Home Page Icon
Home Page
Table of Contents for
Index
Close
Index
by Kamal Al-Haddad, Mariusz Malinowski, Haitham Abu-Rub
Power Electronics for Renewable Energy Systems, Transportation and Industrial Applications
Cover
Title Page
Copyright
Dedication
Foreword
Preface
Acknowledgments
List of Contributors
Chapter 1: Energy, Global Warming and Impact of Power Electronics in the Present Century
1.1 Introduction
1.2 Energy
1.3 Environmental Pollution: Global Warming Problem
1.4 Impact of Power Electronics on Energy Systems
1.5 Smart Grid
1.6 Electric/Hybrid Electric Vehicles
1.7 Conclusion and Future Prognosis
References
Chapter 2: Challenges of the Current Energy Scenario: The Power Electronics Contribution
2.1 Introduction
2.2 Energy Transmission and Distribution Systems
2.3 Renewable Energy Systems
2.4 Transportation Systems
2.5 Energy Storage Systems
2.6 Conclusions
References
Chapter 3: An Overview on Distributed Generation and Smart Grid Concepts and Technologies
3.1 Introduction
3.2 Requirements of Distributed Generation Systems and Smart Grids
3.3 Photovoltaic Generators
3.4 Wind and Mini-hydro Generators
3.5 Energy Storage Systems
3.6 Electric Vehicles
3.7 Microgrids
3.8 Smart Grid Issues
3.9 Active Management of Distribution Networks
3.10 Communication Systems in Smart Grids
3.11 Advanced Metering Infrastructure and Real-Time Pricing
3.12 Standards for Smart Grids
References
Chapter 4: Recent Advances in Power Semiconductor Technology
4.1 Introduction
4.2 Silicon Power Transistors
4.3 Overview of SiC Transistor Designs
4.4 Gate and Base Drivers for SiC Devices
4.5 Parallel Connection of Transistors
4.6 Overview of Applications
4.7 Gallium Nitride Transistors
4.8 Summary
References
Chapter 5: AC-Link Universal Power Converters: A New Class of Power Converters for Renewable Energy and Transportation
5.1 Introduction
5.2 Hard Switching ac-Link Universal Power Converter
5.3 Soft Switching ac-Link Universal Power Converter
5.4 Principle of Operation of the Soft Switching ac-Link Universal Power Converter
5.5 Design Procedure
5.6 Analysis
5.7 Applications
5.8 Summary
Acknowledgment
References
Chapter 6: High Power Electronics: Key Technology for Wind Turbines
6.1 Introduction
6.2 Development of Wind Power Generation
6.3 Wind Power Conversion
6.4 Power Converters for Wind Turbines
6.5 Power Semiconductors for Wind Power Converter
6.6 Controls and Grid Requirements for Modern Wind Turbines
6.7 Emerging Reliability Issues for Wind Power System
6.8 Conclusion
References
Chapter 7: Photovoltaic Energy Conversion Systems
7.1 Introduction
7.2 Power Curves and Maximum Power Point of PV Systems
7.3 Grid-Connected PV System Configurations
7.4 Control of Grid-Connected PV Systems
7.5 Recent Developments in Multilevel Inverter-Based PV Systems
7.6 Summary
References
Chapter 8: Controllability Analysis of Renewable Energy Systems
8.1 Introduction
8.2 Zero Dynamics of the Nonlinear System
8.3 Controllability of Wind Turbine Connected through L Filter to the Grid
8.4 Controllability of Wind Turbine Connected through LCL Filter to the Grid
8.5 Controllability and Stability Analysis of PV System Connected to Current Source Inverter
8.6 Conclusions
References
Chapter 9: Universal Operation of Small/Medium-Sized Renewable Energy Systems
9.1 Distributed Power Generation Systems
9.2 Control of Power Converters for Grid-Interactive Distributed Power Generation Systems
9.3 Ancillary Feature
9.4 Summary
References
Chapter 10: Properties and Control of a Doubly Fed Induction Machine
10.1 Introduction. Basic principles of DFIM
10.2 Vector Control of DFIM Using an AC/DC/AC Converter
10.3 DFIM-Based Wind Energy Conversion Systems
References
