ISBN-13: 9781119475866 / Angielski / Twarda / 2019 / 496 str.
ISBN-13: 9781119475866 / Angielski / Twarda / 2019 / 496 str.
I A review on Classical Multilevel Converters
1 Classical Multilevel Converters
Gabriel H. P. Ooi, Ziyou Lim and Hossein Dehghani
1.1 Introduction
1.2 Classical Two–Level Converter
1.3 The Need of Multilevel Converters
1.4 Classical Three–Level Converters
1.5 Classical Multilevel Converters
1.6 Summary
1.7 References
2 Multilevel Modulation Methods
Ziyou Lim, Harikrishna R. Pinkymol and Hossein Dehghani
2.1 Introduction
2.2 Carrier–Based Modulation
2.3 Space Vector Modulation
2.4 Summary
2.5 References
3 Mathematical Modeling of Classical Three–Level Converters
Gabriel H. P. Ooi
3.1 Introduction
3.2 Three–Level Diode Clamped Converter
3.3 Three–Level Flying Capacitor Converter
3.4 Summary
3.5 References
4 Voltage Balancing Methods for Classical Multilevel Converters
Gabriel H. P. Ooi and Harikrishna R. Pinkymol
4.1 Introduction
4.2 Active Balancing by Adding DC Offset Voltage to Modulating Signals
4.3 Measurement Results for DC Offset Modulation Control
4.4 Natural Balancing by using Star Connected RC Filter
4.5 Measurement Results for Natural Balancing Method
4.6 Space Vector Modulation with Self–Balancing Technique
4.7 Comparative Evaluation
4.8 Summary
4.9 References
II Advanced Multilevel Rectifiers and their Control Strategies
5 Unidirectional Three–Phase Three–Level Unity–Power Factor Rectifier
Gabriel H. P. Ooi and Hossein Dehghani
5.1 Introduction
5.2 Circuit Configuration
5.3 Operation Principle
5.4 Modulation Scheme
5.5 Control Strategy
5.6 Mathematical Modeling
5.7 Design Considerations
5.8 Validation
5.9 Experimental Verification
5.10 Applications
5.11 Summary
5.12 References
6 Bidirectional and Unidirectional Five–Level/Multiple–Pole Multilevel Rectifiers
Gabriel H. P. Ooi
6.1 Introduction
6.2 Circuit Configuration
6.2.1 Bidirectional Front–End Five–Level/Multiple–Pole Multilevel Diode–Clamped Rectifier
6.2.2 Unidirectional Five–Level/Multiple–Pole Multilevel Switch–Clamped Rectifier
6.3 Operation Principle
6.4 Modulation Scheme
6.5 Control Strategy
6.6 Mathematical Modeling
6.7 Design Considerations
6.8 Comparative Evaluation
6.9 Experimental Verification
6.10 Applications
6.11 Summary
6.12 References
7 Five–Level/Multiple–Pole Multilevel VIENNA Rectifier
Gabriel H. P. Ooi, Liu Fangrui and Ali I. Maswood
7.1 Introduction
7.2 Circuit Configuration
7.3 Operation Principle
7.4 Modulation Scheme
7.5 Control Strategy
7.6 Mathematical Modeling
7.7 Design Considerations
7.8 Validation
7.9 Applications
7.10 Summary
7.11 References
8 Five–Level/Multiple–Pole Multilevel Rectifier with Reduced Components
Gabriel H. P. Ooi
8.1 Introduction
8.2 Circuit Configuration
8.3 Operation Principle
8.4 Modulation Scheme
8.5 Control Strategy
8.6 Mathematical Modeling
8.7 Design Considerations
8.8 Validation
8.9 Experimental Verification
8.10 Applications
8.11 Summary
8.12 References
9 Four Quadrant Reduced Modular Cell Rectifier
Ziyou Lim
9.1 Introduction
9.2 Circuit Configuration
9.3 Operation Principle
9.4 Modulation Scheme
9.5 Control Strategy
9.6 Mathematical Modeling
9.7 Design Considerations
9.8 Experimental Verification
9.9 Applications
9.10 Summary
9.11 References
III Advanced Multilevel Inverters and their Control Strategies
10 Transformerless Five–Level/Multiple–Pole Multilevel Inverters with Single dc Bus Configuration
Gabriel H. P. Ooi, Harikrishna R. Pinkymol and Hossein Dehghani
10.1 Introduction
10.2 Five–Level Multiple–Pole Concept
10.3 Circuit Configuration and Operation Principles
10.4 Operation Principle
10.5 Modulation Scheme
10.6 Control Strategy
10.7 Mathematical Modeling
10.8 Design Considerations
10.9 Losses in Power Devices
10.10 Validation
10.11 Experimental Verification
10.12 Applications
10.13 Summary
10.14 References
11 Transformerless Seven–Level/Multiple–Pole Multilevel Inverters with Single Input Multiple Output (SIMO) Balancing Circuit
Gabriel H. P. Ooi
11.1 Introduction
11.2 Circuit Configuration and Operation Principles
11.3 Single Input Multiple Output Voltage Balancing Circuit
11.4 Operation Principle
11.5 Modulation Scheme
11.6 Control Strategy
11.7 Mathematical Modeling
11.8 Design Considerations
11.9 Experimental Verification
11.10 Applications
11.11 Summary
11.12 References
12 Three–Phase Seven–Level Three–Cell Lightweight Flying Capacitor Inverter
Ziyou Lim
12.1 Introduction
12.2 Circuit Configuration
12.3 Operation Principles
12.4 Modulation Scheme
12.5 Control Strategy
12.6 Mathematical Modeling
12.7 Design Considerations
12.8 Harmonic Characteristics
12.9 Experimental Verification
12.10 Applications
12.11 Summary
12.12 References
13 Three–Phase Seven–Level Four–Cell Reduced Flying Capacitor Inverter
Ziyou Lim
13.1 Introduction
13.2 Circuit Configuration
13.3 Operation Principles
13.4 Modulation Scheme
13.5 Control Strategy
13.6 Mathematical Modeling
13.7 Design Considerations
13.8 Experimental Verification
13.9 Applications
13.10 Summary
13.11 References
14 Active Neutral Point Clamped Inverters
Ziyou Lim
14.1 Introduction
14.2 Circuit Configuration
14.3 Operation Principle
14.4 Modulation Scheme
14.5 Mathematical Modeling
14.6 Design Considerations
14.7 Multiple Voltage Quantities Enhancement Control
14.8 Common Mode Reduction Control
