Ghosh / Ledwich Power Quality Enhancement Using Custom Power Devices

Content.- 1 Introduction.- 1.1 Electric Power Quality.- 1.2 Power Electronic Applications in Power Transmission Systems.- 1.3 Power Electronic Applications in Power Distribution Systems.- 1.4 Distributed Generation.- 1.5 References.- 2 Characterization of Electric Power Quality.- 2.1 Power Quality Terms and Definitions.- 2.2 Power Quality Problems.- 2.3 Conclusions.- 2.4 References.- 3 Analysis and Conventional Mitigation Methods.- 3.1 Analysis of Power Outages.- 3.2 Analysis of Unbalance.- 3.3 Analysis of Distortion.- 3.5 Analysis of Voltage Flicker.- 3.6 Reduced Duration and Customer Impact of Outages.- 3.7 Classical Load Balancing Problem.- 3.8 Harmonic Reduction.- 3.9 Voltage Sag or Dip Reduction.- 3.10 Conclusions.- 3.11 References.- 4 Custom Power Devices: An Introduction.- 4.1 Utility-Customer Interface.- 4.2 Introduction to Custom Power Devices.- 4.3 Custom Power Park.- 4.4 Status of Application of Cp Devices.- 4.5 Conclusions.- 4.6 References.- 5 Structure and Control of Power Converters.- 5.1 Inverter Topology.- 5.2 Hard-Switched Versus Soft-Switched.- 5.3 High Voltage Inverters.- 5.4 Combining Inverters for Increased Power and Voltage.- 5.5 Open-Loop Voltage Control.- 5.6 Closed-Loop Switching Control.- 5.7 Second and Higher Order Systems.- 5.8 Conclusions.- 5.9 References.- 6 Solid State Limiting, Breaking and Transferring Devices.- 6.1 Solid State Current Limiter.- 6.2 Solid State Breaker (SSB).- 6.3 Issues in Limiting and Switching Operations.- 6.4 Solid State Transfer Switch (SSTS).- 6.5 Sag/Swell Detection Algorithms.- 6.6 Conclusions.- 6.7 References.- 7 Load Compensation using DSTATCOM.- 7.1 Compensating Single-Phase Loads.- 7.2 Ideal Three-Phase Shunt Compensator Structure.- 7.3 Generating Reference Currents Using Instantaneous PQ Theory.- 7.4 Generating Reference Currents Using Instantaneous Symmetrical Components.- 7.5 General Algorithm for Generating Reference Currents.- 7.6 Generating Reference Currents When the Source Is Unbalanced.- 7.7 Conclusions.- 7.8 References.- 8 Realization and Control of DSTATCOM.- 8.1 DSTATCOM Structure.- 8.2 Control of DSTATCOM Connected To a Stiff Source.- 8.3 DSTATCOM Connected To Weak Supply Point.- 8.4 DSTATCOM Current Control through Phasors.- 8.5 DSTATCOM in Voltage Control Mode.- 8.6 Conclusions.- 8.7 References.- 9 Series Compensation of Power Distribution System.- 9.1 Rectifier Supported DVR.- 9.2 Dc Capacitor Supported DVR.- 9.3 DVR Structure.- 9.4 Voltage Restoration.- 9.5 Series Active Filter.- 9.6 Conclusions.- 9.7 References.- 10 Unified Power Quality Conditioner.- 10.1 UPQC Configurations.- 10.2 Right-Shunt UPQC Characteristics.- 10.3 Left-Shunt UPQC Characteristics.- 10.4 Structure and Control of Right-Shunt Upqc.- 10.5 Structure and Control of Left-Shunt UPQC.- 10.6 Conclusions.- 10.7 References.- 11 Distributed Generation and Grid Interconnection.- 11.1 Distributed Generation — Connection Requirements and Impacts on the Network.- 11.2 Interaction and Optimal Location of DG.- 11.3 Power Quality in DG.- 11.4 Islanding Issues.- 11.5 Distribution Line Compensation.- 11.6 Real Generation.- 11.7 Protection Issues for Distributed Generation.- 11.8 Technologies for Distributed Generation.- 11.9 Power Quality Impact from Different DG Types.- 11.10 Conclusions.- 11.11 References.- 12 Future Directions and Opportunities for Power Quality Enhancement.- 12.1 Power Quality Sensitivity.- 12.2 Utility Based Versus Customer Based Correction.- 12.3 Power Quality Contribution to the Network from Customer Owned Equipment.- 12.4 Interconnection Standards.- 12.5 Power QualityPerformance Requirements and Validation.- 12.6 Shape of Energy Delivery.- 12.7 Role of Compensators in Future Energy Delivery.- 12.8 Conclusions.- 12.9 References.