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Liu H., Zhou Z., Li Y., Wu W., Jiang J., Shi E. Impedance Source Inverters
- Файл формата pdf
- размером 14,46 МБ
- Добавлен пользователем Евгений Машеров
- Описание отредактировано
New York: Springer, 2020. — 293 p.This book focuses on impedance source inverters, discussing their classification, advantages, topologies, analysis methods, working mechanisms, improvements, reliability, and applications. It summarizes methods for suppressing DC-link voltage spikes and duty loss, which can pose a problem for researchers; and presents novel, efficient, steady state and transient analysis methods that are of significant practical value, along with specific calculation examples. Further, the book addresses the reliability of impedance source inverters, adopting a methodology from reliability engineering to do so. Given its scope, it offers a valuable resource for researchers, engineers, and graduate students in fields involving impedance source inverters and new energy sources.Energy Situation
Traditional Power Inverter Topologies
Impedance Source Inverters
Classification of Impedance Source Inverters
Contents OutlineStructure and Equivalent Circuit
Circuit Analysis
Quasi-Z-Source Inverter
Simple Boost Pulse-Width Modulation
Maximum Boost Pulse-Width Modulation
Other Boost Pulse-Width ModulationSingle-Loop Methods
Structure of Current-Fed Z-Source Inverter
Modes of Current-Fed Z-Source Inverter
Modulation of Current-Fed Z-Source Inverter
Closed-Loop Control of Current-Fed Z-Source InverterZ-Source Inverter
High-Performance Improved Z-Source Inverters
Neutral Point Z-Source Inverters
Reduced Leakage Current Z-Source Inverters
Other Basic Z-Source Inverters
Switched Components Z-Source Inverters
Tapped Inductor Z-Source Inverters
Cascaded Quasi-Z-Source Inverters
Three-Level Z-Source Inverters
High-Frequency Transformer Isolated Z-Source Topologies
Low DC-Link Voltage Spikes Y-Source TopologiesT-Source Inverter
Trans-Quasi-Z-Source Inverter
Improved Trans-Quasi-Z-Source Inverter
Inductor–Capacitor–Capacitor–Transformer ZSI
Γ-Source InverterY-Source Inverter
Improved Y-Source Inverter
Extended Quasi-Y-Source Inverter
Startup Current Suppression
Operational States
Current Ratings and Core Size of Coupled Inductor
Component Stresses
Loss of ST Duty Ratio
DC-Link Voltage Spikes
Experimental Results
Modified Y-Source InverterDual Diodes Capacitor–Diode Absorbing Circuits
Operational Modes
Current Analysis
Voltage Analysis
Switching Loss Analysis
Simulation and Experimental Results
Extension of Topologies Range
Single Diode Capacitor–Diode Clamping Circuits
Embedded Capacitor–Diode Absorbing Circuits
Operational States
Current Analysis
Voltage Analysis
Simulation and Experimental Results
Cascaded Quasi-Z-Network Clamping Circuits
Operational Modes
Current Analysis
Voltage Analysis
Stresses and Lifetime
Extra Power Loss Analysis
Simulation and Experimental ResultsTraditional Analysis of Voltage and Current Stresses
Current Analysis
Voltage Analysis
Method Applied to Other Converters
Transient Analysis Based on Impedance Source Inverter
Derivation of the Coupled Inductor Model
Derivation of the Whole Circuit Model
Switching Transient Analysis
Experimental ResultsBasic Concept of Reliability Theory
Index of Reliability Evaluation
Method for Physics of Failure
Reliability Block Diagram Method
Monte Carlo Method
Failure Mechanism of Power Devices
Electrical Structure of IGBT Module
The Package Structure of IGBT Module
Failure Mechanism of IGBT Module
Package-Related Fault
Burning Failure
Structure of Capacitor
Classification of Capacitors
Failure Mechanism of Capacitor
Thermal Model of IGBT
IGBT Power Loss Model
IGBT Thermal Model
Thermal Model of Capacitor
Lifetime Model Based on Statistics
Lifetime Model Based on Physical Mechanism
Lifetime Models of DC-Link Capacitors
Reliability Analysis of Life DistributionPower Decoupling Characteristics
Application of Impedance Source Inverter in Power Decoupling
Photovoltaic Power Characteristics
