Distributed Optimal Control of Large-Scale Wind Farm Clusters: Optimal Active and Reactive Power Control, and Fault Ride Through: Wind Energy Engineering
Autor Qiuwei Wu, Sheng Huang, Juan Wei, Pengda Wang, Canbing Li, Vladimir Terzijaen Limba Engleză Paperback – mar 2025
Researchers, faculty, scientists, engineers, R&D, and other industry professionals, as well as graduate and postgraduate students studying and working in wind energy will find this comprehensive resource a valuable addition to their work.
- Presents the latest developments in the distributed optimal control of large-scale wind power plant clusters
- Covers both active and reactive power control, as well as techniques for high voltage ride through (HVRT)
- Provides methodologies to follow set-points from system operators in order to maintain expected voltages
- Includes control algorithms and codes for implementing the control schemes
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Specificații
ISBN-13: 9780443292347
ISBN-10: 0443292345
Pagini: 400
Dimensiuni: 152 x 229 mm
Editura: ELSEVIER SCIENCE
Seria Wind Energy Engineering
ISBN-10: 0443292345
Pagini: 400
Dimensiuni: 152 x 229 mm
Editura: ELSEVIER SCIENCE
Seria Wind Energy Engineering
Cuprins
Section I - Introduction
1. Introduction to Large-Scale Wind Power Integration
Section II - Optimal Active Power Control of Large-Scale Wind Farm Clusters
2. Bi-Level Decentralized Active Power Control for Large-Scale Wind Farm Clusters
3. Optimal Active Power Control Based on MPC for DFIG-based Wind Farm Equipped with Distributed Energy Storage Systems
4. Hierarchical Active Power Control of DFIG-based Wind Farm with Distributed Energy Storage Systems based on Alternating Direction Method of Multipliers (ADMM)
5 Hierarchical Optimal Control for Synthetic Inertial Response of Wind Farm Based on Alternating Direction Method of Multipliers (ADMM)
Section III - Optimal Active and Reactive Power Control of Large-Scale Wind Farm Clusters
6. Bi-Level Decentralized Active and Reactive Power Control for Large-Scale Wind Farm Cluster
7. Two-Tier Combined Active and Reactive Power Control for VSC–HVDC Connected Large-Scale Wind Farm Cluster based on Alternating Direction Method of Multipliers (ADMM)
8. Distributed Optimal Active and Reactive Power Control for Wind Farms Based on ADMM
9. ADMM-based Distributed Active and Reactive Power Control for Regional AC Grids with Wind Farms
Section IV - Optimal Voltage Control of Large-Scale Wind Farm Clusters
10. Distributed Voltage Control based on ADMM for Large Scale Wind Farm Cluster connected to VSC HVDC
11. Distributed Optimal Voltage Control for VSC-HVDC Connected Large-Scale Wind Farm Cluster Based on Analytical Target Cascading Method
12. Adaptive Droop-based Hierarchical Optimal Voltage Control Scheme for VSC-HVDC Connected Offshore Wind Farm
13. Distributed Optimal Voltage Control Strategy for AC Grid with DC Connection and Offshore Wind Farms Based on Alternating Direction Method of Multipliers (ADMM)
Section V - Fault Ride Through of Wind Farm Clusters
14. Coordinated Droop Control and Adaptive Model Predictive Control for Enhancing HVRT and Post-Event Recovery of Large-Scale Wind Farms
15. Hierarchical Event-Triggered MPC-Based Coordinated Control for HVRT and Voltage Restoration of Large-Scale Wind Farms
16. Coordinated Voltage Support Control for Enhancing LVRT Capability of Large-Scale Wind Farms
1. Introduction to Large-Scale Wind Power Integration
Section II - Optimal Active Power Control of Large-Scale Wind Farm Clusters
2. Bi-Level Decentralized Active Power Control for Large-Scale Wind Farm Clusters
3. Optimal Active Power Control Based on MPC for DFIG-based Wind Farm Equipped with Distributed Energy Storage Systems
4. Hierarchical Active Power Control of DFIG-based Wind Farm with Distributed Energy Storage Systems based on Alternating Direction Method of Multipliers (ADMM)
5 Hierarchical Optimal Control for Synthetic Inertial Response of Wind Farm Based on Alternating Direction Method of Multipliers (ADMM)
Section III - Optimal Active and Reactive Power Control of Large-Scale Wind Farm Clusters
6. Bi-Level Decentralized Active and Reactive Power Control for Large-Scale Wind Farm Cluster
7. Two-Tier Combined Active and Reactive Power Control for VSC–HVDC Connected Large-Scale Wind Farm Cluster based on Alternating Direction Method of Multipliers (ADMM)
8. Distributed Optimal Active and Reactive Power Control for Wind Farms Based on ADMM
9. ADMM-based Distributed Active and Reactive Power Control for Regional AC Grids with Wind Farms
Section IV - Optimal Voltage Control of Large-Scale Wind Farm Clusters
10. Distributed Voltage Control based on ADMM for Large Scale Wind Farm Cluster connected to VSC HVDC
11. Distributed Optimal Voltage Control for VSC-HVDC Connected Large-Scale Wind Farm Cluster Based on Analytical Target Cascading Method
12. Adaptive Droop-based Hierarchical Optimal Voltage Control Scheme for VSC-HVDC Connected Offshore Wind Farm
13. Distributed Optimal Voltage Control Strategy for AC Grid with DC Connection and Offshore Wind Farms Based on Alternating Direction Method of Multipliers (ADMM)
Section V - Fault Ride Through of Wind Farm Clusters
14. Coordinated Droop Control and Adaptive Model Predictive Control for Enhancing HVRT and Post-Event Recovery of Large-Scale Wind Farms
15. Hierarchical Event-Triggered MPC-Based Coordinated Control for HVRT and Voltage Restoration of Large-Scale Wind Farms
16. Coordinated Voltage Support Control for Enhancing LVRT Capability of Large-Scale Wind Farms