A degradation model of synchronous generator stator insulation

Proceedings of the 37th Annual North American Power Symposium, 2005. Pub Date : 2005-12-19 DOI:10.1109/NAPS.2005.1560539

L.M. Monge-Guerrero, A. Irizarry-Rivera

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引用次数: 2

Abstract

In this work the authors present a degradation model of generator stator insulation to compute failure probabilities. This may in turn be used to develop risk-based maintenance for synchronous generators. First, generators different failure modes were identified and studied. The most common failure mode encountered was failure of the stator winding insulation. Following Simoni's insulation deterioration model, a mathematical-theoretical insulation degradation model of the stator winding insulation was developed. The model measures degradation in electrical strength through time as a function of generator's voltage and current. An example for a generator of 13.8 kV and 100 MVA is presented. The results show for the case where the applied voltage and current were at normal operating condition, the winding insulation last approximately three months, while the case at highest applied voltage and highest increase in current, the insulation last a few hours. Complete and reliable data on generators is still needed in order to verify the model and to calculate failure probabilities.

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同步发电机定子绝缘退化模型

在这项工作中，作者提出了一种发电机定子绝缘退化模型，用于计算故障概率。这反过来又可用于为同步发电机制定基于风险的维护。首先，确定并研究了发电机的不同故障模式。最常见的故障模式是定子绕组绝缘失效。按照 Simoni 的绝缘劣化模型，开发了定子绕组绝缘劣化的数学理论模型。该模型根据发电机电压和电流的函数来测量电气强度随时间的衰减。以一台 13.8 千伏、100 兆伏安的发电机为例进行说明。结果显示，在外加电压和电流处于正常运行状态的情况下，绕组绝缘可持续约三个月，而在外加电压最高、电流增加最大的情况下，绝缘可持续数小时。为了验证模型和计算故障概率，仍需要完整可靠的发电机数据。

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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Proceedings of the 37th Annual North American Power Symposium, 2005.

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