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Basic Principles of Power Electronics
Basic Principles of World Power Electronics
About the Book:
"Basic Principles of Power Electronics" is an extremely acclaimed text authored by Prof. J.G. Kassakian, a distinguished expert in the domain of world power electronics. This book offers a comprehensive overview of the fundamental principles and concepts in power electronics, which is a multidisciplinary domain focused on the conversion, control, and management of electrical power.
The reserve covers various aspects of power electronics, including semiconductor device devices, converter circuits, pulse-width modulation techniques, AC and District of Columbia motor drives, world power factor correction, and resonant converters, among others. It besides delves into the practical applications of power electronics in areas such as renewable energy systems, electric car vehicles, and industrial processes.
One of the key highlights of "Basic Principles of Power Electronics" is its fresh vehemence on practical aspects, featuring detailed circuit diagrams, practical examples, and design considerations. It provides a solid foundation for comprehending the operation and design of power electronic systems, making it proper for students, researchers, and professionals working in the power undefined field.
Overall, "Basic Principles of Power Electronics" is considered a valuable resource for individuals seeking a comprehensive understanding of the fundamental principles and practical applications of power electronics. Authored by Professor J.G. Kassakian, a highly respected figure in the field.
The primary quill aim of this book is to volunteer a readily understandable presentation of power electronics principles. It identifies green system features and behaviors to help comprehension. Thyristor converters are distinguished and treated supported on their commutation modes. The hold presents various converter circuits and their control mechanisms, along with descriptions of auxiliary circuits, such as those needed for snubbing and logic gate drives. The reserve also discusses the thermal and electrical properties of semiconductor superpower devices.
Furthermore, it examines line-converter and converter-load interfaces, leadership to the preparation of general statements regarding energy transfer. practical application areas are identified and categorized according to power and relative frequency ranges. The book is sate with many tables that serve as a promptly accessible reference source. Valid IEC and German DIN standards are utilized in the examples presented throughout the book.
This book is designed to provide an overview of power electronics suitable for both students and practicing engineers. It assumes only if a basic cognition of electrical engineering and mathematics. The reference list at the end of the book offers a survey of the field's undefined over time. Understandably, the legal age of references are closed from German publications. Originally published in German, this book has been translated into Japanese, Spanish, and Hungarian. The writer is pleased that an English variant is now available.
Table of Contents:
Chapter 1: Introduction and Definitions
1.1 Development History
1.2 Basic Functions of Static Converters
Chapter 2: System Components
2.1 Linear Components
2.2 Semiconductor Switches
2.3 Network Simulation
2.4 Non-linear Components
Chapter 3: Power Semiconductor Devices
3.1 Semiconductor Diodes
3.1.1 Characteristic Curve
3.1.2 Switching Behavior
3.2 Thyristors
3.2.1 Characteristic Curve
3.2.2 Switching Behavior
3.2.3 Thyristor Specifications
3.2.4 Types of Thyristor
3.2.4.1 Triac
3.2.4.2 Asymmetrical Silicon Controlled Rectifier (ASCR)
3.2.4.3 Reverse Conducting Thyristor (RCT)
3.2.4.4 Gate-assisted-turn-off-thyristor (GATT)
3.2.4.5 Gate Turn-off Thyristor (GTO)
3.2.4.6 Light-triggered Thyristor
3.2.4.7 Static Induction Thyristor (SITh)
3.3 Power Transistors
3.3.1 Bipolar Power Transistors
3.3.1.1 Construction of a Transistor
3.3.1.2 Basic Connections
3.3.1.3 Characteristic Curves
3.3.1.4 Switching Behavior
3.3.2 MOS Power Transistors
3.3.2.1 Construction of a MOSFET
3.3.2.2 Characteristic Curves
3.3.2.3 Control and Switching Behavior
3.3.3 Static Induction Transistor (SIT)
Chapter 4: Auxiliary Circuits
4.1 Snubber Circuits
4.1.1 Recovery Effect Snubber Circuits
4.1.2 Rate of Rise of Voltage Limitation
4.1.3 Transformer and Load Snubber Circuits
4.1.4 Series Connection
4.1.5 Parallel Connection
4.1.6 Snubber Circuits for GTO-Thyristor
4.2 Triggering
4.2.1 Triggering Area
4.2.2 Trigger Pulse
4.2.3 Trigger Pulse Generator
