Younis, Hafiz Muhammad Fahim (2024) Advanced AC-AC, AC-DC and DC-DC power electronics converters for smart grid. Masters thesis, Memorial University of Newfoundland.
Full text not available from this repository.
Abstract
Converters and controllers of power electronics are the lifeblood of many emerging technologies in manufacturing, information technology and more. This thesis investigates the design, analysis, and implementation of advanced AC-AC, AC-DC and DC-DC power electronics converters for high voltage gain and voltage sag/swell compensation in power grids. Firstly, direct single-phase AC-AC converter by using an auto transformer approach and impedance network is presented. It has buck-boost operation in a single-stage direct AC-AC conversion. The high voltage gain is enabled through magnetic coupling and turn ratios of coupled transformer. Notably, it employs a coupled transformer, achieving high voltage gain while maintaining an optimal switching duty ratio, with a 1:1 unity turn ratio. Secondly, AC-DC converter with three output terminals for use in the DC applications is explained. This converter converts an input AC voltage into two output DC voltages. The output DC voltages can be obtained higher or lower than the input AC voltage. The proposed converter with four active switches is analyzed in detail, and control strategies are developed. Finally, a switched-inductor A-source DC-DC converter with an impedance network is presented. The operations of topology are based on the autotransformer technique, which are effective for a wide range of applications due to better DC voltage gain. This network achieves higher voltage gain with less switching duty cycle by using a minimal turns ratio rather than other magnetically coupled impedance source networks. The previous converters usually have high total harmonic distortion (THD) due to discontinuous input current and are not able to operate in buck-boost mode simultaneously. Integrated circuits are becoming smaller, but existing power electronics converters are still inefficient, large, and expensive. Thus, proposed converters have simple structures, operations and share a common ground between the input and output, which enhances the reliability of the power conversion systems. Experimental results are obtained to validate the operations and effectiveness of the proposed converters for the power grids.
| Item Type: | Thesis (Masters) |
|---|---|
| URI: | http://research.library.mun.ca/id/eprint/16650 |
| Item ID: | 16650 |
| Additional Information: | Includes bibliographical references -- Restricted until September 9, 2025 |
| Keywords: | power electronics, converters, AC supply, high gain |
| Department(s): | Engineering and Applied Science, Faculty of |
| Date: | September 2024 |
| Date Type: | Submission |
| Library of Congress Subject Heading: | Power electronics; Electric current converters; Electric transformers; Smart power grids |
Actions (login required)
 |
View Item |