Chapter 11: AC–DC–AC Converters for Distributed Power Generation Systems
11.1 Introduction
11.2 Pulse-Width Modulation for AC–DC–AC Topologies
11.3 DC-Link Capacitors Voltage Balancing in Diode-Clamped Converter
11.4 Control Algorithms for AC–DC–AC Converters
11.5 AC–DC–AC Converter with Active Power FeedForward
11.6 Summary and Conclusions
References
Chapter 12: Power Electronics for More Electric Aircraft
12.1 Introduction
12.2 More Electric Aircraft
12.3 More Electric Engine (MEE)
12.4 Electric Power Generation Strategies
12.5 Power Electronics and Power Conversion
12.6 Power Distribution
12.7 Conclusions
References
Chapter 13: Electric and Plug-In Hybrid Electric Vehicles
13.1 Introduction
13.2 Electric, Hybrid Electric and Plug-In Hybrid Electric Vehicle Topologies
13.3 EV and PHEV Charging Infrastructures
13.4 Power Electronics for EV and PHEV Charging Infrastructure
13.5 Vehicle-to-Grid (V2G) and Vehicle-to-Home (V2H) Concepts
13.6 Power Electronics for PEV Charging
References
Chapter 14: Multilevel Converter/Inverter Topologies and Applications
14.1 Introduction
14.2 Fundamentals of Multilevel Converters/Inverters
14.3 Cascaded Multilevel Inverters and Their Applications
14.4 Emerging Applications and Discussions
14.5 Summary
Acknowledgment
References
Chapter 15: Multiphase Matrix Converter Topologies and Control
15.1 Introduction
15.2 Three-Phase Input with Five-Phase Output Matrix Converter
15.3 Simulation and Experimental Results
15.4 Matrix Converter with Five-Phase Input and Three-Phase Output
15.5 Sample Results
Acknowledgment
References
Chapter 16: Boost Preregulators for Power Factor Correction in Single-Phase Rectifiers
16.1 Introduction
16.2 Basic Boost PFC
16.3 Half-Bridge Asymmetric Boost PFC
16.4 Interleaved Dual-Boost PFC
16.5 Conclusion
References
Chapter 17: Active Power Filter
17.1 Introduction
17.2 Harmonics
17.3 Effects and Negative Consequences of Harmonics
17.4 International Standards for Harmonics
17.5 Types of Harmonics
17.6 Passive Filters
17.7 Power Definitions
17.8 Active Power Filters
17.9 APF Switching Frequency Choice Methodology
17.10 Harmonic Current Extraction Techniques (HCET)
17.11 Shunt Active Power Filter
17.12 Series Active Power Filter
17.13 Unified Power Quality Conditioner
Acknowledgment
References
Chapter 18A: Hardware-in-the-Loop Systems with Power Electronics: A Powerful Simulation Tool
18A.1 Background
18A.2 Increasing the Performance of the Power Stage
18A.3 Machine Model of an Asynchronous Machine
18A.4 Results and Conclusions
References
Chapter 18B: Real-Time Simulation of Modular Multilevel Converters (MMCs)
18B.1 Introduction
18B.2 Choice of Modeling for MMC and Its Limitations
18B.3 Hardware Technology for Real-Time Simulation
18B.4 Implementation for Real-Time Simulator Using Different Approach
18B.5 Conclusion
References
Chapter 19: Model Predictive Speed Control of Electrical Machines
19.1 Introduction
19.2 Review of Classical Speed Control Schemes for Electrical Machines
19.3 Predictive Current Control
19.4 Predictive Torque Control
19.5 Predictive Torque Control Using a Direct Matrix Converter
19.6 Predictive Speed Control
19.7 Conclusions
Acknowledgment
References
Chapter 20: The Electrical Drive Systems with the Current Source Converter
20.1 Introduction
20.2 The Drive System Structure
20.3 The PWM in CSCs
20.4 The Generalized Control of a CSR
20.5 The Mathematical Model of an Asynchronous and a Permanent Magnet Synchronous Motor
20.6 The Current and Voltage Control of an Induction Machine
20.7 The Current and Voltage Control of Permanent Magnet Synchronous Motor
20.8 The Control System of a Doubly Fed Motor Supplied by a CSC
20.9 Conclusion
References
