Cascaded High-Voltage-Gain Bidirectional Switched-Capacitor DC–DC Converters for Distributed Energy Resources Applications

Cascaded High-Voltage-Gain Bidirectional Switched-Capacitor DC–DC Converters for Distributed Energy Resources Applications

A family of bidirectional switched-capacitor (SC) converters with high-gain ratio of any positive integer is proposed in this paper for distributed energy resources applications. As compared with other existing SC converters achieving a same conversion gain, the main advantages of the proposed conve...

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Bibliographic Details
Published in:IEEE transactions on power electronics Vol. 32; no. 2; pp. 1220 - 1231
Main Authors: Xiong, Song, Tan, Siew-Chong
Format: Journal Article
Language:English
Published: New York IEEE 01-02-2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Auxiliary power units
Batteries
Bidirectional
Capacitors
Conversion
Conversion ratio
Converters
Distributed generation
Driver circuits
Electric potential
Energy resources
Energy sources
Full load
High temperature
High voltages
high-voltage gain
Magnetomechanical effects
MOSFETs
Power supply circuits
renewable energy
Stress
switched-capacitor
Switches
Voltage control
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Summary:A family of bidirectional switched-capacitor (SC) converters with high-gain ratio of any positive integer is proposed in this paper for distributed energy resources applications. As compared with other existing SC converters achieving a same conversion gain, the main advantages of the proposed converters are that they require a relatively lower number of switches and capacitors, have a relatively lower switch's and capacitor's stress, and that their associated driver circuits are simpler to realize. Importantly, with the achievable conversion ratio being flexible and that the input and output of the proposed converters are of common ground, the proposed converters are widely suitable for many applications. Moreover, as the proposed converters do not possess magnetic component or any component that can severely degrade the converters' performance at high temperature, they are especially useful for high-temperature applications. Besides, the proposed converters are capable of delivering bidirectional power, which is a key requirement for emerging applications with battery storages. Different aspects of the proposed converters, including a simple auxiliary power supply circuit for the MOSFETs' drivers, will be discussed in this paper. A nine-time SC converter prototype that operates with 20-V input voltage, 100-W output, and at 75 kHz, is constructed and tested. Experiment results show that the maximum efficiency achievable with this prototype is over 98% (without driver's loss) and the efficiency over the entire load range between 25 and 100 W is over 95.5% including the driver's loss. The output voltage ripple of the SC converter is less than 1%. When the SC converter is open-loop controlled, the load voltage regulation is relatively well kept at less than 5% between full load and no load conditions.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2016.2552380