14.9 Applications
14.10 Summary
14.11 References
15 Multilevel–Level Z–Source Inverters
Muhammad Musthafa Roomi
15.1 Introduction
15.2 Two–Level Z–Source Inverter
15.3 Three–Level Single Z–Source Network with Neutral–Point Connected to Split Capacitor Bank Inverter
15.4 Three–Level Single Z–Source Network with Neutral–Point Connected to Split Input dc–sources Inverter
15.5 Three–level Dual Z–Source Neutral–Point–Clamped Inverter
15.6 Modulation Methods for Three–Level Z–Source Neutral–Point–Clamped Inverter
15.7 Modulation Method for Three–level Dual Z–Source Neutral–Point–Clamped Inverter
15.8 Reference Disposition Level Shifted Pulse Width Modulation for Non–Ideal Dual Z–Source Network Neutral–Point–Clamped Inverter
15.9 Applications
15.10 Summary
15.11 References
IV Grid–Integration Applications of Advanced Multilevel Converters
16 Multilevel Converter–Base Photovoltaic Power Conversion
Hossein Dehghani, Georgios Konstantiou and Josep Pou
16.1 Introduction
16.2 Photovoltaic Power Conversion Principles
16.3 Three–Level Neutral–Point–Clamped Inverter–Based Photovoltaic Power Plant
16.4 Seven–Level Cascaded H–Bridge Inverter–Based Photovoltaic Power Plant
16.5 Summary
16.6 References
17 Multilevel Converter–Based Wind Power Conversion
Khan Md Shafquat Ullah
17.1 Introduction
17.2 Wind Power Conversion Principles
17.3 Three–Level Neutral–Point–Clamped Inverter–Based Wind Turbine System
17.4 Multilevel Unity Power Factor Rectifier–Based Wind Turbine System
17.5 Summary
17.6 References
18 Multilevel–Level Z–Source Inverter–Based Fuel Cell Power Generation
Muhammad Musthafa Roomi
18.1 Introduction
18.2 Fuel Cell Power Conversion Principles
18.3 Modeling of Proton Exchange Membrane Fuel Cell
18.4 Circuit Configuration
18.5 Control Strategy
18.6 Validation
18.7 Summary
18.8 References
19 Multilevel Converter–Based Flexible Alternating Current Transmission System
Muhammad Musthafa Roomi, Khan Md Shafquat Ullah and Harikrishna R. Pinkymol
19.1 Introduction
19.2 A Space Vector Modulated Five–Level Multiple–pole Multilevel Diode Clamped Based–static Synchronous Compensator (STATCOM)
19.3 Multilevel Converter–Based Dynamic Voltage Restorer (DVR)
19.4 Summary
19.5 References
Ali Iftekhar Maswood, PhD, is an Associate Professor at Nanyang Technological University, Singapore. He received his B & M. Eng with first class from Moscow Power Engineering Institute and Ph. D degree from Concordia University, Canada. Having taught in Canada for sometime, he joined NTU, Singapore. Dr. Maswood is an Associate Editor, IET PEL, author of more than top 100 journal and conference papers and number of patents. His research interest is in unity pf converters, harmonics, multilevel converters, modulation techniques. He is the recipient of several national and international grants that include Qatar Foundation & Rolls Royce.
Hossein Dehghani Tafti, PhD, received the B.Sc. and M.Sc. degrees in electrical engineering and power system engineering from Amirkabir University of Technology, Tehran, Iran, in 2009 and 2011, respectively, and the Ph.D. degree in electrical engineering from Nanyang Technological University, Singapore, in 2017. From February 2016 to August 2016, he was on a research exchange program with the University of New South Wales, Sydney, NSW, Australia, where he was working in the control of multilevel grid–connected converters. From August 2017 to October 2017, he was a Researcher with Aalborg University, Aalborg, Denmark, where he was working on the constant power generation of photovoltaic power plants. Since January 2018 he is working as a research fellow in Nanyang Technological University. His research interest includes photovoltaic power plants, multilevel converters, renewable energy, and fault–ride–through capabilities of power converters.
A comprehensive survey of advanced multilevel converter design, control, operation and grid–connected applications
Advanced Multilevel Converters and Applications in Grid Integration presents a comprehensive review of the core principles of advanced multilevel converters, which require fewer components and provide higher power conversion efficiency and output power quality. The authors noted experts in the field explain in detail the operation principles and control strategies and present the mathematical expressions and design procedures of their components.
The text examines the advantages and disadvantages compared to the classical multilevel and two level power converters. The authors also include examples of the industrial applications of the advanced multilevel converters and offer thoughtful explanations on their control strategies. Advanced Multilevel Converters and Applications in Grid Integration provides a clear understanding of the gap difference between research conducted and the current industrial needs. This important guide:
Written for university students in electrical engineering, researchers in areas of multilevel converters, high–power converters and engineers and operators in power industry, Advanced Multilevel Converters and Applications in Grid Integration offers a comprehensive review of the core principles of advanced multilevel converters, with contributions from noted experts in the field.
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