F.Z. PENG, H. LI, G.-J. SU, J.S. LAWLER, "A New ZVS Bidirectional DC-DC Converter for Fuel Cell and Battery Application", IEEE Transactions on Power Electronics, Vol. 19, No. 1, January 2004, pp. 54-65.
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**Article : **[ART603]

**Titre : **F.Z. PENG, H. LI, G.-J. SU, J.S. LAWLER, *A New ZVS Bidirectional DC-DC Converter for Fuel Cell and Battery Application*, IEEE Transactions on Power Electronics, Vol. 19, No. 1, January 2004, pp. 54-65.

**Cité dans :**[THESE133] B. BIDOGGIA, *Etude et réalisation de nouveaux convertisseurs connectant plusieurs sources d'énergies renouvelables au réseau*, These de doctorat, septembre 2005 - aout 2008.

**Auteur : **Fang Z. Peng

**Auteur : **Hui Li

**Auteur : **Gui-Jia Su

**Auteur : **Jack S. Lawler

**Source : **IEEE TRANSACTIONS ON POWER ELECTRONICS

**Volume : **19

**Numéro : **1

**Date : **JANUARY 2004

**Pages : **54 - 65

**Lien : **private/01262053.pdf - 12 pages, 1029 Ko.

**Vers : **Abstract

**Vers : **Bibliographie

This paper presents a new zero-voltage-switching

(ZVS) bidirectional dc-dc converter. Compared to the traditional

full and half bridge bidirectional dc-dc converters for the similar

applications, the new topology has the advantages of simple circuit

topology with no total device rating (TDR) penalty, soft-switching

implementation without additional devices, high efficiency

and simple control. These advantages make the new converter

promising for medium and high power applications especially for

auxiliary power supply in fuel cell vehicles and power generation

where the high power density, low cost, lightweight and high

reliability power converters are required. The operating principle,

theoretical analysis, and design guidelines are provided in this

paper. The simulation and the experimental verifications are also

presented.

**Index_Terms : **Auxiliary power supply, dc-dc converter, fuel cell vehicle, power generation, TDR, ZVS.

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** [1] : ** [ART272] S. HAMADA, M. NAKAOKA, *A novel zero-voltage and zero-current switching PWM DC-DC converter with reduced conduction losses*, IEEE Transactions on Power Electronics, Volume 17, Issue 3, May 2002, pp. 413-419.

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