基于超声信号的金属化膜电容器老化状态评估方法

doi:10.19595/j.cnki.1000-6753.tces.241498

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摘要金属化膜电容器（MFC）是模块化多电平变流器（MMC）中较为薄弱的部件之一,准确地评估其健康状态对柔性直流输电系统的安全稳定运行意义重大。该文对MFC超声信号的局部放电相位分布（PRPD）谱图进行分析,提出一种基于健康指数公式的老化状态评估方法。首先,通过搭建超声监测试验平台采集声信号,分析MFC在老化过程中的失效机理;其次,基于自愈放电和局部放电比例的显著变化,探讨老化对PRPD谱图中放电信号分布的影响;最后在此基础上,构建基于健康指数公式的线性回归模型进行老化状态评估,并通过试验验证所提方法与模型的可行性和有效性。结果表明,与现有方法相比,该方法只需采集超声信号的PRPD谱图信息即可评估MFC当前的老化程度,解决了传统方法会对系统回路造成影响、抗干扰能力弱且监测精度较低的问题,为MMC的状态监测和寿命评估提供了新的手段,并为MFC非电量状态监测方法的研究奠定了基础。

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关键词 ：金属化膜电容器, 超声法, 局部放电相位分布（PRPD）谱图, 老化状态评估

Abstract：Metallized film capacitors (MFCs) are essential components in modular multilevel converters (MMCs) used for flexible direct current (DC) transmission. The assessment of their aging state is critical to ensuring the reliability of MMCs. This study aims to establish a non-intrusive aging evaluation method for MFCs based on the analysis of phase-resolved partial discharge (PRPD) spectra derived from ultrasonic signals, thereby providing real-time condition monitoring without interrupting system operation.
An experimental setup was constructed to facilitate accelerated aging of MFCs and to capture discharge events through ultrasonic sensing. Metallized polypropylene film capacitor samples, each with a rated capacitance of 18 µF and rated voltage of 2 kV, were subjected to an elevated voltage of 1.5 times their nominal rating under a controlled temperature of 65℃. The ultrasonic signals generated during discharge events were recorded using high-sensitivity ultrasonic sensors placed at the grounded terminals of the capacitors.
The recorded ultrasonic data were processed to obtain PRPD spectra, which characterize the discharge event phase distribution and amplitude. Several key metrics were extracted, including phase entropy, amplitude entropy, and their respective standard deviations. These metrics were used to construct a comprehensive health index (HI) that was combined with the observed capacitance decline data. A linear regression model was subsequently developed to relate the HI to the aging state, with optimal weights for the HI parameters determined through nonlinear optimization.
The experimental results revealed distinct changes in PRPD characteristics as aging progressed. Initially, the self-healing discharges dominated, but as the capacitor aged, partial discharges became more significant. As the capacitance degraded from 100% to 94% of its nominal value (C₀), the proportion of self-healing discharges decreased from 47.6% to 18.5%, while the proportion of partial discharges increased from 52.4% to 81.5%. The PRPD spectra showed that the phase distribution of discharges became more dispersed, while discharge amplitudes concentrated at lower levels during the aging process.
The health index effectively captured the trends in PRPD spectra, with the linear regression model demonstrating an error of less than 1 percentage point compared to offline capacitance measurements conducted using a high-precision bridge. This finding indicates that the health index can reliably represent the MFC aging state, providing a basis for real-time evaluation without invasive electrical testing.
The proposed method presents a novel, non-intrusive approach for assessing the aging of metallized polypropylene film capacitors, particularly suitable for use in MMCs within flexible DC transmission systems. The ultrasonic-based analysis of PRPD spectra not only avoids interference with electrical circuitry but also provides strong anti-interference capability and high precision. The health index, constructed from phase entropy, amplitude entropy, and their standard deviations, correlates effectively with the decline in capacitance, enabling a quantitative assessment of the aging state. This contributes to the development of non-electrical parameter-based monitoring techniques for power electronic capacitors.
Future work will focus on further refining the health index model and exploring its application to other capacitor types or components in high-voltage power systems. Expanding the use of non-electrical monitoring parameters could enhance the reliability of aging assessment methods in critical power electronics applications.

Key words： Metallized film capacitors ultrasound method phase-resolved partial discharge (PRPD) spectrogram aging status assessment

收稿日期: 2024-08-24

PACS:

TM536

基金资助:国家重点研发计划资助项目（2023YFB2406900）

通讯作者: 汲胜昌, 男,1976年生,教授,博士生导师,研究方向为电力设备在线监测及故障诊断、振动噪声机理及抑制技术。E-mail：jsc@xjtu.edu.cn

作者简介: 许馨愉, 女,2002年生,硕士研究生,研究方向为柔性直流输电用金属化膜电容器状态劣化特性及检测实验方法。E-mail：460232@stu.xjtu.edu.cn

引用本文:

许馨愉, 汲胜昌, 郑琳子, 闫昕旖, 祝令瑜. 基于超声信号的金属化膜电容器老化状态评估方法[J]. 电工技术学报, 2025, 40(5): 1652-1661. Xu Xinyu, Ji Shengchang, Zheng Linzi, Yan Xinyi, Zhu Lingyu. Aging State Evaluation Method of Metallized Film Capacitors Based on Ultrasonic Signals. Transactions of China Electrotechnical Society, 2025, 40(5): 1652-1661.

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