Single-Phase ZAC-Source AC-AC Converter With High Buck and Boost Voltage Conversion Capability

Single-Phase ZAC-Source AC-AC Converter With High Buck and Boost Voltage Conversion Capability

In this article, a novel Z AC -source single-phase ac-ac converter with high buck and boost voltage conversion capability is introduced. The proposed topology utilizes the Z AC -source network to regulate the frequency and magnitude of the output voltage. The proposed converter operates in buck mode...

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Bibliographic Details
Published in:IEEE transactions on industrial electronics (1982) Vol. 67; no. 11; pp. 9251 - 9259
Main Authors: Rahman, Khaliqur, Meraj, Mohammad, Bhaskar, Mahajan Sagar, Iqbal, Atif
Format: Journal Article
Language:English
Published: New York IEEE 01-11-2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
AC-AC converters
AC–AC converter
amplitude control
boost operation
buck operation
Capacitors
Closed loops
Commutation
Conversion
Converters
Electric potential
Field programmable gate arrays
Frequency control
Inductors
Switches
Topology
Voltage
Voltage control
Waveforms
ZAC-source
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Description
Summary:In this article, a novel Z AC -source single-phase ac-ac converter with high buck and boost voltage conversion capability is introduced. The proposed topology utilizes the Z AC -source network to regulate the frequency and magnitude of the output voltage. The proposed converter operates in buck mode when the duty cycle lies between 0 and 0.33, and boost mode when the duty cycle lies between 0.33 and 1. The switching control strategy is discussed and the proposed converter provides a feature to control the magnitude and frequency of the output voltage independently. Employment of capacitors in the outer closed loop results in a highly consistent operation characterized by inherent soft commutation capability, removal of the source shoot-through risk, and enhanced input current waveform quality. Due to these advantages, it can be applied to the adjustable speed drives and traction systems. The control code is executed in dSPACE 1006 embedded with field-programmable gate array (FPGA) dS5203 board and the performance of the proposed converter is tested experimentally. The obtained experimental results are provided which validates the theoretical analysis and performance of the proposed converter.
ISSN:0278-0046
1557-9948
DOI:10.1109/TIE.2019.2956386