High Step-Down Isolated PWM DC-DC Converter Based on Combining a Forward Converter With the Series-Capacitor Structure

Incorporating switched-capacitor structures into isolated dc-dc converters is a promising approach to alleviate the limitations of topologies fully based on the use of high step-down transformers. In this paper, the combination of a forward converter with a series-capacitor structure is proposed for...

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Bibliographic Details
Published in:IEEE access 2023, Vol.11, p.131045-131063
Main Authors: Rodriguez, Juan, Garcia-Mere, Juan R., Lamar, Diego G., Hernando, Marta M., Sebastian, Javier
Format: Article
Language:English
Subjects:
Capacitors
Conduction losses
Conversion ratio
Current sharing
DC-DC power converters
Efficiency
Electric potential
High conversion ratio
Hybrid power systems
hybrid switched-capacitor converters
Inductors
isolated converters
Pulse width modulation
Rectifiers
Ripples
Switched capacitor networks
Switches
Topology
Transformers
Voltage
Voltage converters (DC to DC)
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Summary:Incorporating switched-capacitor structures into isolated dc-dc converters is a promising approach to alleviate the limitations of topologies fully based on the use of high step-down transformers. In this paper, the combination of a forward converter with a series-capacitor structure is proposed for applications that require a very high step-down conversion ratio, low output voltage ripple, high output current and isolation. The result of the combination only adds one series-capacitor, one inductor, one switch and one diode (or synchronous rectifier switch) to the component count of a conventional forward converter, thus avoiding the use of a complete second phase. The topology provides high step-down conversion ratio and low output voltage ripple, a characteristic that can be used to decrease the total energy stored by inductors (i.e., higher power density) and/or to reduce the switching frequency (i.e., higher efficiency). Moreover, the converter provides inherent current sharing between the two inductors, natural balance of the voltage across the series-capacitor and lower conduction losses. The converter operation is validated with a 100W and 48V-to-5/3.3/2.5/1.8V prototype that achieves a peak efficiency of 95.8% and a full load efficiency of 91.1%.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2023.3334794