Phase-shift-controlled three-level converter with reduced voltage stress featuring ZVS over the full operation range

J.L. Duarte; J. Lokos; F.B.M. Horck, van

doi:10.1109/TPEL.2012.2215345

Phase-shift-controlled three-level converter with reduced voltage stress featuring ZVS over the full operation range

J.L. Duarte, J. Lokos, F.B.M. Horck, van

Research output: Contribution to journal › Article › Academic › peer-review

49 Citations (Scopus)

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Abstract

The simplicity of phase-shift control at fixed switching frequency and 50% duty-cycle operation is fully exploited by the proposed converter topology. The transistor voltages are clamped to only 50% of the dc input, the dc bus capacitive dividers being naturally stabilized. Furthermore, zero-voltage switching for all switches is guaranteed from no-load to full-load conditions, that is to say, from zero to nominal output voltage and from zero to nominal load current. As such, the proposed topology is an excellent candidate for demanding applications as compact battery chargers for electric vehicles. Experimental results obtained from a 400-80-V/0-360-V/2-kW/100-kHz prototype support the theoretical analysis.

Original language	English
Pages (from-to)	2140-2150
Number of pages	11
Journal	IEEE Transactions on Power Electronics
Volume	28
Issue number	5
DOIs	https://doi.org/10.1109/TPEL.2012.2215345
Publication status	Published - 2013

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abstract = "The simplicity of phase-shift control at fixed switching frequency and 50% duty-cycle operation is fully exploited by the proposed converter topology. The transistor voltages are clamped to only 50% of the dc input, the dc bus capacitive dividers being naturally stabilized. Furthermore, zero-voltage switching for all switches is guaranteed from no-load to full-load conditions, that is to say, from zero to nominal output voltage and from zero to nominal load current. As such, the proposed topology is an excellent candidate for demanding applications as compact battery chargers for electric vehicles. Experimental results obtained from a 400-80-V/0-360-V/2-kW/100-kHz prototype support the theoretical analysis.",

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N2 - The simplicity of phase-shift control at fixed switching frequency and 50% duty-cycle operation is fully exploited by the proposed converter topology. The transistor voltages are clamped to only 50% of the dc input, the dc bus capacitive dividers being naturally stabilized. Furthermore, zero-voltage switching for all switches is guaranteed from no-load to full-load conditions, that is to say, from zero to nominal output voltage and from zero to nominal load current. As such, the proposed topology is an excellent candidate for demanding applications as compact battery chargers for electric vehicles. Experimental results obtained from a 400-80-V/0-360-V/2-kW/100-kHz prototype support the theoretical analysis.

AB - The simplicity of phase-shift control at fixed switching frequency and 50% duty-cycle operation is fully exploited by the proposed converter topology. The transistor voltages are clamped to only 50% of the dc input, the dc bus capacitive dividers being naturally stabilized. Furthermore, zero-voltage switching for all switches is guaranteed from no-load to full-load conditions, that is to say, from zero to nominal output voltage and from zero to nominal load current. As such, the proposed topology is an excellent candidate for demanding applications as compact battery chargers for electric vehicles. Experimental results obtained from a 400-80-V/0-360-V/2-kW/100-kHz prototype support the theoretical analysis.

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Phase-shift-controlled three-level converter with reduced voltage stress featuring ZVS over the full operation range

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