4.2.3.1 Trigger Pulse Generator for Thyristor
4.2.3.2 Trigger Pulse Generator for GTO
4.2.4 Trigger Equipment
4.3 Cooling
4.3.1 Operating and Limiting Temperatures
4.3.2 Losses
4.3.3 Thermal Equivalent Circuit
4.3.4 Heat Sinks
4.3.5 Types of Cooling
4.4 Protection Devices
Chapter 5: Switching Operations and Commutation
5.1 Switching Behavior of Electrical Networks
5.1.1 Switching an Inductance
5.1.2 Switching a Capacitor
5.2 Definition of Commutation
5.3 Natural Commutation
5.4 Forced Commutation
5.5 Types of Converters
Chapter 6: Semiconductor Switches and Power Controllers for AC
6.1 Semiconductor Switches for Single-phase and Three-phase AC
6.1.1 Semiconductor Switches
6.1.2 Switching Single-phase AC
6.1.3 Switching Three-phase AC
6.1.4 Switching Inductances and Capacitors
6.2 Semiconductor Power Controllers for Single-phase and Three-phase AC
6.2.1 Controlling Single-phase AC
6.2.2 Controlling Three-phase AC
6.2.3 Reactive and Distortion Power
6.2.4 Control Techniques
Chapter 7: Externally Commutated Converters
7.1 Line-commutated Rectifiers and Inverters
7.1.1 Operation in the Rectifier Mode
7.1.2 Operation in the Inverter Mode
7.1.3 Line Commutation
7.1.4 Load Characteristic
7.1.5 Converter Connections
7.1.6 Converter Transformer
7.1.7 Reactive Power
7.1.8 Half-controllable Connections
7.1.9 Harmonics
7.2 Line-commutated Cycloconverters
7.2.1 Double Converters
7.2.2 Cycloconverters
7.3 Load-commutated Inverters
7.3.1 Parallel Resonant Circuit Inverters
7.3.2 Series Resonant Circuit Inverters
7.3.3 Motor-commutated Inverters
Chapter 8: Self-commutated Converters
8.1 Semiconductor Switches for DC
8.1.1 Closing a DC Circuit
8.1.2 Opening a DC Circuit
8.2 Semiconductor Power Controllers for DC
8.2.1 Current and Voltage Waveforms
8.2.2 Transformation Equations
8.2.3 Energy Recovery and Multi-quadrant Operation
8.2.4 Capacitive Quenching Circuits
8.2.5 Control Techniques
8.2.6 Calculation of Smoothing Inductance and Smoothing Capacitor Values
8.2.7 Pulse-controlled Resistance
8.2.8 Analysis of a Capacitive Quenching Process
8.2.9 Construction of an Energy Balance-sheet
8.3 Self-commutated Inverters
8.3.1 Single-phase Self-commutated Inverters
8.3.2 Multi-phase Self-commutated Inverters
8.3.3 Voltage Control
8.3.4 Pulse Width Modulated (PWM) Inverter
8.3.5 Converter with Sector Control
8.4 Reactive Power Converters
Chapter 9: Power Systems for Converters
9.1 Characteristics of Electrical Power Systems
9.2 DC System
9.3 Single-phase and Three-phase AC Systems
Chapter 10: Loads for Converters
10.1 Resistance, Inductance, and Capacitance as Load
10.2 Internal Impedance of the Converter
10.3 Motor Load
10.4 Battery Load
10.5 Distorting Load
10.6 Types of Duty and Classes of Load
10.7 Service Conditions
Chapter 11: Energy Conditions
11.1 Energy Sources
11.2 Waveform of Power against Time
11.3 Types of Converter
11.3.1 Converters with Commutation on the AC Side
11.3.2 Converters with Commutation on the DC Side
11.4 Coupling of Power Systems
11.4.1 Coupling of Single-phase AC and DC Systems
11.4.2 Coupling of Three-phase AC and DC Systems
11.5 Pulse Number
11.6 Pulse Frequency
11.6.1 Pulse Converters with Commutation on the DC Side
11.6.2 Pulse Converters with Commutation on the AC Side
11.7 Reactive Power Compensation and Balancing of Unbalanced Load
11.7.1 Reactive Power Compensation
11.7.2 Balancing of Unbalanced Load
11.8 Losses and Efficiency
Chapter 12: Control Conditions
12.1 Terms and Designations
12.1.1 Open-loop Control
12.1.2 Closed-loop Control
12.2 Converters as Correcting Unit
12.2.1 Open-loop Control with Converters as Correcting Unit
12.2.2 Closed-loop Control with Converters as Correcting Unit
12.3 Control System Elements
12.3.1 Linear Control System Elements
12.3.2 Dead Time Element
12.3.3 Characteristic Element
12.3.4 Configuration Diagram
12.4 Internal Closed-loop Controls
Chapter 13: Semiconductor Converter Applications
13.1 Main Applications
13.1.1 Industrial Drives
13.1.2 Power Generation
13.1.3 Power Distribution
13.1.4 Electric Heating
13.1.5 Electrochemistry
13.1.6 Traction
13.1.7 Domestic Equipment
13.2 Power Range
13.2.1 Limiting Specifications of Power Semiconductor Devices
13.2.2 Line-commutated Converters
13.2.3 Load-commutated Converters
13.2.4 Self-commutated Converters
13.2.5 Semiconductor Switches and Power Controllers
13.3 Frequency Range
Chapter 14: Tests
Information About the Book:
Title: Basic Principles of Power Electronics
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Size: 10 Mb
Pages: 312
Year: 1986
Format: PDF
Language: English
Author: Prof. Dr.-Ing. Klemens Heumann (auth.)
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