Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply

Zhixing Yan; Yuan Gao; Gao Liu; Shaokang Luan; Morten Rahr Nielsen; Bjorn Rannestad; Hongbo Zhao; Stig Munk-Nielsen

doi:10.1109/ECCE55643.2024.10861793

Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply

Zhixing Yan^*, Yuan Gao, Gao Liu, Shaokang Luan, Morten Rahr Nielsen, Bjorn Rannestad, Hongbo Zhao, Stig Munk-Nielsen

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Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

Abstract

With the advancement of medium-voltage power devices, ensuring robust isolation and interference immunity for medium-voltage gate drivers has become a critical focus in both industry and academia. Among the critical components, the gate-driver power supply transformer poses the most significant challenge. Typically, the voltages on either side of the winding remain in the range of tens of volts, while the primary-to-secondary voltage difference can be thousands of volts. To address this unique application, this paper provides detailed insights into partial discharge considerations for improving design. Simulation results reveal that the electric field distribution of the improved transformer becomes more uniform. Furthermore, partial-discharge test results demonstrate a remarkable 74% increase in the partial-discharge inception voltage. Additionally, the paper conducts a 6 kV / 30 A double pulse test and continuous test, showcasing robust performance of the transformer.

Originalsprog	Engelsk
Titel	2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 - Proceedings
Antal sider	5
Forlag	IEEE (Institute of Electrical and Electronics Engineers)
Publikationsdato	2024
Sider	6841-6845
ISBN (Trykt)	979-8-3503-7605-0, 979-8-3503-7607-4
ISBN (Elektronisk)	979-8-3503-7606-7
DOI	https://doi.org/10.1109/ECCE55643.2024.10861793
Status	Udgivet - 2024
Begivenhed	2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 - Phoenix, USA Varighed: 20 okt. 2024 → 24 okt. 2024

Konference

Konference	2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024
Land/Område	USA
By	Phoenix
Periode	20/10/2024 → 24/10/2024
Sponsor	ABB Group, COMSOL, et al., Hioki USA Corporation, How2Power.Com, John Deere

Navn	IEEE Energy Conversion Congress and Exposition (ECCE)
ISSN	2329-3748

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Publisher Copyright:
© 2024 IEEE.

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10.1109/ECCE55643.2024.10861793

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Citationsformater

Yan, Z., Gao, Y., Liu, G., Luan, S., Nielsen, M. R., Rannestad, B., Zhao, H., & Munk-Nielsen, S. (2024). Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply. I 2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 - Proceedings (s. 6841-6845). IEEE (Institute of Electrical and Electronics Engineers). https://doi.org/10.1109/ECCE55643.2024.10861793

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title = "Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply",

abstract = "With the advancement of medium-voltage power devices, ensuring robust isolation and interference immunity for medium-voltage gate drivers has become a critical focus in both industry and academia. Among the critical components, the gate-driver power supply transformer poses the most significant challenge. Typically, the voltages on either side of the winding remain in the range of tens of volts, while the primary-to-secondary voltage difference can be thousands of volts. To address this unique application, this paper provides detailed insights into partial discharge considerations for improving design. Simulation results reveal that the electric field distribution of the improved transformer becomes more uniform. Furthermore, partial-discharge test results demonstrate a remarkable 74% increase in the partial-discharge inception voltage. Additionally, the paper conducts a 6 kV / 30 A double pulse test and continuous test, showcasing robust performance of the transformer.",

keywords = "Gate driver power supply, Medium voltage, Partial discharge, transformer",

author = "Zhixing Yan and Yuan Gao and Gao Liu and Shaokang Luan and Nielsen, {Morten Rahr} and Bjorn Rannestad and Hongbo Zhao and Stig Munk-Nielsen",

note = "Publisher Copyright: {\textcopyright} 2024 IEEE.; 2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 ; Conference date: 20-10-2024 Through 24-10-2024",

year = "2024",

doi = "10.1109/ECCE55643.2024.10861793",

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isbn = "979-8-3503-7605-0",

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Yan, Z , Gao, Y , Liu, G , Luan, S , Nielsen, MR, Rannestad, B, Zhao, H & Munk-Nielsen, S 2024, Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply. i 2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 - Proceedings. IEEE (Institute of Electrical and Electronics Engineers), IEEE Energy Conversion Congress and Exposition (ECCE), s. 6841-6845, 2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024, Phoenix, USA, 20/10/2024. https://doi.org/10.1109/ECCE55643.2024.10861793

Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply. / Yan, Zhixing ; Gao, Yuan ; Liu, Gao et al.
2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 - Proceedings. IEEE (Institute of Electrical and Electronics Engineers), 2024. s. 6841-6845 (IEEE Energy Conversion Congress and Exposition (ECCE)).

Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

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AU - Yan, Zhixing

AU - Gao, Yuan

AU - Liu, Gao

AU - Luan, Shaokang

AU - Nielsen, Morten Rahr

AU - Rannestad, Bjorn

AU - Zhao, Hongbo

AU - Munk-Nielsen, Stig

PY - 2024

Y1 - 2024

N2 - With the advancement of medium-voltage power devices, ensuring robust isolation and interference immunity for medium-voltage gate drivers has become a critical focus in both industry and academia. Among the critical components, the gate-driver power supply transformer poses the most significant challenge. Typically, the voltages on either side of the winding remain in the range of tens of volts, while the primary-to-secondary voltage difference can be thousands of volts. To address this unique application, this paper provides detailed insights into partial discharge considerations for improving design. Simulation results reveal that the electric field distribution of the improved transformer becomes more uniform. Furthermore, partial-discharge test results demonstrate a remarkable 74% increase in the partial-discharge inception voltage. Additionally, the paper conducts a 6 kV / 30 A double pulse test and continuous test, showcasing robust performance of the transformer.

AB - With the advancement of medium-voltage power devices, ensuring robust isolation and interference immunity for medium-voltage gate drivers has become a critical focus in both industry and academia. Among the critical components, the gate-driver power supply transformer poses the most significant challenge. Typically, the voltages on either side of the winding remain in the range of tens of volts, while the primary-to-secondary voltage difference can be thousands of volts. To address this unique application, this paper provides detailed insights into partial discharge considerations for improving design. Simulation results reveal that the electric field distribution of the improved transformer becomes more uniform. Furthermore, partial-discharge test results demonstrate a remarkable 74% increase in the partial-discharge inception voltage. Additionally, the paper conducts a 6 kV / 30 A double pulse test and continuous test, showcasing robust performance of the transformer.

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ER -

Yan Z , Gao Y , Liu G , Luan S , Nielsen MR, Rannestad B et al. Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply. I 2024 IEEE Energy Conversion Congress and Exposition, ECCE 2024 - Proceedings. IEEE (Institute of Electrical and Electronics Engineers). 2024. s. 6841-6845. (IEEE Energy Conversion Congress and Exposition (ECCE)). doi: 10.1109/ECCE55643.2024.10861793

Partial Discharge Improvements of Isolated Transformer in Medium-Voltage Gate-Driver Power Supply

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