Power Systems Operation with 100% Renewable Energy Sources combines concepts of renewable energy integration into power systems with real-world case studies to bridge the gap between theory and implementation. The book examines the challenges and solutions for renewable energy integration into the transmission and distribution grids, and also provides information on design, analysis, and operation. Starting with an introduction to renewable energy sources and bulk power systems, including policies and frameworks for grid upgradation, the book then provides forecasting, modeling and analysis techniques for renewable energy sources. Subsequent chapters discuss grid code requirements and compliance, before presenting a detailed breakdown of solar and wind integration into power systems. Other topics such as voltage control and optimization, power quality enhancement, and stability control are also considered. Filled with case studies, applications and techniques, this book is a valuable read to researchers, students and engineers working towards more sustainable power systems.
1. Introduction to renewable energy sources and bulk power system
2. Overview of various renewable energy sources - hybrid systems
introduction to power systems power system devices and components
3. Framework and policies for achieving 100% renewables into the bulk power
system
4. Introduction the need for 100% renewables policies and framework
grid up-gradation to achieve 100% renewables
5. Forecasting of renewable energy sources
6. Introduction forecasting solar PV systems forecasting wind energy
conversion system tools required
7. Modeling and analysis of renewable energy sources
8. Introduction modeling and analysis of solar PV systems modeling and
analysis of wind energy conversion system - power and energy management
case studies
9. Power electronics interface for renewable energy integration into power
systems
10. Introduction Different types of power electronic interface Power
electronics for solar PV systems Power electronics for wind energy
conversion system case studies
11. Grid code requirements and compliance
12. Introduction to various grid codes technical requirements: voltage,
frequency, power quality, protection, active and reactive power, frequency
control Integration study example in PSSE, Digsilent Power factory and
PSCAD
13. Solar PV integration into bulk power systems
14. Power outputs technical challenges of integrating into distribution
grid technical challenges of integrating into transmission grid technical
solutions simulation examples
15. Wind integration into bulk power systems
16. Power outputs technical challenges of On-shore wind plant integrating
into distribution grid technical challenges of On-shore wind plant
integrating into transmission grid technical challenges of Off-shore wind
plant integrating into transmission grid - technical solutions simulation
examples
17. Renewable energy integration into the weak grid system and its
challenges
18. Introduction technical challenges techno-economic solution
simulation examples
19. Volt/Var control and optimization
20. Introduction Volt/Var control and optimization for distribution grid -
Volt/Var control and optimization for transmission grid - techno-economic
solution case studies
21. Reactive power management
22. Introduction location of reactive of compensation device reactive
power compensation device rating and its optimization techno-economic
solution capacitor banks, reactor banks, STATCOMs, synchronous condensers
23. Power quality enhancement
24. Introduction Power quality: voltage and current harmonics, voltage
fluctuation and rapid voltage change, DC injection harmonic filters
SATCOMs, SVC, UPFC techno-economic solution - examples
25. Stability control and enhancement
26. Introduction stability control and assessments stability enhancement
techno-economic solution - examples
27. Energy Storage Systems for bulk power systems
28. Introduction The need for energy storage system energy storage system
for transmission system distributed energy storage systems ancillary
services location of energy storage system case studies
29. Electric vehicle charging, demand Response and its impact on bulk power
systems
30. Introduction types of electric vehicle charging, impact of renewable
energy powered fast charging station operating characteristics on primary and
secondary distribution system, supply vs. demand - demand response power
and energy management case studies
Sanjeevikumar Padmanaban is a Full Professor in Electrical Power Engineering with the Department of Electrical Engineering, Information Technology, and Cybernetics of the University of South-Eastern Norway, Norway. He has over a decade of academic and teaching experience, including Associate/Assistant Professorships at the University of Johannesburg, South Africa (2016-2018), Aalborg University, Denmark (2018-2021) and the CTIF Global Capsule Laboratory at Aarhus University, Denmark (2021-present). Prof. Padmanaban received a lifetime achievement award from Marquis Whos Who - USA 2017 for contributing to power electronics and renewable energy research, and was listed among the worlds top 2% of scientists by Stanford University, USA in 2019. Prof. C. Sharmeela is a Professor in the Department of Electrical and Electronics Engineering, CEG Campus, Anna University, India. She completed her PhD in Electrical Engineering at Anna University in 2009, and a PG Diploma in Electrical Energy Management and Energy Audit at Annamalai University in 2010. Dr. Sharmeela has 20 years of teaching experience, teaching various subjects to undergraduate and postgraduate students, and has completed several research projects and consultancy work in renewable energy, power quality, and design of PQ compensators for various industries. She is a senior member of the IEEE, and a life member of CBIP, the Institution of Engineers (India), ISTE, and SSI. She has published over 30 research publications in peer-reviewed journals and 50 papers at international and national conferences. Mr. P. Sivaraman is currently working as a Program Manager at WRI India. He completed his B.E. in Electrical and Electronics Engineering and M.E. in Power Systems Engineering at Anna University, India in 2012 and 2014 respectively, and has over 7 years of industrial experience in the field of power system analysis, renewable energy integration, solar photovoltaic systems, wind power plants, power quality studies, and harmonic assessments, troubleshooting for various power quality problems, microgrid design, providing techno-economical solutions to various power quality problems for industries across India. He has trained more than 500 personnel on renewable energy and power quality, carried out power quality assessments for over 300 sites all over India, and has validated over 200 power quality reports. He is an active participant in the IEEE standards association, as a member of numerous working groups, and is a senior member of the Institute of Electrical and Electronics Engineers (IEEE), member of the International Council on Large Electric Systems (CIGRE), Life Member of the Institution of Engineers (India), and member of the European Energy Center (EEC). He received his Professional Engineer (PEng) certification from the Institution of Engineers India. Mr. Sivaraman has authored, co-authored or edited 6 books and published several papers at national and international conferences.
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