How to Improve IEEE C57.104-2019 DGA Fault Severity Interpretation

2022 IEEE/PES Transmission and Distribution Conference and Exposition (T&D) Pub Date : 2022-04-25 DOI:10.1109/td43745.2022.9816859

Z. Draper, J. Dukarm, C. Beauchemin

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引用次数: 1

Abstract

This paper provides an example of how to improve DGA fault severity interpretation using screening test statistics and optimization curves with transformer failure data. Initial comparison of ‘cookbook’ fault severity methods in Draper & Dukarm 2021 [1] showed that IEEE C57.104-2019 had fallen short of its potential by not having a clearly defined status code higher than a 3. The IEEE guidelines provide for an undefined ‘Extreme DGA’ category which we attempt to define in this paper using failure data. We found that the overall performance of IEEE 2019 as a predictor of near-term transformer failure can be considerably improved by just multiplying the status code 3 limits by a factor of seven. Nevertheless, this simple modification to IEEE 2019 is not able to achieve as high of a positive predictive value or diagnostic odds ratio as PFS (IEC 60599–2015 / CIGRE TB 771) or Reliability-based DGA. Further algorithmic changes using population data with actual failure cases will be required to improve the performance of future DGA fault severity interpretation methods.

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如何改进IEEE C57.104-2019 DGA故障级别解释

本文以变压器故障数据为例，介绍了如何利用筛选试验统计数据和优化曲线改进DGA故障严重程度解释。对Draper & Dukarm 2021[1]中“食谱”故障严重性方法的初步比较表明，IEEE C57.104-2019没有明确定义高于3的状态码，因此没有发挥其潜力。IEEE指南提供了一个未定义的“极限DGA”类别，我们试图在本文中使用故障数据定义该类别。我们发现，通过将状态码3限制乘以7倍，IEEE 2019作为近期变压器故障预测器的整体性能可以大大提高。然而，这种对IEEE 2019的简单修改无法实现像PFS (IEC 60599-2015 / CIGRE TB 771)或基于可靠性的DGA那样高的阳性预测值或诊断优势比。为了提高未来DGA故障严重程度解释方法的性能，需要使用具有实际故障案例的种群数据进行进一步的算法更改。

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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2022 IEEE/PES Transmission and Distribution Conference and Exposition (T&D)

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