Traditional fault diagnosis methods for mineral oil-immersed power transformer based on dissolved gas analysis: Past, present and future

IF 3.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IET Nanodielectrics Pub Date : 2024-04-22 DOI:10.1049/nde2.12082
Arnaud Nanfak, Eke Samuel, Issouf Fofana, Fethi Meghnefi, Martial Gildas Ngaleu, Charles Hubert Kom
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Abstract

A key factor in ensuring the efficient and safe operation of power transformers is the early and accurate diagnosis of incipient faults. Among the tools available to achieve this goal, dissolved gas analysis (DGA) is widely used by power transformers' maintenance professionals. It is a preventive maintenance tool, used for condition monitoring, fault diagnosis and unplanned outage prevention. With the development of artificial intelligence (AI), many intelligent-based methods using AI tools have been proposed in the literature for DGA data interpretation. Although these methods achieve high diagnostic accuracies and improve DGA efficiency, they are generally complicated and the research documented in these publications is difficult to replicate. Traditional DGA-based methods are simple, easy to understand and implement, and widely used by power transformers' maintenance professionals. Many methods proposed in recent years overcome the limitations of the pioneer methods and are increasingly effective. The authors present a detailed and comprehensive literature review of the traditional DGA-based methods for mineral oil-immersed power transformer faults diagnosis. This review also addresses ways to improve the efficiency of the available traditional methods. Some pitfalls that need to be taken into account to improve the efficiency of the DGA-based diagnostic methods are also presented.

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基于溶解气体分析的矿物油浸式电力变压器传统故障诊断方法:过去、现在和未来
确保电力变压器高效安全运行的一个关键因素是及早准确地诊断出初期故障。在可用于实现这一目标的工具中,溶解气体分析 (DGA) 被电力变压器维护专业人员广泛使用。它是一种预防性维护工具,用于状态监测、故障诊断和意外停电预防。随着人工智能(AI)的发展,文献中提出了许多使用人工智能工具的基于智能的 DGA 数据解读方法。虽然这些方法能达到很高的诊断精度并提高 DGA 效率,但它们一般都很复杂,而且这些出版物中记录的研究很难复制。传统的基于 DGA 的方法简单、易于理解和实施,被电力变压器维护专业人员广泛使用。近年来提出的许多方法克服了先驱方法的局限性,而且越来越有效。作者对基于 DGA 的矿物油浸式电力变压器故障诊断传统方法进行了详细而全面的文献综述。这篇综述还探讨了如何提高现有传统方法的效率。此外,还介绍了提高基于 DGA 诊断方法效率所需注意的一些误区。
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来源期刊
IET Nanodielectrics
IET Nanodielectrics Materials Science-Materials Chemistry
CiteScore
5.60
自引率
3.70%
发文量
7
审稿时长
21 weeks
期刊最新文献
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