Description
WILEY INDIA Power Quality Problems And Mitigation Techniques by Bhim Singh
Maintaining a stable level of power quality in the distribution network is a growing challenge due to increased use of power electronics converters in domestic, commercial and industrial sectors. Power quality deterioration is manifested in increased losses; poor utilization of distribution systems; mal-operation of sensitive equipment and disturbances to nearby consumers, protective devices and communication systems. However, as the energy-saving benefits will result in increased AC power processed through power electronics converters, there is a compelling need for improved understanding of mitigation techniques for power quality problems.
About the Author
Professor Bhim Singh has worked at the IIT Delhi Department of Electrical Engineering since 1997. He has 30 years' experience in research
TABLE OF CONTENTS
Preface
About the Companion Website
1 Power Quality: An Introduction
1.1 Introduction
1.2 State of the Art on Power Quality
1.3 Classification of Power Quality Problems
1.4 Causes of Power Quality Problems
1.5 Effects of Power Quality Problems on Users
1.6 Classification of Mitigation Techniques for Power Quality Problems
1.7 Literature and Resource Material on Power Quality
1.8 Summary
1.9 Review Questions
2 Power Quality Standards and Monitoring
2.1 Introduction
2.2 State of the Art on Power Quality Standards and Monitoring
2.3 Power Quality Terminologies
2.4 Power Quality Definitions
2.5 Power Quality Standards
2.6 Power Quality Monitoring
2.7 Numerical Examples
2.8 Summary
2.9 Review Questions
2.10 Numerical Problems
2.11 Computer Simulation-Based Problems
3 Passive Shunt and Series Compensation
3.1 Introduction
3.2 State of the Art on Passive Shunt and Series Compensators
3.3 Classification of Passive Shunt and Series Compensators
3.4 Principle of Operation of Passive Shunt and Series Compensators
3.5 Analysis and Design of Passive Shunt Compensators
3.6 Modeling, Simulation, and Performance of Passive Shunt and Series Compensators
3.7 Numerical Examples
3.8 Summary
3.9 Review Questions
3.10 Numerical Problems
3.11 Computer Simulation-Based Problems
4 Active Shunt Compensation
4.1 Introduction
4.2 State of the Art on DSTATCOMs
4.3 Classification of DSTATCOMs
4.4 Principle of Operation and Control of DSTATCOMs
4.5 Analysis and Design of DSTATCOMs
4.6 Modeling, Simulation, and Performance of DSTATCOMs
4.7 Numerical Examples
4.8 Summary
4.9 Review Questions
4.10 Numerical Problems
4.11 Computer Simulation-Based Problems
5 Active Series Compensation
5.1 Introduction
5.2 State of the Art on Active Series Compensators
5.3 Classification of Active Series Compensators
5.4 Principle of Operation and Control of Active Series Compensators
5.5 Analysis and Design of Active Series Compensators
5.6 Modeling, Simulation, and Performance of Active Series Compensators
5.7 Numerical Examples
5.8 Summary
5.9 Review Questions
5.10 Numerical Problems
5.11 Computer Simulation-Based Problems
6 Unified Power Quality Compensators
6.1 Introduction
6.2 State of the Art on Unified Power Quality Compensators
6.3 Classification of Unified Power Quality Compensators
6.4 Principle of Operation and Control of Unified Power Quality Compensators
6.5 Analysis and Design of Unified Power Quality Compensators
6.6 Modeling, Simulation, and Performance of UPQCs
6.7 Numerical Examples
6.8 Summary
6.9 Review Questions
6.10 Numerical Problems
6.11 Computer Simulation-Based Problems
7 Loads That Cause Power Quality Problems
7.1 Introduction
7.2 State of the Art on Nonlinear Loads
7.3 Classification of Nonlinear Loads
7.4 Power Quality Problems Caused by Nonlinear Loads
7.5 Analysis of Nonlinear Loads
7.6 Modeling, Simulation and Performance of Nonlinear Loads
7.7 Numerical Examples
7.8 Summary
7.9 Review Questions
7.10 Numerical Problems
7.11 Computer Simulation-Based Problems
8 Passive Power Filters
8.1 Introduction
8.2 State of the Art on Passive Power Filters
8.3 Classification of Passive Filters
8.4 Principle of Operation of Passive Power Filters
8.5 Analysis and Design of Passive Power Filters
8.6 Modeling, Simulation, and Performance of Passive Power Filters
8.7 Limitations of Passive Filters
8.8 Parallel Resonance of Passive Filters with the Supply System and Its Mitigation
8.9 Numerical Examples
8.10 Summary
8.11 Review Questions
8.12 Numerical Problems
8.13 Computer Simulation-Based Problems
9 Shunt Active Power Filters
9.1 Introduction
9.2 State of the Art on Shunt Active Power Filters
9.3 Classification of Shunt Active Power Filters
9.4 Principle of Operation and Control of Shunt Active Power Filters
9.5 Analysis and Design of Shunt Active Power Filters
9.6 Modeling, Simulation, and Performance of Shunt Active Power Filters
9.7 Numerical Examples
9.8 Summary
9.9 Review Questions
9.10 Numerical Problems
9.11 Computer Simulation-Based Problems
10 Series Active Power Filters
10.1 Introduction
10.2 State of the Art on Series Active Power Filters
10.3 Classification of Series Active Power Filters
10.4 Principle of Operation and Control of Series Active Power Filters
10.5 Analysis and Design of Series Active Power Filters
10.6 Modeling, Simulation and Performance of Series Active Power Filters
10.7 Numerical Examples
10.8 Summary
10.9 Review Questions
10.10 Numerical Problems
10.11 Computer Simulation-Based Problems
11 Hybrid Power Filters
11.1 Introduction
11.2 State of the Art on Hybrid Power Filters
11.3 Classification of Hybrid Power Filters
11.4 Principle of Operation and Control of Hybrid Power Filters
11.5 Analysis and Design of Hybrid Power Filters
11.6 Modeling, Simulation and Performance of Hybrid Power Filters
11.7 Numerical Examples
11.8 Summary
11.9 Review Questions
11.10 Numerical Problems
11.11 Computer Simulation-Based Problems
References
Index