Power Transformer Condition Monitoring Based on Evaluating Oil Properties

Ivan V. Bryakin; Igor V. Bochkarev; Vadim R. Khramshin; Vadim R. Gasiyarov; Ivan V. Liubimov

doi:10.3390/machines10080630

Machines (Jul 2022)

Power Transformer Condition Monitoring Based on Evaluating Oil Properties

Ivan V. Bryakin,
Igor V. Bochkarev,
Vadim R. Khramshin,
Vadim R. Gasiyarov,
Ivan V. Liubimov

Affiliations

Ivan V. Bryakin: Institute of Mechanical Engineering and Automation, National Academy of Sciences of the Kyrgyz Republic, Bishkek 720010, Kyrgyzstan
Igor V. Bochkarev: Department of Electromechanics, Kyrgyz State Technical University named after I. Razzakov, Bishkek 720010, Kyrgyzstan
Vadim R. Khramshin: Power Engineering and Automated Systems Institute, Nosov Magnitogorsk State Technical University, 455000 Magnitogorsk, Russia
Vadim R. Gasiyarov: Department of Automation and Control, Moscow Polytechnic University, 107023 Moscow, Russia
Ivan V. Liubimov: Department of Mechatronics and Automation, South Ural State University, 454080 Chelyabinsk, Russia

DOI: https://doi.org/10.3390/machines10080630
Journal volume & issue: Vol. 10, no. 8
p. 630

Abstract

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The authors review the techniques applied to diagnose oil aging. Further, the authors put forward a new diagnostic method. It stipulates for an additional high-frequency measuring loop formed in an operating transformer. This dielcometric measuring capacitor cell includes a stray capacitance generated by the transformer winding and core. The monitoring of the dependence between the physico–technological oil parameters and the measuring cell capacity is fundamental for the procedures for determining the composition and properties of the transformer oil filling this cell. High-frequency low-voltage is the output signal. To prevent the cross-impact of low-frequency high-voltage and high-frequency low-voltage circuits, the pilot high-frequency low-voltage is excited by a special coupling capacitor; the output to the power feeder is conducted through an appropriate low-frequency choke, where the measuring capacitor cell does not disturb the normal transformer operation. The key physical processes used for the monitoring are analyzed and described in detail. The authors develop an algorithm to compute the current resistances of both the transformer oil and its impurities. The transformer state is estimated by comparing the parameters specified with preset permissible limits. A structure flowchart based on two synchronous quadrature detectors is proposed for a high-frequency measuring loop. The monitoring system considered allows for determining the following insulating oil properties by using the algorithm for processing the recorded data: moisture content; dielectric losses due to the accumulation of aging products in the oil and its pollution; and the content of dissolved gases in the oil. The monitoring system operability and efficiency are confirmed by appropriate experimental studies. The experiments are conducted using a TM-25-6/0.4 oil-filled transformer with a capacity of 25 kVA in a steady-state operating mode at a load current of 25 A. It is found that the proposed control system allows for identifying a critical defect of increased moisture content in the oil with no more than 10% error, and a sensitivity threshold in the order of tenths of ppm.

Published in Machines

ISSN: 2075-1702 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Technology: Mechanical engineering and machinery
Website: http://www.mdpi.com/journal/machines

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