Power electronics and motor drive systems
Power Electronics and Motor Drive Systems is designed to aid electrical engineers, researchers, and students to analyze and address common problems in state-of-the-art power electronics technologies. Author Stefanos Manias supplies a detailed discussion of the theory of power electronics circuits an...
| Otros Autores: | |
|---|---|
| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
London, [England] :
Academic Press
2017.
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| Edición: | 1st edition |
| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009630169406719 |
Tabla de Contenidos:
- Front Cover
- Power Electronics and Motor Drive Systems
- Power Electronics and Motor Drive SystemsStefanos N. ManiasSchool of Electrical and Computer Engineering National Technical ...
- Copyright
- Dedication
- Contents
- About the Author
- Preface
- Acknowledgments
- List of Abbreviations
- List of Symbols
- 1 - Power Electronics Technology
- 1.0 Introduction to Power Electronics Technology
- 1.1 Synthesis of a Required Voltage Waveform
- 1.2 Power Electronics Applications
- 1.3 Introduction to Power Semiconductor Devices
- Bibliography and Publications
- 2 - Circuits With Switches and Diodes
- 2.0 Introduction
- 2.1 Circuit With DC Source and Resistive-Capacitive Load
- 2.2 Circuit With DC Source and Resistive-Inductive Load
- 2.3 Circuit With DC Source and Inductive Load
- 2.4 Circuit With DC Source and R-L-C Load
- 2.5 Circuit With AC Source and R-L-C Load
- 2.6 Power Diode
- 2.6.1 Power Diode Dynamic Switching Characteristics
- Solution
- 2.7 Single-Phase Half-Wave Diode Rectifier With Resistive Load
- 2.8 Single-Phase Half-Wave Diode Rectifier With Resistive-Capacitive Load
- 2.9 Single-Phase Half-Wave Diode Rectifier With R-L Load
- 2.10 Single-Phase Half-Wave Diode Rectifier With R-L Load and Freewheeling Diode
- 2.11 Single-Phase Half-Wave Diode Rectifier With R-L-E Load
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Bibliography and Publications
- 3 - Thyristor and Single-Phase Half-Wave Controlled Rectifier
- 3.0 Introduction
- 3.1 Thyristor-Silicon Controlled Rectifier
- 3.1.1 Thyristor Dynamic Behavior
- 3.2 Single-Phase Half-Wave Thyristor Rectifier With Resistive Load
- 3.3 Single-Phase Half-Wave Thyristor Rectifier With Resistive-Inductive Load
- 3.4 Single-Phase Half-Wave Thyristor Rectifier With Inductive Load.
- 3.5 Single-Phase Half-Wave Thyristor Rectifier With R-L-E Load
- 3.6 Gate Drive Circuits for Thyristors
- Solution
- Solution
- Solution
- Solution
- 3.7 Simulation Examples Using the Power Simulation Software Program
- Solution
- Solution
- Bibliography and Publications
- 4 - Diode Rectifiers
- 4.0 Introduction
- 4.1 Single-Phase Full-Wave Diode Rectifier With Center-Tapped Transformer
- 4.1.1 Evaluation of the Rectifier Input Current When the Output Current Is Pure DC of I¯o Value
- 4.2 Power Components Calculation and Power Quality for Nonlinear Loads
- 4.2.1 Power Components Calculation for Sinusoidal Voltage and Nonsinusoidal Input Current
- 4.2.2 Power Components Calculation When Both Voltage and Input Current Are Nonsinusoidal
- 4.2.3 Power Components Calculation for a Single-Phase Full-Wave Rectifier With Center-Tapped Transformer When the Output Current ...
- 4.3 Single-Phase Full-Bridge Diode Rectifier
- 4.4 Multiphase Half-Wave Diode Rectifiers
- 4.5 Three-Phase Bridge Diode Rectifier
- 4.5.1 Rectifier Analysis When the Output Current Is Pure DC of I¯o Value
- 4.5.2 Rectifier Analysis When the Output Current Is Discontinuous
- 4.6 Twelve-Pulse Diode Rectifier
- 4.7 Commutation Overlap Phenomenon of Diodes
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- 4.8 Simulation Examples Using Power Simulation Software
- Bibliography and Publications
- 5 - Thyristor-Controlled Rectifiers
- 5.0 Introduction
- 5.1 Single-Phase Full-Bridge Fully Controlled Thyristor Rectifier
- 5.1.1 Rectifier Analysis for Various Conditions of Operation
- 5.1.1.1 Operation With Discontinuous Output Current and Resistive Load
- 5.1.1.2 Operation With Discontinuous Output Current and R-L Load
- Solution.
- 5.1.1.3 Operation With Continuous Output Current and R-L Load
- Solution
- 5.1.1.4 Operation With Continuous Output Current and R-L-E Load
- Solution
- Solution
- 5.1.1.5 Operation With Pure DC Output Current of I¯o Value and R-L-E Load
- Solution
- Solution
- 5.1.1.6 Rectifier Operating in Inverter Mode
- Solution
- 5.1.2 Linear Control of Rectifier Output Voltage
- 5.1.3 Cosine Control of Rectifier Output Voltage
- 5.2 Three-Phase Half-Wave Thyristor Rectifier
- 5.3 Three-Phase Bridge Fully Controlled Thyristor Rectifier
- 5.3.1 Operation With Pure DC Output Current of I¯o Value
- 5.3.2 Conduction Angle Overlap Phenomenon in the Three-Phase Half-Wave Thyristor Rectifier
- 5.3.3 Conduction Angle Overlap Phenomenon in the Three-Phase Bridge Fully Controlled Thyristor Rectifier
- Solution
- Solution
- 5.4 Asymmetric or Half-Controlled Rectifiers
- Solution
- Solution
- 5.5 Twelve-Pulse Fully Controlled Thyristor Rectifier
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Solution
- Bibliography and Publications
- 6 - Inverters (DC-AC Converters)
- 6.0 Introduction
- 6.1 Single-Phase Half-Bridge Inverter
- 6.2 Single-Phase Full-Bridge Inverter
- 6.3 Output Voltage Control of Single-Phase Inverters
- 6.3.1 Single Pulse Width Modulation Technique for Quasi Square-Wave Single-Phase Full-Bridge Inverter
- Solution
- Solution
- 6.3.2 Single-Phase Two-Level Sinusoidal Pulse Width Modulation
- Solution
- Solution
- Solution
- Solution
- Solution
- 6.4 Three-Phase Voltage Source Inverter
- 6.4.1 Operation of the Three-Phase Full-Bridge Inverter With 180° Switch Conduction
- Solution
- Solution
- 6.4.2 Operation of the Three-Phase Full-Bridge PWM Inverter With 120° Switch Conduction.
