Simulation of nanofluid as a two-phase flow in a distribution transformer

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

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  • Ferdowsi University of Mashhad (FUM)
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Details

OriginalspracheEnglisch
Titel des Sammelwerks2019 IEEE Electrical Insulation Conference, EIC 2019
UntertitelProceedings
Herausgeber (Verlag)Institute of Electrical and Electronics Engineers Inc.
Seiten258-261
Seitenumfang4
ISBN (elektronisch)978-1-5386-7624-0
ISBN (Print)978-1-5386-7625-7
PublikationsstatusVeröffentlicht - Juni 2019
Veranstaltung2019 IEEE Electrical Insulation Conference, EIC 2019 - Calgary, Kanada
Dauer: 16 Juni 201919 Juni 2019

Publikationsreihe

NameElectrical Insulation Conference and Electrical Manufacturing Expo
Band2019-June
ISSN (Print)2334-0975
ISSN (elektronisch)2576-6791

Abstract

In this article, the natural convection heat transfer of Fe304/oil and graphene/oil nanofluids and mineral oil inside a 200 kVA distribution transformer is numerically studied. The Fe304/oil and graphene/oil nanofluids were simulated as a mixture two-phase flow where mineral oil was modeled as a single-phase flow with the temperature dependent thermophysical properties. Based on the simulation results, the nanoparticles when dispersed in oil enhance the convective heat transfer of oil and decrease its hotspot temperature. So that, the hotspot temperature of the Fe304/oil and graphene/oil were respectively 1 °C and 4.5 °C lower than that of the mineral oil. In addition, the transformer filled with graphene/oil nanofluid experienced considerably lower temperature in the thermally critical region. According to the obtained results, employing the nanofluid improves the cooling performance of the transformer, which leads to a more reliable operation and longer life.

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Simulation of nanofluid as a two-phase flow in a distribution transformer. / Raeisian, Leyla; Werle, Peter; Niazmand, Hamid.
2019 IEEE Electrical Insulation Conference, EIC 2019: Proceedings. Institute of Electrical and Electronics Engineers Inc., 2019. S. 258-261 9046609 (Electrical Insulation Conference and Electrical Manufacturing Expo; Band 2019-June).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Raeisian, L, Werle, P & Niazmand, H 2019, Simulation of nanofluid as a two-phase flow in a distribution transformer. in 2019 IEEE Electrical Insulation Conference, EIC 2019: Proceedings., 9046609, Electrical Insulation Conference and Electrical Manufacturing Expo, Bd. 2019-June, Institute of Electrical and Electronics Engineers Inc., S. 258-261, 2019 IEEE Electrical Insulation Conference, EIC 2019, Calgary, Kanada, 16 Juni 2019. https://doi.org/10.1109/EIC43217.2019.9046609
Raeisian, L., Werle, P., & Niazmand, H. (2019). Simulation of nanofluid as a two-phase flow in a distribution transformer. In 2019 IEEE Electrical Insulation Conference, EIC 2019: Proceedings (S. 258-261). Artikel 9046609 (Electrical Insulation Conference and Electrical Manufacturing Expo; Band 2019-June). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/EIC43217.2019.9046609
Raeisian L, Werle P, Niazmand H. Simulation of nanofluid as a two-phase flow in a distribution transformer. in 2019 IEEE Electrical Insulation Conference, EIC 2019: Proceedings. Institute of Electrical and Electronics Engineers Inc. 2019. S. 258-261. 9046609. (Electrical Insulation Conference and Electrical Manufacturing Expo). doi: 10.1109/EIC43217.2019.9046609
Raeisian, Leyla ; Werle, Peter ; Niazmand, Hamid. / Simulation of nanofluid as a two-phase flow in a distribution transformer. 2019 IEEE Electrical Insulation Conference, EIC 2019: Proceedings. Institute of Electrical and Electronics Engineers Inc., 2019. S. 258-261 (Electrical Insulation Conference and Electrical Manufacturing Expo).
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abstract = "In this article, the natural convection heat transfer of Fe304/oil and graphene/oil nanofluids and mineral oil inside a 200 kVA distribution transformer is numerically studied. The Fe304/oil and graphene/oil nanofluids were simulated as a mixture two-phase flow where mineral oil was modeled as a single-phase flow with the temperature dependent thermophysical properties. Based on the simulation results, the nanoparticles when dispersed in oil enhance the convective heat transfer of oil and decrease its hotspot temperature. So that, the hotspot temperature of the Fe304/oil and graphene/oil were respectively 1 °C and 4.5 °C lower than that of the mineral oil. In addition, the transformer filled with graphene/oil nanofluid experienced considerably lower temperature in the thermally critical region. According to the obtained results, employing the nanofluid improves the cooling performance of the transformer, which leads to a more reliable operation and longer life.",
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Download

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AU - Werle, Peter

AU - Niazmand, Hamid

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N2 - In this article, the natural convection heat transfer of Fe304/oil and graphene/oil nanofluids and mineral oil inside a 200 kVA distribution transformer is numerically studied. The Fe304/oil and graphene/oil nanofluids were simulated as a mixture two-phase flow where mineral oil was modeled as a single-phase flow with the temperature dependent thermophysical properties. Based on the simulation results, the nanoparticles when dispersed in oil enhance the convective heat transfer of oil and decrease its hotspot temperature. So that, the hotspot temperature of the Fe304/oil and graphene/oil were respectively 1 °C and 4.5 °C lower than that of the mineral oil. In addition, the transformer filled with graphene/oil nanofluid experienced considerably lower temperature in the thermally critical region. According to the obtained results, employing the nanofluid improves the cooling performance of the transformer, which leads to a more reliable operation and longer life.

AB - In this article, the natural convection heat transfer of Fe304/oil and graphene/oil nanofluids and mineral oil inside a 200 kVA distribution transformer is numerically studied. The Fe304/oil and graphene/oil nanofluids were simulated as a mixture two-phase flow where mineral oil was modeled as a single-phase flow with the temperature dependent thermophysical properties. Based on the simulation results, the nanoparticles when dispersed in oil enhance the convective heat transfer of oil and decrease its hotspot temperature. So that, the hotspot temperature of the Fe304/oil and graphene/oil were respectively 1 °C and 4.5 °C lower than that of the mineral oil. In addition, the transformer filled with graphene/oil nanofluid experienced considerably lower temperature in the thermally critical region. According to the obtained results, employing the nanofluid improves the cooling performance of the transformer, which leads to a more reliable operation and longer life.

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