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Inicio Revista Iberoamericana de Automática e Informática Industrial RIAI Extensión del Rango de Operación con Conmutación Suave de un Convertidor CC-C...
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Vol. 13. Núm. 1.
Páginas 127-134 (Enero - Marzo 2016)
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Vol. 13. Núm. 1.
Páginas 127-134 (Enero - Marzo 2016)
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DOI: 10.1016/j.riai.2015.04.007
Open Access
Extensión del Rango de Operación con Conmutación Suave de un Convertidor CC-CC Bidireccional de Tres Puertos
Extending the Soft-Switching Operating Range of a Bidirectional Three-Port DC-DC Converter
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Laureano Piris-Botalla
Autor para correspondencia
lpiris@ing.unrc.edu.ar

Autor para correspondencia. URL: www.ing.unrc.edu.ar/grupos/gea/.
, Germán G. Oggier, Andrés M. Airabella, Guillermo O. García
Grupo de Electrónica Aplicada (GEA), Facultad de Ingeniería, Universidad Nacional de Río Cuarto, Ruta Nacional # 36 Km. 601, X5804BYA, Río Cuarto, Argentina. CONICET
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En este trabajo se analiza la operación con conmutación suave de un convertidor CC-CC bidireccional de tres puertos (CTP) para sistemas eléctricos híbridos. Se estudia el principio de control de flujo de energía y la operación con conmutación suave para establecer sus regiones de operación. A partir de este análisis se definen criterios de diseño para operar el CTP con conmutación suave en un amplio rango de funcionamiento. Los parámetros considerados son las relaciones de transformación y las inductancias de dispersión del transformador, las cuales determinan la máxima potencia que puede ser transferida. Se presentan resultados experimentales para validar el análisis.

Palabras clave:
Electrónica de Potencia
Convertidores y Accionamientos Eléctricos
Sistemas Eléctricos y Electrónicos de Potencia
Vehículos Híbridos
Abstract

The behavior of a three-port bidirectional DC-DC converter (TPC) under soft-switching mode applied to hybrid electric systems is analyzed in this paper. The principle of power flow control and the operation under soft-switching mode have been studied to establish the converter operation regions. The parameters considered are the transformer turns ratio and the leakage inductances, which establish the maximum power that can be transferred. As a result, design considerations to operate the TPC under soft-switching mode within a wide operation range, by using the conventional modulation strategy, are presented. Experimental results are included to validate the proposal.

Keywords:
Power Electronics
Power Converters and Drives
Smart Grid
Electronic and Electrical Power Systems
Hybrid Vehicles
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