A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range
A new zero-voltage switching full-bridge dc-dc converter for battery charging is proposed in this paper. The proposed isolated dc-dc converter is used for the dc-dc conversion stage of the electric vehicle charger. The primary switches in dc-dc converter turn-on at zero voltage over the battery-char...
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sg-ntu-dr.10356-1413612021-01-13T02:17:20Z A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range Kanamarlapudi, Venkata Ravi Kishore Wang, Benfei Kandasamy, Nandha Kumar So, Ping Lam School of Electrical and Electronic Engineering Energy Research Institute @ NTU (ERI@N) Engineering::Electrical and electronic engineering Battery Charging Electric Vehicle (EV) Charger A new zero-voltage switching full-bridge dc-dc converter for battery charging is proposed in this paper. The proposed isolated dc-dc converter is used for the dc-dc conversion stage of the electric vehicle charger. The primary switches in dc-dc converter turn-on at zero voltage over the battery-charging range with the help of passive auxiliary circuit. The diode clamping circuit on the primary side minimizes the severity of voltage spikes across the secondary rectifier diodes, which are commonly present in conventional full-bridge dc-dc converters. The main switches are controlled with an asymmetrical pulse-width modulation (APWM) technique resulting in higher efficiency. APWM reduces the current stress of the main switches and the circulating losses compared with the conventional phase-shift modulation method by controlling the auxiliary inductor current over the entire operating range of the proposed converter. The steady-state analysis of auxiliary circuit and its design considerations are discussed in detail. A 100-kHz 1.2-kW full-bridge dc-dc converter prototype is developed. The experimental results are presented to validate the analysis and efficiency of the proposed converter. 2020-06-08T02:32:53Z 2020-06-08T02:32:53Z 2018 Journal Article Kanamarlapudi, V. R. K., Wang, B., Kandasamy, N. K., & So, P. L. (2018). A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range. IEEE Transactions on Industry Applications, 54(1), 571 - 579. doi:10.1109/TIA.2017.2756031 0093-9994 https://hdl.handle.net/10356/141361 10.1109/TIA.2017.2756031 2-s2.0-85040987336 1 54 571 579 en IEEE Transactions on Industry Applications © 2017 IEEE. All rights reserved. |
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Engineering::Electrical and electronic engineering Battery Charging Electric Vehicle (EV) Charger |
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Engineering::Electrical and electronic engineering Battery Charging Electric Vehicle (EV) Charger Kanamarlapudi, Venkata Ravi Kishore Wang, Benfei Kandasamy, Nandha Kumar So, Ping Lam A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range |
| description |
A new zero-voltage switching full-bridge dc-dc converter for battery charging is proposed in this paper. The proposed isolated dc-dc converter is used for the dc-dc conversion stage of the electric vehicle charger. The primary switches in dc-dc converter turn-on at zero voltage over the battery-charging range with the help of passive auxiliary circuit. The diode clamping circuit on the primary side minimizes the severity of voltage spikes across the secondary rectifier diodes, which are commonly present in conventional full-bridge dc-dc converters. The main switches are controlled with an asymmetrical pulse-width modulation (APWM) technique resulting in higher efficiency. APWM reduces the current stress of the main switches and the circulating losses compared with the conventional phase-shift modulation method by controlling the auxiliary inductor current over the entire operating range of the proposed converter. The steady-state analysis of auxiliary circuit and its design considerations are discussed in detail. A 100-kHz 1.2-kW full-bridge dc-dc converter prototype is developed. The experimental results are presented to validate the analysis and efficiency of the proposed converter. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Kanamarlapudi, Venkata Ravi Kishore Wang, Benfei Kandasamy, Nandha Kumar So, Ping Lam |
| format |
Article |
| author |
Kanamarlapudi, Venkata Ravi Kishore Wang, Benfei Kandasamy, Nandha Kumar So, Ping Lam |
| author_sort |
Kanamarlapudi, Venkata Ravi Kishore |
| title |
A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range |
| title_short |
A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range |
| title_full |
A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range |
| title_fullStr |
A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range |
| title_full_unstemmed |
A new ZVS full-bridge DC-DC converter for battery charging with reduced losses over full-load range |
| title_sort |
new zvs full-bridge dc-dc converter for battery charging with reduced losses over full-load range |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/141361 |
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1690658292892696576 |