Coupled numerical modelling of power loss generation in busbar system of low-voltage switchgear

Coupled numerical modelling of power loss generation in busbar system of low-voltage switchgear

This paper presents a coupled mathematical model of the heat transfer processes in an electric switchgear. The considered problem required the computation of the detailed distribution of the power losses and all the heat transfer modes (radiation, convection, and conduction) within a unit. In this c...

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Veröffentlicht in:International journal of thermal sciences 2014-08, Vol.82 (82), p.122-129
Hauptverfasser: Bedkowski, Mateusz, Smolka, Jacek, Banasiak, Krzysztof, Bulinski, Zbigniew, Nowak, Andrzej J., Tomanek, Tomasz, Wajda, Adam
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Sprache:eng
Schlagworte:
Applied sciences
Busbar system
Busbars
Computation
Conduction heating
Connection and protection apparatus
Electrical engineering. Electrical power engineering
Exact sciences and technology
Heat transfer
Joining
Mathematical models
Power loss
Switchgear
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container_end_page 129
container_issue 82
container_start_page 122
container_title International journal of thermal sciences
container_volume 82
creator Bedkowski, Mateusz
Smolka, Jacek
Banasiak, Krzysztof
Bulinski, Zbigniew
Nowak, Andrzej J.
Tomanek, Tomasz
Wajda, Adam
description This paper presents a coupled mathematical model of the heat transfer processes in an electric switchgear. The considered problem required the computation of the detailed distribution of the power losses and all the heat transfer modes (radiation, convection, and conduction) within a unit. In this complex thermal analysis, different definitions of electric busbar heating were considered and compared. The most advanced model, which couples the thermal and electromagnetic fields in two ways, was also compared with the simplified approaches. First, the direct current loading of the busbar, which neglected the alternating current effects, was considered. Second, models that included only one method of coupling were calculated for different assumed average busbar temperatures. Finally, the model with the two-way coupling, which took the eddy currents and proximity effects into account, was simulated using an iteration loop between the electromagnetic and fluid flow solvers. This study employed a geometrical model of industrial low-voltage switchgear. The presented mathematical model was also validated against temperature measurements carried out by a certified laboratory. The obtained results show that a fully coupled model produces very satisfactory agreement between computed and experimental data. •Coupled thermal and electromagnetic model of switchgear was formulated.•Different formulations of power loss in busbars were examined.•Hotspots in industrial switchgear were identified.
doi_str_mv 10.1016/j.ijthermalsci.2014.04.001
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The considered problem required the computation of the detailed distribution of the power losses and all the heat transfer modes (radiation, convection, and conduction) within a unit. In this complex thermal analysis, different definitions of electric busbar heating were considered and compared. The most advanced model, which couples the thermal and electromagnetic fields in two ways, was also compared with the simplified approaches. First, the direct current loading of the busbar, which neglected the alternating current effects, was considered. Second, models that included only one method of coupling were calculated for different assumed average busbar temperatures. Finally, the model with the two-way coupling, which took the eddy currents and proximity effects into account, was simulated using an iteration loop between the electromagnetic and fluid flow solvers. This study employed a geometrical model of industrial low-voltage switchgear. The presented mathematical model was also validated against temperature measurements carried out by a certified laboratory. The obtained results show that a fully coupled model produces very satisfactory agreement between computed and experimental data. •Coupled thermal and electromagnetic model of switchgear was formulated.•Different formulations of power loss in busbars were examined.•Hotspots in industrial switchgear were identified.</description><identifier>ISSN: 1290-0729</identifier><identifier>EISSN: 1778-4166</identifier><identifier>DOI: 10.1016/j.ijthermalsci.2014.04.001</identifier><language>eng</language><publisher>Kidlington: Elsevier Masson SAS</publisher><subject>Applied sciences ; Busbar system ; Busbars ; Computation ; Conduction heating ; Connection and protection apparatus ; Electrical engineering. 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The considered problem required the computation of the detailed distribution of the power losses and all the heat transfer modes (radiation, convection, and conduction) within a unit. In this complex thermal analysis, different definitions of electric busbar heating were considered and compared. The most advanced model, which couples the thermal and electromagnetic fields in two ways, was also compared with the simplified approaches. First, the direct current loading of the busbar, which neglected the alternating current effects, was considered. Second, models that included only one method of coupling were calculated for different assumed average busbar temperatures. Finally, the model with the two-way coupling, which took the eddy currents and proximity effects into account, was simulated using an iteration loop between the electromagnetic and fluid flow solvers. This study employed a geometrical model of industrial low-voltage switchgear. The presented mathematical model was also validated against temperature measurements carried out by a certified laboratory. The obtained results show that a fully coupled model produces very satisfactory agreement between computed and experimental data. •Coupled thermal and electromagnetic model of switchgear was formulated.•Different formulations of power loss in busbars were examined.•Hotspots in industrial switchgear were identified.</description><subject>Applied sciences</subject><subject>Busbar system</subject><subject>Busbars</subject><subject>Computation</subject><subject>Conduction heating</subject><subject>Connection and protection apparatus</subject><subject>Electrical engineering. 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The presented mathematical model was also validated against temperature measurements carried out by a certified laboratory. The obtained results show that a fully coupled model produces very satisfactory agreement between computed and experimental data. •Coupled thermal and electromagnetic model of switchgear was formulated.•Different formulations of power loss in busbars were examined.•Hotspots in industrial switchgear were identified.</abstract><cop>Kidlington</cop><pub>Elsevier Masson SAS</pub><doi>10.1016/j.ijthermalsci.2014.04.001</doi><tpages>8</tpages></addata></record>
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source Elsevier ScienceDirect Journals
subjects Applied sciences
Busbar system
Busbars
Computation
Conduction heating
Connection and protection apparatus
Electrical engineering. Electrical power engineering
Exact sciences and technology
Heat transfer
Joining
Mathematical models
Power loss
Switchgear
title Coupled numerical modelling of power loss generation in busbar system of low-voltage switchgear
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