Journal
IEEE JOURNAL OF EMERGING AND SELECTED TOPICS IN POWER ELECTRONICS
Volume 10, Issue 6, Pages 6938-6949Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/JESTPE.2021.3129137
Keywords
Cascaded H-bridge (CHB); control; motor drives; multilevel converter
Categories
Funding
- NaturalSciences and Engineering Research Council of Canada
- OntarioCentres of Excellence
- Rockwell Automation Canada
Ask authors/readers for more resources
This article proposes a reduced switch-count topology for regenerative cascaded H-bridge (CHB) motor drives. It utilizes a four-switch three-phase inverter active front end to reduce the switch count, which resolves the issues of high switch count, switching power losses, and increased cost in traditional drives. The article also addresses challenges such as voltage imbalance and harmonics through phase alternation connection and carrier phase-shifting techniques. The proposed configuration and control techniques are analyzed theoretically, through simulation studies, and experimentally validated on a scaled-down seven-level regenerative CHB drive.
This article employs a reduced switch-count topology in regenerative cascaded H-bridge (CHB) motor drives. Conventional regenerative CHB drive employs six-switch voltage source converters in the front end of each power cell to capture and utilize the regenerated energy. This solution is accompanied by a high number of switches, gate drives, and control circuits, especially when the number of levels increases. This causes high switching power losses, and increase in the cost, size, and weight of the overall system. This article utilizes a four-switch three-phase inverter active front end to reduce the switch count of the CHB power cell. The utilization of the four-switch inverter creates several challenges in terms of voltage imbalance on the capacitors and harmonics on the grid side. First, these challenges in medium-voltage operation are analyzed and addressed. Then, a new phase alternation connection method and two carrier phase-shifting techniques are proposed in this article to address the input current harmonics and comply with the grid connection standards. The performance of the proposed configuration and control techniques is analyzed theoretically and with simulation studies. The feasibility of the proposed configuration is validated experimentally on a scaled-down seven-level regenerative CHB drive.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available