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Determination of relative thermal performance of power transformers using data driven thermal models

Determination of relative thermal performance of power transformers using data driven thermal models
Determination of relative thermal performance of power transformers using data driven thermal models
Reliability of power transformers is essential for managing electrical power transmission systems. Condition monitoring is needed to ensure that power transformers work as expected. A critical parameter used in condition monitoring is the hot spot temperature, which is governed by the thermal performance of the unit. Transformers are type tested during commissioning to guarantee that the temperature rise above ambient conditions does not exceed 78°C at their maximum capacity. However, thermal performance could change over a long period of time due to ageing. Generally, a transformer has sister units that are ordered at the same time and have the same specification, this group of units is referred to as a transformer family. Theoretically, thermal performance of transformers in the same family should be identical. However, due to ageing and different loading conditions, thermal performance could gradually diverge within a family. In this paper, thermal models for power transformers developed using Gaussian process regression are proposed. Once transformer thermal models for each transformer have been built, they are used to predict the transformer temperature of sister units. Typically, the average errors between the measurement and prediction made by the thermal model using its own data should be about zero, however, the average errors that are generated by the thermal model of the sister transformer could be positive or negative, if the thermal behavior between them is significantly divergent. The proposed method has been validated using data for three 400kV/275kV autotransformers and has been shown to work effectively.
362-365
IEEE
Doolgindachbaporn, Atip
671b2094-83bc-463d-873c-d9ea9decefcd
Callender, George
4189d79e-34c3-422c-a601-95b156c27e76
Lewin, Paul
78b4fc49-1cb3-4db9-ba90-3ae70c0f639e
Simonson, Edward
1fb30844-83ef-48c4-95bf-e9eaef5b89d5
Wilson, Gordon
fd02d259-a5b6-44ce-be29-47073c552c5b
Doolgindachbaporn, Atip
671b2094-83bc-463d-873c-d9ea9decefcd
Callender, George
4189d79e-34c3-422c-a601-95b156c27e76
Lewin, Paul
78b4fc49-1cb3-4db9-ba90-3ae70c0f639e
Simonson, Edward
1fb30844-83ef-48c4-95bf-e9eaef5b89d5
Wilson, Gordon
fd02d259-a5b6-44ce-be29-47073c552c5b

Doolgindachbaporn, Atip, Callender, George, Lewin, Paul, Simonson, Edward and Wilson, Gordon (2022) Determination of relative thermal performance of power transformers using data driven thermal models. In 2022 IEEE Electrical Insulation Conference (EIC). IEEE. pp. 362-365 . (doi:10.1109/EIC51169.2022.9833187).

Record type: Conference or Workshop Item (Paper)

Abstract

Reliability of power transformers is essential for managing electrical power transmission systems. Condition monitoring is needed to ensure that power transformers work as expected. A critical parameter used in condition monitoring is the hot spot temperature, which is governed by the thermal performance of the unit. Transformers are type tested during commissioning to guarantee that the temperature rise above ambient conditions does not exceed 78°C at their maximum capacity. However, thermal performance could change over a long period of time due to ageing. Generally, a transformer has sister units that are ordered at the same time and have the same specification, this group of units is referred to as a transformer family. Theoretically, thermal performance of transformers in the same family should be identical. However, due to ageing and different loading conditions, thermal performance could gradually diverge within a family. In this paper, thermal models for power transformers developed using Gaussian process regression are proposed. Once transformer thermal models for each transformer have been built, they are used to predict the transformer temperature of sister units. Typically, the average errors between the measurement and prediction made by the thermal model using its own data should be about zero, however, the average errors that are generated by the thermal model of the sister transformer could be positive or negative, if the thermal behavior between them is significantly divergent. The proposed method has been validated using data for three 400kV/275kV autotransformers and has been shown to work effectively.

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More information

Published date: 25 July 2022
Venue - Dates: IEEE Electrical Insulation Conference (EIC), Knoxville, United States, 2022-06-19 - 2022-06-23
Learn more about Electrical Power Engineering research

Identifiers

Local EPrints ID: 494417
URI: http://eprints.soton.ac.uk/id/eprint/494417
DOI: doi:10.1109/EIC51169.2022.9833187
PURE UUID: 5998adcd-281e-4db1-98d1-be7cd8709ee5
ORCID for Paul Lewin: ORCID iD orcid.org/0000-0002-3299-2556

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Date deposited: 07 Oct 2024 17:20
Last modified: 08 Oct 2024 01:33

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Contributors

Author: Atip Doolgindachbaporn
Author: George Callender
Author: Paul Lewin ORCID iD
Author: Edward Simonson
Author: Gordon Wilson

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