Chapter 21: Common-Mode Voltage and Bearing Currents in PWM Inverters: Causes, Effects and Prevention
21.1 Introduction
21.2 Determination of the Induction Motor Common-Mode Parameters
21.3 Prevention of Common-Mode Current: Passive Methods
21.4 Active Systems for Reducing the CM Current
21.5 Common-Mode Current Reduction by PWM Algorithm Modifications
21.6 Summary
References
Chapter 22: High-Power Drive Systems for Industrial Applications: Practical Examples
22.1 Introduction
22.2 LNG Plants
22.3 Gas Turbines (GTs): the Conventional Compressor Drives
22.4 Technical and Economic Impact of VFDs
22.5 High-Power Electric Motors
22.6 High-Power Electric Drives
22.7 Switching Devices
22.8 High-Power Converter Topologies
22.9 Multilevel VSI Topologies
22.10 Control of High-Power Electric Drives
22.11 Conclusion
Acknowledgment
References
Chapter 23: Modulation and Control of Single-Phase Grid-Side Converters
23.1 Introduction
23.2 Modulation Techniques in Single-Phase Voltage Source Converters
23.3 Control of AC–DC Single-Phase Voltage Source Converters
23.4 Summary
References
Chapter 24: Impedance Source Inverters
24.1 Multilevel Inverters
24.2 Quasi-Z-Source Inverter
24.3 qZSI-Based Cascade Multilevel PV System
24.4 Hardware Implementation
Acknowledgments
References
Index
End User License Agreement
Search in book...
Toggle Font Controls
Playlists
Add To
Create new playlist
Name your new playlist
Playlist description (optional)
Cancel
Create playlist
Sign In
Email address
Password
Forgot Password?
Create account
Login
or
Continue with Facebook
Continue with Google
Sign Up
Full Name
Email address
Confirm Email Address
Password
Login
Create account
or
Continue with Facebook
Continue with Google
Prev
Previous Chapter
Chapter 24: Impedance Source Inverters
Next
Next Chapter
End User License Agreement
Index
ABC natural reference frame current control
AC-AC conversion
AC-link converters
AC-module configuration
Active filter for cm current reduction
Active front end
Active power control
Active power feed-forward (APFF)
Active rectifier
Active zero voltage control
Adaptive
Airbus
Aircraft
Anti-islanding detection
APF
APU
Artificial
Asymmetric half-bridge
Asynchronous
Average model
Average modeling
Batteries
Battery charger
Bearing currents
Bearing protection rings
Bipolar junction transistor (BJT)
Bleed air
Blocking
Blowers
Boeing
Boost control
Boost-buck
Breakdown
Brushless
Buck-boost converter
Buffering
By-product
Canceler
Capacitive bearing current
Capacitor bank
Capacitor DC-link
Capacitor Flying
Carrier-based
Cascade multilevel inverter
Cascaded H-bridge
Centralized configuration
Channel
Circulating bearing current
Clarke
Climate change
Coil
Common mode choke
Common mode current reduction
Common mode equivalent circuit
Common mode passive filters
Common mode transformer
Common mode voltage (cmv)
Commutation requirements
Compatibility
Compensator
Compressed air storage
Compressor
Computers
Condensers
Constraints
Control accuracy
Control algorithm
Control current
Control delays
Control dynamics
Control loop
Control method
Control of permanent magnet synchronous motor
Control signals
Controllability
Controller dc-link voltage
Controller design
Controller line current
Controller line power
Controller machine angular speed
Controller machine electromagnetic torque
Controller proportional-integral (pi)
Controller stator flux
Controllers design
Converter 2-level
Converter 3-level
Converter ac-dc
Converter ac-dc-ac
Converter bidirectional
Converter dc-ac
Converter indirect
Converter simplified
Converter three-phase
Correlation
Coupling inductor
Cross-correlation
Cross-vector
Crowbar
CSI
Cùk converter
Current and voltage control