- 6.4.3 Operation of the Three-Phase Full-Bridge Inverter With Sinusoidal Pulse Width Modulation Control Technique
- Solution
- 6.5 Multilevel Voltage Source Inverters
- 6.5.1 Neutral Point Diode Clamped Multilevel Inverters
- 6.5.2 Flying Capacitors Multilevel Inverters
- Solution
- 6.5.3 Cascaded H-bridge Multilevel Inverters
- 6.5.4 Modular Multilevel Converter
- 6.5.5 Application of Sinusoidal Pulse Width Modulation Control Technique to Multilevel Inverters
- 6.5.5.1 Application of PD-SPWM Control Technique to Five-Level NPDCMI and FCMIs
- 6.5.5.2 Application of APOD-SPWM Control Technique to Five-Level DCMI and FCMI
- 6.5.5.3 PSC-SPWM Control Technique Applied to a Single-Phase Five-Level CHBMI
- 6.5.6 Comparison Between the Conventional and Multilevel Inverters
- 6.6 Current Source Inverters
- 6.6.1 Operation of a Three-Phase CSI Based on Quasi Square-Wave Output Line Currents
- 6.6.2 Operation of Single-Phase Forced Commutated Current Source Inverter
- Mode I (Fig. 6.102(c))
- Mode II (Fig. 6.102(d))
- Mode III
- 6.7 Selected Harmonic Elimination Technique and SHE-PWM
- 6.7.1 SHE Technique Applied to the Inverter Output Voltage Without PWM
- 6.7.1.1 SHE-PWM Technique Applied to Two-Level Output Voltage
- Solution
- 6.7.1.2 Selected Harmonic Elimination Applied to a Three-Level Output Voltage
- 6.7.1.3 SHE-PWM Technique Applied to a Three-Level Output Voltage
- 6.7.1.4 SHE-PWM Technique With 60° Modulation (Modified SHE Technique)
- 6.8 Other Pulse Width Modulation Techniques
- 6.8.1 Trapezoidal Pulse Width Modulation
- 6.8.2 Harmonic Injection Pulse Width Modulation
- 6.8.3 Multiple Pulses Pulse Width Modulation and Staircase Pulse Width Modulation
- 6.8.4 60°-Pulse Width Modulation
- 6.8.5 Hysteresis Band Current Controlled Pulse Width Modulation
- 6.8.6 Space Vector Pulse Width Modulation.
- 6.8.6.1 Derivation of Switching States and Respective Output Voltages of a Three-Phase Two-Level Inverter
- 6.8.6.2 Clarke and Park Reference Frame Transformations
- 6.8.6.3 Implementation Steps of the SVPWM Technique for a Three-Phase Two-Level Voltage Source Inverter
- 6.9 P-Q Control of a Three-Phase Voltage Source Inverter
- Solution
- 6.9.1 P-Q Control Based on the Decoupling Control of d-q Current Components
- Solution
- Bibliography and Publications
- 7 - DC-DC Converters
- 7.0 Introduction
- 7.1 Step-Down or Buck Converter
- 7.1.1 Buck Converter Analysis When the Inductor Current Is Continuous
- 7.1.2 Buck Converter Analysis When the Inductor Current Is Discontinuous
- Solution
- Solution
- Solution
- Solution
- 7.2 Step-Up or Boost Converter
- 7.2.1 Boost Converter Analysis When the Inductor Current Is Continuous
- 7.2.2 Boost Converter Analysis When the Inductor Current Is Discontinuous
- Solution
- Solution
- 7.3 Buck-Boost (Step-Down-Step-Up) DC-DC Converter
- Solution
- 7.4 Output Voltage Control of DC-DC Converters Using Pulse Width Modulation Technique
- 7.5 Switched-Mode Power Supplies
- 7.5.1 Flyback Converter Analysis
- 7.5.1.1 Flyback Converter Analysis When the Magnetizing Current Is Continuous
- 7.5.1.2 Flyback Converter Analysis When the Magnetizing Current Is Discontinuous
- Solution
- Solution
- 7.5.2 Waveforms and Transfer Functions of the DC-DC Converters of Fig. 7.17 Except Flyback
- 7.6 State-Space Representation of DC-DC Converters
- 7.6.1 Boost Converter State-Space Equations for Continuous Current Operation and Ideal Components
- 7.6.2 Buck Converter State-Space Equations for Continuous Current Operation and Ideal Components
- 7.7 Discrete State Equations of Boost and Buck Converters
- 7.8 Simplified Circuits and Approximate Transfer Functions of Boost and Buck Converters.
- 7.9 Boost and Buck Converter Simulation Using SPICE and MATLAB/Simulink Software.
