Modeling and Control of Power Electronics Converter Systems for Power Quality Improvements provides grounded theory for the modeling, analysis and control of different converter topologies that improve the power quality of mains. Intended for researchers and practitioners working in the field, topics include modeling equations and the state of research to improve power quality converters. By presenting control methods for different converter topologies and aspects related to multi-level inverters and specific analysis related to the AC interface of drives, the book helps users by putting a particular emphasis on different control algorithms that enhance knowledge and research work.
- Present In-depth coverage of modeling and control methods for different converter topology
- Includes a particular emphasis on different control algorithms to give readers an easier understanding
- Provides a results and discussion chapter and MATLAB simulation to support worked examples and real-life application scenarios
Arvustused
"Among the book's strengths is that it includes modelling and control methods for different ac-dc converter topologies used in the active improvement of power quality. It also facilitates understanding using real parameters for simulations in MATLAB and PSIM programs as well as experimental tests to show the efficiency of grid current harmonics reduction according to valid standards.""I recommend this book as a useful text for students and scholars who work in the area of power quality improvement and are interested in design and modelling"--Marian P. Kazmierkowski, Warsaw University of Technology, IEEE Industrial Electronics Magazine, September 2019
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vii | |
| Biography |
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ix | |
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1 Power Quality: An Introduction |
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1 | (30) |
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1 | (1) |
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1.2 Power Quality Phenomena |
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2 | (2) |
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1.3 Types of Power Quality Disturbances |
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4 | (7) |
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1.4 Causes and Effects of Power Quality Problems |
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11 | (2) |
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1.5 Power Quality Standards |
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13 | (15) |
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28 | (3) |
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29 | (1) |
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29 | (2) |
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2 Control Strategies of Shunt Active Power Filter |
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31 | (54) |
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31 | (5) |
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2.2 Topologies of Active Power Filters |
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36 | (5) |
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2.3 Shunt Active Power Filter |
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41 | (40) |
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81 | (4) |
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81 | (3) |
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84 | (1) |
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3 Conventional Multilevel Inverter: Topologies and Control Strategies |
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85 | (36) |
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85 | (1) |
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3.2 Conventional Multilevel Inverter Topologies |
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86 | (13) |
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3.3 Multilevel Inverter Modulation Techniques |
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99 | (18) |
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117 | (4) |
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118 | (3) |
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4 Control of Multilevel Inverters With Reduced Device Count |
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121 | (30) |
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121 | (4) |
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125 | (5) |
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4.3 Universal Control Scheme |
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130 | (5) |
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4.4 Implementation of Universal Control Scheme (UCS) for a Five-Level Inverter Based on CCS-MLI |
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135 | (13) |
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148 | (3) |
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148 | (3) |
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5 Active Waveshaping Techniques for Power-Quality Improvements in AC Drives |
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151 | (42) |
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151 | (1) |
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5.2 Classification of Active Waveshaping Techniques |
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152 | (3) |
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5.3 Design and Modeling of Active Waveshaping Converters |
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155 | (7) |
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5.4 Matlab-Based Model of Single-Phase Improved Power-Quality Converters for Feeding VC-PMSM Drive |
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162 | (3) |
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5.5 Hardware Implementation of Single-Phase Improved Power-Quality Converters for Feeding PMSM Drive |
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165 | (1) |
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5.6 DSP-Based Software Implementation of Two-Switch ac---dc Converter |
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166 | (4) |
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5.7 Testing of Two-Switch ac---dc Converter |
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170 | (1) |
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5.8 Results and Discussion |
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171 | (18) |
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189 | (4) |
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190 | (1) |
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Gains of PI Voltage Controller |
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191 | (2) |
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6 Isolated Active Waveshaping Techniques for Power Quality Improvements in Variable Frequency AC Drive |
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193 | (68) |
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193 | (1) |
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6.2 Classification of Isolated Active Waveshaping Techniques in AC-DC Converter Feeding VC-Based PMSM Drive |
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194 | (3) |
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6.3 Design of Isolated Active Waveshaping Converters in DCM of Operation |
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197 | (22) |
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6.4 PSIM-Based Simulation of High Frequency Transformer Isolated AC-DC Converters for Feeding PMSM Drive |
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219 | (1) |
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6.5 DSP-Based Hardware Implementation of Isolated AC-DC Converters for Feeding PMSM Drive |
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220 | (5) |
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6.6 DSP-Based Software Implementation of High Frequency Transformer Isolated AC-DC Converters |
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225 | (1) |
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6.7 Testing of High Frequency Transformer Isolated AC-DC Converters |
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226 | (1) |
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6.8 Results and Discussion |
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227 | (31) |
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258 | (3) |
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259 | (2) |
| Appendix I Design Equations of High Frequency Isolated AC-DC Converters |
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261 | (2) |
| Appendix II Design Parameters of High Frequency Isolated AC-DC Converters |
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263 | (2) |
| Glossary |
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265 | (2) |
| Index |
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267 | |
Sanjeet Kumar Dwivedi, PhD, is an adjunct professor at Curtin University, Perth, Australia and is working as a scrum master and senior R&D engineer in control engineering, application, and motor control for Danfoss Power Electronics, Graasten, Denmark since 2008, where he is conducting research on new control techniques in power electronics and motor drives. He has authored more than 40 technical papers and holds 3 international patents. Dr. Shailendra Jain is currently working as a Professor in the Department of Electrical Engineering, Maulana Azad National Institute of Technology, India. His research interests include Power Electronics & Electrical Drives, Power Quality Improvement, Active Power Filter/ STATCOM/ HPF Converters, Multilevel Inverters, Reduce Device Count MLIs, Electrical Vehicular Systems, Distributed Generation, Applications of Artificial Intelligence in Electrical Systems, High Speed Transit System. He is serving as an editorial member and reviewer of several international reputed journals. Prof Krishna Kumar Gupta obtained B.Tech (Electrical Engineering) and M.Tech. (Power Systems) degrees from Maulana Azad National Institute of Technology (MANIT) Bhopal in 2005 and 2007 respectively. He pursued research on emerging topologies of multilevel inverters” and awarded Ph.D by MANIT Bhopal in the year 2013.
He has authored many articles published in international journals and conferences. He is an active reviewer of many journals including IEEE Transactions of Industrial Electronics, IEEE Transactions of Power Electronics and IET Power Electronics. His areas of interest include power electronics for renewable energy, energy storage devices for power system applications, real time controllers for power electronic systems and modulation strategies for power converters. Dr. Gupta is a recipient of the Young Scientist Award, conferred by Council of Science and Technology, Government of M.P. He has authored a book on Inverters, published by Elsevier Inc. He has also contributed chapters in the book on Electrical Drives being published by IEEE-Wiley Press. He has been invited as an Expert Speaker to many NITs. In addition, he is working on funded project on improving the LED driving technology for enhanced warranty of LED products. Dr. Pradyumn Chaturvedi's current research area is Multilevel Converters, Its Applications in High Power Electrical Drives and Renewable Energy Sources, Power Quality Improvement, Photovoltaic Power Conditioning.
