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Permanent link (DOI): https://doi.org/10.7939/R3W37M15X

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Modeling, Analysis and Advanced Control of Voltage- and Current-Source Converters in Renewable Energy-Based Active Distribution Systems Open Access

Descriptions

Other title
Subject/Keyword
Current-Source-Converters
Voltage-Source-Converters
Weak-Grid
Microgrid
Phase-Locked-Loop
AC/DC
Stability
Type of item
Thesis
Degree grantor
University of Alberta
Author or creator
Radwan, Amr A A
Supervisor and department
Mohamed, Yasser A.-R. I. (Electrical and Computer Engineering)
Examining committee member and department
Liang, Hao (Electrical and Computer Engineering, University of Alberta)
Dinavahi, Venkata (Electrical and Computer Engineering, University of Alberta)
Willamson, Sheldon S. (Department of Electrical, Computer, and Software Engineering, University of Ontario-Institute of Technology)
Mohamed, Yasser A.-R. I. (Electrical and Computer Engineering, University of Alberta)
Khajehoddin, S. Ali (Electrical and Computer Engineering, University of Alberta)
Department
Department of Electrical and Computer Engineering
Specialization
Energy Systems
Date accepted
2015-10-16T09:32:43Z
Graduation date
2016-06
Degree
Doctor of Philosophy
Degree level
Doctoral
Abstract
This thesis addresses the integration of renewable energy resources into the grid-connected and isolated distribution systems using voltage- and current-source converters. Motivated by its promising potential and attractive features, a one-stage current-source converter (CSC) is selected as an effective interfacing device for the photovoltaic (PV) generators to the utility-grid. The operation of the grid-connected CSC-based PV system is investigated under different operating conditions, parameters variation, and control topologies. From the dc-side, it is found that the variation in the weather conditions, e.g., solar irradiance levels, might affect the dynamic performance of the vector-controlled grid-connected CSCs. Small-signal dc-side impedance models for the CSC and the PV generators are developed to investigate the system stability. Active compensation techniques are proposed so that the system performance is well maintained under different operating points. From the ac-side, a susceptible potential to instabilities is yielded under the very weak grid conditions. This potential significantly increases in the vector-controlled converters. The implementation of the phase-locked loop (PLL) is found to have a detrimental impact on the system stability as the grid impedance increases. Two solutions for the very weak grid integration have been proposed. Firstly, the power synchronization control (PSC) scheme is developed for CSCs in PV applications so that the PLL is no longer needed, and hence a seamless integration to the very weak grid is achieved. Secondly, supplementary compensation loops are proposed and added to the conventional PLL-based vector-controlled CSC so that the negative impacts of the PLL are completely alleviated. In both cases, small-signal state-space models are developed to investigate the system stability and provide a detailed design approach for the proposed controllers. A larger system level integration is considered in this thesis by interfacing multiple distributed generation (DG) units to the conventional distribution system. A generalized hybrid alternating-current (ac)/direct-current (dc) system that constitutes ac and dc subgrids is created to efficiently accommodate the dc-type renewable sources (such as PVs, batteries, fuel cells, etc.) to the ac-type conventional distribution system. Both subgrids are interconnected using voltage-source converters (VSCs) to facilitate a bidirectional power exchange via multiple inversion-rectification processes. To achieve an accurate and efficient operation, a supervisory power management algorithm is proposed. The algorithm operates successfully regardless of the control mode of the individual DG units. However, the integration of severe dynamic loads, such as direct online inductions motors (IMs) into the ac-side of the hybrid system reflects very lightly damped modes, which in turns induce instabilities, particularly in the isolated mode of operation. Therefore, active compensation techniques have been proposed to increase the system damping. Throughout this thesis, time domain simulations under Matlab/Simulink® environment for the systems under study are presented to validate the analytical results and show the effectiveness of the proposed techniques.
Language
English
DOI
doi:10.7939/R3W37M15X
Rights
This thesis is made available by the University of Alberta Libraries with permission of the copyright owner solely for the purpose of private, scholarly or scientific research. This thesis, or any portion thereof, may not otherwise be copied or reproduced without the written consent of the copyright owner, except to the extent permitted by Canadian copyright law.
Citation for previous publication
Amr A. A. Radwan and Y. A.-R. I. Mohamed, “Analysis and active suppression of ac- and dc-side instabilities in grid-connected current-source converter-based photovoltaic system,” IEEE Transactions on Sustainable Energy, vol. 4, no. 3, pp. 630-642, July 2013.Amr A. A. Radwan and Y. A.-R. I. Mohamed, “Improved vector control strategy for current-source converters connected to very weak grids,” IEEE Transactions on Power Systems, in press [available online].Amr A. A. Radwan and Y. A.-R. I. Mohamed, “Stabilization of medium-frequency modes in isolated microgrids supplying direct online induction motor loads,” IEEE Transactions on Smart Grid, vol. 5, no. 1, pp. 358-370, January 2014.Amr A. A. Radwan and Y. A.-R. I. Mohamed, “Networked power management and control of AC-DC hybrid microgrid,” IEEE Systems Journal, in press [available online].

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