Current control
Current loop
Current source converter
Current source inverter,
see
CSI
Current source rectifier
Current tracking
Cycloconverter
Damping
Data
DC-DC converter
DC-DC power converters
DDPWM
Dead-time
Dead-time effect
Decoupling network (dn)
Deicing
Design of dc– link voltage control loop
Design of pi based current control loop
Design of pr based current control loop
Detailed model
Detuning angle
Detuning problem
DFT
Dielectric
Digital signal processor (dsp)
Diode clamped multilevel inverter
Dips
Direct duty ratio
Direct power and torque control with space vector modulations (DPTC-SVM)
Direct power control-space vector modulated (DPC-SVM)
Direct torque control
Direct torque control-space vector modulated (DTC-SVM)
Distributed generation
Distributed power generation systems (DPGSS)
Disturbance
Doubly fed induction machine (DFIM)
DQ synchronous reference frame current control
Droop control
DSP
Dual-boost
Durability
Eddy-current
Electric machines
Electric vehicles
Electric/hybrid vehicles
Electrical machine model
Electromagnetic interference (EMI)
Electromagnetic torque
Elevators
Emission
EN61000–
EN61000–
Energy conservation
Energy storage
Energy storage systems
Enslin
FACTS
FADEC
Fans
Fault tolerance and reliability
Feedback
Feed-forward
FFT
Fictitious
Field oriented control
Field oriented control (foc)
Filter
Five phase
Flicker
Flux oriented control
Flyback
Flying capacitor converters (FCCs)
Flying capacitor multilevel inverter
Flywheel
Fourier
FPGA
Fractional open-circuit voltage
Fractional short-circuit current
Freewheeling
Frequency fundamental
Frequency harmonics
Frequency sampling
Frequency switching
Fuel cell
Gallium nitride
Gas turbines
Gate injection transistor (git)
Gate turn-off thyristor (gto)
GCT
GDU
Generalized multilevel inverter
Generators
Geothermal energy
Geothermal power
Global warming
Greenhouse gases
Grid AC
Grid codes
Grid connection
Grid current
Grid DC
Grid side
Grid voltage dips
Grid-interactive distributed power generation systems
Grid-tied converter
H– Diode clamped converter
Hardware
Hardware-in-the-loop (HIL)
Harmonic compensation
H– Bridge converter
HCET
Heaters
Heating
H-Flying capacitor converter
High electron mobility transistor (HEMT)
High-frequency current ripple
High-impedance
HNPC
HVDC
Hybrid modulation
Hysteresis
Hysteretic control
Identification
Ieee
IEGT
IGBT
IGCT
Impedance parameter
Incremental conductance
Induction motor
Inductive
Inductor size
Industrial voltage source inverters (VSIS)
Industries
Inertia emulation
Inherent characteristics
Input/output feedback linearization
Insulated gate bipolar transistor (IGBT)
Insulation
Integrated choke
Integrated gate commutated thyristor (IGCT)
Intelligent maintenance
Interference
Interior permanent magnet
Interior permanent magnet (IPM)
Interleaved converters
Internal dynamic
Inverter modulation index
Inverter under test (IUT)
Islanding detection
Isolator
Junction field effect transistor JFET
Kalman
K-phase
Lamps
LCI
LCL filter
Leakage current
Lighting
Linear control
Liquefied
Lng plant
Load current estimation
Low voltage ride through
Low-order
Low-pass filter
Machine model of an asynchronous machine
Machine side
Magnetic bearing
Magnetic freewheeling control
Magnetic-less multilevel DC-DC converters
Matrix converter
Maximum output
Maximum power point tracking
Maximum switching losses
Microgrids
Microprocessors
Mini-Hydro generators
Misoperation
Mitigation methods to global warming
Model predictive control
Modeling approach
Modular multilevel converter
Modulation algorithm
Modulation index
Modulation indices
Modulation method
Modulation period
Modulation range
Modulation techniques
Modulus optimum (MO)
