41/I7/2510

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