MPPT Control and System Control Methods
An Improved Y-Source Inverter PV System and Simulation Results
A Quasi-Z-Source Single-Phase Inverter PV System and Simulation Results
A Single-Phase Z-Source Inverter PV System and Simulation ResultsZ-Source Inverter for the Wind Power System
Simulation Results of a ZSI-Based Wind Power System
Quasi-Z-Source InverterZ-Source Inverter-Based Permanent Magnet Synchronous Motor
Modified Z-Source Inverter-Based Three-Phase Induction Motor Drive
Traditional Power Inverter Topologies
Impedance Source Inverters
Classification of Impedance Source Inverters
Contents OutlineStructure and Equivalent Circuit
Circuit Analysis
Quasi-Z-Source Inverter
Simple Boost Pulse-Width Modulation
Maximum Boost Pulse-Width Modulation
Other Boost Pulse-Width ModulationSingle-Loop Methods
Structure of Current-Fed Z-Source Inverter
Modes of Current-Fed Z-Source Inverter
Modulation of Current-Fed Z-Source Inverter
Closed-Loop Control of Current-Fed Z-Source InverterZ-Source Inverter
High-Performance Improved Z-Source Inverters
Neutral Point Z-Source Inverters
Reduced Leakage Current Z-Source Inverters
Other Basic Z-Source Inverters
Switched Components Z-Source Inverters
Tapped Inductor Z-Source Inverters
Cascaded Quasi-Z-Source Inverters
Three-Level Z-Source Inverters
High-Frequency Transformer Isolated Z-Source Topologies
Low DC-Link Voltage Spikes Y-Source TopologiesT-Source Inverter
Trans-Quasi-Z-Source Inverter
Improved Trans-Quasi-Z-Source Inverter
Inductor–Capacitor–Capacitor–Transformer ZSI
Γ-Source InverterY-Source Inverter
Improved Y-Source Inverter
Extended Quasi-Y-Source Inverter
Startup Current Suppression
Operational States
Current Ratings and Core Size of Coupled Inductor
Component Stresses
Loss of ST Duty Ratio
DC-Link Voltage Spikes
Experimental Results
Modified Y-Source InverterDual Diodes Capacitor–Diode Absorbing Circuits
Operational Modes
Current Analysis
Voltage Analysis
Switching Loss Analysis
Simulation and Experimental Results
Extension of Topologies Range
Single Diode Capacitor–Diode Clamping Circuits
Embedded Capacitor–Diode Absorbing Circuits
Operational States
Current Analysis
Voltage Analysis
Simulation and Experimental Results
Cascaded Quasi-Z-Network Clamping Circuits
Operational Modes
Current Analysis
Voltage Analysis
Stresses and Lifetime
Extra Power Loss Analysis
Simulation and Experimental ResultsTraditional Analysis of Voltage and Current Stresses
Current Analysis
Voltage Analysis
Method Applied to Other Converters
Transient Analysis Based on Impedance Source Inverter
Derivation of the Coupled Inductor Model
Derivation of the Whole Circuit Model
Switching Transient Analysis
Experimental ResultsBasic Concept of Reliability Theory
Index of Reliability Evaluation
Method for Physics of Failure
Reliability Block Diagram Method
Monte Carlo Method
Failure Mechanism of Power Devices
Electrical Structure of IGBT Module
The Package Structure of IGBT Module
Failure Mechanism of IGBT Module
Package-Related Fault
Burning Failure
Structure of Capacitor
Classification of Capacitors
Failure Mechanism of Capacitor
Thermal Model of IGBT
IGBT Power Loss Model
IGBT Thermal Model
Thermal Model of Capacitor
Lifetime Model Based on Statistics
Lifetime Model Based on Physical Mechanism
Lifetime Models of DC-Link Capacitors
Reliability Analysis of Life DistributionPower Decoupling Characteristics
Application of Impedance Source Inverter in Power Decoupling
Photovoltaic Power Characteristics
MPPT Control and System Control Methods
An Improved Y-Source Inverter PV System and Simulation Results
A Quasi-Z-Source Single-Phase Inverter PV System and Simulation Results
A Single-Phase Z-Source Inverter PV System and Simulation ResultsZ-Source Inverter for the Wind Power System
Simulation Results of a ZSI-Based Wind Power System
Quasi-Z-Source InverterZ-Source Inverter-Based Permanent Magnet Synchronous Motor
Modified Z-Source Inverter-Based Three-Phase Induction Motor Drive
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