新型大容量同步冷凝器故障分析与远程故障诊断技术研究

Jiang Chen, Sun Chuan, Xia Chao
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摘要

同步电容器具有无功容量大、电压支持能力强等显著优势,可有效解决特高压直流换流器换向故障和电压跌落等突出问题。它们在电网中的应用越来越广泛。然而,大容量凝汽器体积大、结构复杂、故障易发,急需开展故障特征分析与诊断技术研究。本文分析了大容量同步电容器的特点及其工程优势,如提高受端电网的短路率,提高输电极限功率,在特高压直流受端换流故障时工作在强制励磁状态以提供电压支持,在直流闭锁时吸收多余的无功功率以抑制电压骤升,以及通过灵活切换迟相或导相状态为交流电网提供动态可调的无功支持等。本文介绍了常见的故障,如质量不平衡、不对中、摩擦、油膜振荡等。同时,采用计算机仿真分析、实验室仿真分析和现场测量测试方法对故障特征进行了分析。在此基础上,利用故障模式识别和可信度评估,提出了同步冷凝器的标准故障诊断方法。通过建立同步冷凝器故障模型库,并采用时域和频域信号分析技术,利用特征值计算采样信号的瞬时值和变化率,从而确定故障的可信度和性质。通过对相关标准和历史数据的比较和分析,确定了故障的严重程度,以及问题同步冷凝器的趋势和严重程度。这项研究的结果进一步推动了大容量同步冷凝器故障诊断技术的发展。
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Research on Fault Analysis and Remote Fault Diagnosis Technology of New Large Capacity Synchronous Condenser
Synchronous condensers offer significant benefits in large reactive power capacity and strong voltage support ability, which can effectively solve prominent problems such as commutation failure and voltage drop of ultra-high voltage DC converters. They are increasingly widely used in power grids. However, the large-capacity condenser has a large volume and complex structure and is prone to faults, which urgently requires research on fault feature analysis and diagnosis technology. This article analyzes the features of large-capacity synchronous condensers and their engineering advantages, such as increasing the short-circuit ratio of the receiving power grid, improving the transmission limit power, working in a forced excitation state for voltage support in the event of a commutation failure at the UHVDC receiving end, absorbing excess reactive power to suppress sudden voltage rise during DC blocking, and providing dynamically adjustable reactive power support for the AC power grid through flexible switching of late or leading phase states. This article provides common faults, such as mass imbalance, misalignment, friction, oil film oscillation, etc. At the same time, the fault characteristics are analyzed using computer simulation analysis, laboratory simulation analysis, and on-site measurement testing methods. A standard fault diagnosis method for synchronous condensers is proposed on this basis, utilizing fault pattern recognition and credibility evaluation. By establishing a library of fault models for the synchronous condenser and employing time-domain and frequency-domain signal analysis techniques, the credibility and nature of the fault are determined by calculating the instantaneous values and rate of change of the sampled signal using eigenvalues. Through the comparison and analysis of pertinent standards and historical data, the severity of the fault is ascertained, along with the trend and severity of the problematic synchronous condenser. The findings of this study have additionally advanced the progress of fault diagnosis technology for synchronous condensers with large capacities.
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