More electric aircraft
More electric engine
MOSFET
Motor drives
M-phase
MPPT
Multilevel inverter
Multi-loops control
Multi-phase
Multiplier/divider
Multi-scalar control system structure
Multi-scalar control
Multi-scalar model
Multi-scalar variables
Multi-string configuration
Mutual inductance
Natural gas
Network management
Neural
Neurons
Noise-canceling
Non-minimum phase
Nondistorted
Nonfundamental
Nonlinear control
Nonlinear system
Nonlinearity compensation control
Non-sinusoidal
Nonstiff
NPC
N-phase
Offset duty ratio
One– dimensional modulation
Orthogonal
Oscillations
Overheating
Overloading
Overvoltage
Parallel programming
Parallel-connection
Periodic
Perturb and observe
Phase locked loop (PLL)
Phase-locked
Photovoltaic energy
Photovoltaic generators
Photovoltaic power generation
Photovoltaic systems
Photovoltaics
Physical
Pollution
Polyphase
Position observer
Position sensor
Power coefficient
Power control
Power distribution
Power factor correction (PFC)
Power hardware in the loop PHIL
Power module
Power optimized aircraft
Power quality
Power semiconductor devices
Power systems
Power transistors
P-q
P-q-r
Predictive
Predictive current control
Predictive torque control
Programmable logic controls (PLCS)
Proportional resonant controller
Propulsion
Protection
Protective
Proximity
Pulse width modulation
PV energy
Quality of the grid current
Quasi-z source cascade multilevel inverter
Quasi-z-source inverter
RDFT
Reactive power capability
Reactive power control
Reactor
Real time simulation
Real-time
Rectifier
Rectifiers
Recursive
Refrigeration
Refrigerators
Relay
Reliability
Renewable energy
Renewable energy system
Rotor grounding current
Routh-Hurwitz criteria
Sampling period
Sampling time
Saturation
Scaling factor
Scherbius
Semiconductor devices
Sensorless control
Sepic
Sequence decomposition
Sequential programming
Sequential switching
Seven phase
Shaft voltage
Sheppard-Taylor
Silicon carbide
Silicon carbide devices
Single-phase converter
Single-stage inverter
Small- and medium-sized enterprises (SMES)
Small wind turbine systems
Small-signal model
Smart grid
Smart metering
Soft switching
Space vector modulation (SVM)
Space vector modulation with one zero vector (SVM1Z)
Space vector state
Speed control
Stability
Standalone operation
Standards
Standards for smart grids
State-space model
Steady state model
Strength modeling
Stress analysis
String configuration
Superconductor
SVPWM
Switching combinations
Switching frequency
Switching function
Symmetry optimum (SO)
Synchronization
Synchronous motor
Technical and economic impact
Three active vector modulation (3AVM)
Three non-parity active vectors (3NPAV)
Thrust
Thyristor
Tidal power
Topology classical
Topology simplified
Total harmonic distortion (THD)
Traction
Transfer functions
Transformation matrix
Transformerless
Transformerless topology
T-Type
Unbalanced grid
Unipolar modulation
Universal power converters
Variable speed drives
Variable speed drives VSD
Variable speed generation
Vector control
Vehicle-to-grid storage
Virtual flux (VF)
Virtual machine(VM)
Virtual torque (VT)
Voltage control
Voltage drop
Voltage loop
Voltage oriented control (VOC)
Voltage regulation
Voltage ripple
Voltage source converter
Voltage source converters (VSCS)
Voltage source inverter (VSI)
Wave energy
Wide bandgap
Wind energy
Wind energy conversion systems (or wind energy conversion)
Wind generators
Wind power generation
Wind turbine aerodynamic
Wind turbine control
Zero dynamics
Z-source inverter
Add Highlight
No Comment
..................Content has been hidden....................
You can't read the all page of ebook, please click
here
login for view all page.
Day Mode
Cloud Mode
Night Mode
Reset