Multilevel Inverters
Introduction and Emergent Topologies
- 1st Edition - February 14, 2021
- Imprint: Academic Press
- Editor: Ersan Kabalci
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 2 1 6 6 8 - 2
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 2 3 2 3 9 - 2
Multilevel Inverters: Topologies, Control Methods, and Applications investigates modern device topologies, control methods, and application areas for the rapidly developin… Read more
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Request a sales quoteMultilevel Inverters: Topologies, Control Methods, and Applications investigates modern device topologies, control methods, and application areas for the rapidly developing conversion technology. The device topologies section begins with conventional two-level inverter topologies to provide a background on the DC-AC power conversion process and required circuit configurations. Thereafter, multilevel topologies originating from neutral point clamped topologies are presented in detail. The improved and inherited regular multilevel topologies such as flying capacitor and conventional H-bridge topology are presented to illustrate the multilevel concept. Emerging topologies are introduced regarding application areas such as renewable energy sources, electric vehicles, and power systems. The book goes on to discuss fundamental operational principles of inverters using the conventional pulse width modulated control method. Current and voltage based closed loop control methods such as repetitive control, space vector modulation, proportional resonant control and other recent methods are developed. Core modern applications including wind energy, photovoltaics, microgrids, hybrid microgrids, electric vehicles, active filters, and static VAR compensators are investigated in depth. Multilevel Inverters for Emergent Topologies and Advanced Power Electronics Applications is a valuable resource for electrical engineering specialists, smart grid specialists, researchers on electrical, power systems, and electronics engineering, energy and computer engineers.
- Reviews mathematical modeling and step-by-step simulation examples, straddling both basic and advanced topologies
- Assesses how to systematically deploy and control multilevel power inverters in application scenarios
- Reviews key applications across wind energy, photovoltaics, microgrids, hybrid microgrids, electric vehicles, active filters, static VAR compensators
Electrical Engineering Specialists; Smart Grid Specialists; Researchers on Electrical, Power Systems, and Electronics Engineering; Energy Engineers; Computer Engineers. Graduate and early career researchers at MSc and PhD level in energy and power engineering
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- Chapter 1: Introduction to multilevel voltage source inverters
- Abstract
- 1.1: Introduction
- 1.2: Conventional multilevel inverter topologies
- 1.3: Soft switching and resonant multilevel inverters
- 1.4: Fundamentals of control schemes
- Chapter 2: Neutral-point-clamped and T-type multilevel inverters
- Abstract
- Acknowledgment
- 2.1: Neutral-point-clamped multilevel inverters
- 2.2: T-type inverter
- 2.3: Conclusion
- Chapter 3: Conventional H-bridge and recent multilevel inverter topologies
- Abstract
- 3.1: Introduction
- 3.2: H-bridge inverter topology
- 3.3: Common mode voltage and leakage current
- 3.4: Modulation strategy
- 3.5: H5 inverter topology
- 3.6: H6 inverter topology
- 3.7: HERIC inverter
- 3.8: Recent H-bridge based multilevel topologies
- 3.9: Remarks and conclusion
- Chapter 4: Packed U-Cell topology: Structure, control, and challenges
- Abstract
- Acknowledgment
- 4.1: Introduction
- 4.2: Packed U-cell topology
- 4.3: Control techniques
- 4.4: Applications
- 4.5: Commercialization challenges
- 4.6: Conclusions
- Chapter 5: Modular multilevel converters
- Abstract
- 5.1: Introduction
- 5.2: Fundamentals of a modular multilevel converter
- 5.3: Classical control methods
- 5.4: Pulse width modulation schemes
- 5.5: Submodule capacitor voltage control
- 5.6: Current control
- 5.7: Applications
- 5.8: Conclusions
- Chapter 6: Asymmetrical multilevel inverter topologies
- Abstract
- 6.1: Introduction
- 6.2: Asymmetric multilevel inverter with polarity generation part
- 6.3: Asymmetric MLI topologies without polarity generation module
- 6.4: Remarks and conclusion
- Chapter 7: Resonant and Z-source multilevel inverters
- Abstract
- 7.1: General operating principle of resonant circuits
- 7.2: General operating principle of impedance-source networks
- 7.3: Overview of multilevel inverters
- 7.4: Resonant multilevel inverters: Main circuits
- 7.5: Impedance source-derived multilevel inverters: Control, benefits, and applications
- 7.6: Conclusions
- Index
- Edition: 1
- Published: February 14, 2021
- Imprint: Academic Press
- No. of pages: 274
- Language: English
- Paperback ISBN: 9780128216682
- eBook ISBN: 9780128232392
EK
Ersan Kabalci
Ersan Kabalci is Department Head of Electrical and Electronics Engineering at Nevsehir University, Turkey. He received his MSc and PhD in Electrical and Electronics Engineering from Gazi University, Turkey, where his research focused on implementing an enhanced modulation scheme for multilevel inverters. Dr. Kabalci also serves as an Associate Editor for several international indexed journals and as a reviewer for more than 25 international journals on power electronics and renewable energy sources. His current research interests include power electronic applications and drives for renewable energy sources, microgrids, distributed generation, power line communication, and smart grid applications. He has been a member of the IEEE since 2009.
Affiliations and expertise
Professor, Electrical and Electronics Engineering, Faculty of Engineering and Architecture, Nevsehir Hacı Bektas Veli University, Nevsehir, TurkeyRead Multilevel Inverters on ScienceDirect