Design and Control of Active Power Filters towards the Decarbonisation of Smart Grid Networks
Coordonnateurs : Khadem Shafi, Basu Malabika, Komurcugil Hasan
Design and Control of Active Power Filters towards the Decarbonisation of Smart Grid Networks helps readers optimize grid stability and power quality using active power filters in transitioning decarbonized power systems moving from high voltage to low voltage distributed smart networks. The work opens with an extensive foundation in in grid stability and power quality optimization, but then goes on to discuss advanced design, control, integration and placement considerations for APFs for smart grids with high penetration of VRE and EV. Integration topologies and the placement of APFs in these VRE integrated networks are also discussed.
Finally, applied solutions on design, control and integration of APFs in microgrid networks are presented before parallel operation and distributed design and control issues are reviewed. Numerous case studies support the work, and a expansive discussion of future trends for APFs in smart grids rounds out the content.
Section I: Grid stability and power quality in smart grid network with high penetration of VRE 1. Grid stability and power quality in VRE integrated networks 2. Application of latest device/equipment in stabilising the smart grid with ancillary services
Section II: Design, Control and Integration of APFs with high penetration of VRE 3. Basics of APFs – Design, topology and control 4. Integration/placement of APFs in distributed generation network 5. Advanced design and dynamic control strategies of APFs in different smart grid networks 6. Parallel operation and control of APFs in presence of VRE 7. Design and control of multi-level/multi-modular APFs
Section III: Integration of APFs in Microgrid networks 8. Integration, placement and control of APFs in microgrid networks 9. Multi-functional APFs for grid stability and power quality improvement 10. Real life demonstration examples
Section IV: Future Trends of APFs 11. Placement of APFs and participation in ancillary market 12. Advancement in energy management and control
Malabika Basu received the B.E. and M.E. degrees from the Bengal Engineering College, Shibpur, India, in 1995 and 1997, respectively, and the Ph.D. degree from the Indian Institute of Technology Kanpur, India, in 2003, all in electrical engineering. From 2001 to 2003, she was a Lecturer with Jadavpur University, Kolkata, India. From 2003 to 2006, she was an Arnold F. Graves Postdoctoral Fellow with Dublin Institute of Technology, Ireland, and worked as a Lecturer since 2006. She is currently a senior lecturer in the Technological University Dublin. She has authored or co-authored more than 100 technical publications in various international journals and conference proceedings. Her current research interests include grid integration of renewable energy sources, power quality and conditioners, photovoltaics and wind energy conversion, HVDC systems, smart grid, and microgrids. Currently she also serves as one of the associate editors of IEEE Access for Power
- Explores advanced design and dynamic control strategies of active power filters (APFs) in different smart grid networks in the presence of highly penetrated variable renewable energies (VRE) and Electric Vehicles (EV)
- Reviews the design and control of Multi-functional/Multi-level/Multi-modular/Parallel operation of APFs for grid stability and power quality improvement in LV/MV/HV networks
- Assesses different integration and placement methods of APFs in grid connected or off-grid microgrid networks
- Discusses real life demonstration examples of APFs, network analysis and loss minimization, techno-economic analysis, business case scenarios
- Presented detailed simulation models and implementations in MATLAB
Date de parution : 06-2024
Ouvrage de 316 p.
15.2x22.8 cm
Thème de Design and Control of Active Power Filters towards the... :
Mots-clés :
Power Quality; Active Power Filters; Unified Power Quality Conditioner; Dynamic Control; Smart Grid Networks; UPQC; Grid Stability; Harmonics; Distorted Grid; Weak Grid; Microgrids; Isolated Systems; battery energy storage system (BESS); multifunctional converter; parallel systems; multi-level topologies; Variable Renewable Energy