Advanced Frequency Regulation Strategies in Renewable-Dominated Power Systems

1st Edition - September 1, 2023
Editors: Sandeep Dhundhara, Yogendra Arya, Ramesh C. Bansal
Language: English
Paperback ISBN:
9 7 8 - 0 - 3 2 3 - 9 5 0 5 4 - 1
eBook ISBN:
9 7 8 - 0 - 3 2 3 - 9 5 0 5 5 - 8

Advanced Frequency Regulation Strategies in Renewable-Dominated Modern Power Systems discusses advanced control strategies positioned to attain stable and reliable electric power… Read more

Advanced Frequency Regulation Strategies in Renewable-Dominated Power Systems

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Advanced Frequency Regulation Strategies in Renewable-Dominated Modern Power Systems discusses advanced control strategies positioned to attain stable and reliable electric power operation in highly renewable modern grids. These strategies are increasingly valuable components of the practitioner technical toolbox, and are essential to maintain frequency and voltage regulations, assert power quality standards, and ensure overall grid stability. This book focuses on the rapid integration of renewable-based generating units in power systems, highlighting state-of-the-art technologies and emerging topics pertaining to load frequency control, robust control strategies, and energy storage systems. Chapters are accompanied by case studies drawn from modern international practice.

Cover image
Title page
Table of Contents
Copyright
Contributors
Preface
Chapter 1: Overview of the renewable-dominated power systems and their frequency regulation issues
Abstract
1.1: Introduction
1.2: Characteristics of RESs integration in PSs
1.3: Frequency regulation issues due to the integration of RES in PSs
1.4: Role of flexible AC transmission systems for RES integration
1.5: Robust controllers for frequency regulation issue
1.6: Future prospects of renewable-dominated power systems
1.7: Conclusion
References
Chapter 2: Impacts of high renewable energy penetration on power system flexibility and strategies for frequency control
Abstract
2.1: Introduction
2.2: Effects of growing renewable penetration on power system
2.3: Flexibility provision
2.4: Conclusion
References
Further reading
Chapter 3: Effective frequency control in renewable dominated power systems
Abstract
3.1: Introduction
3.2: Effect of inertia on frequency stability
3.3: Frequency criteria based on grid codes
3.4: Participation of renewable energy sources in frequency control
3.5: Modeling of RESs for frequency control
3.6: Conventional generation with steam turbines and hydroturbines
3.7: Application of metaheuristic optimization on frequency control
3.8: Case study for two-area power system
3.9: Conclusions and future prospective
Appendix
References
Chapter 4: Nonlinear resilient frequency controller for hybrid power system
Abstract
4.1: Introduction
4.2: Small-signal stability modeling and control methodology
4.3: Optimization technique
4.4: Kharitonov's theorem
4.5: Results and discussion
4.6: Conclusion
Appendix 1: State-space modeling
Appendix 2: Applied optimization and WDG system's input parameters
Appendix 3
References
Chapter 5: Design of an I + Fuzzy based PD control strategy for damping power system oscillations in a networked environment integrated with renewable energy sources
Abstract
5.1: Introduction
5.2: Load frequency control: An important aspect of power system
5.3: Description of I + Fuzzy based PD controller structure
5.4: Application of metaheuristic optimization algorithms in the backdrop of LFC
5.5: Case studies
5.6: Summary
5.7: Future scope
Appendix: System parameter values
References
Chapter 6: Utilization of solid oxide fuel cell in amalgamated frequency-voltage control of RES-based restructured power systems
Abstract
6.1: Introduction
6.2: System investigations
6.3: TIDN-FOID controller
6.4: Structure investigation with SHO
6.5: Results and assessment
6.6: Conclusion
Appendix
References
Chapter 7: Price-based frequency regulation strategies in renewable-dominated power systems
Abstract
7.1: Introduction to price-based frequency regulation strategies in the Indian electricity market
7.2: Review of price-based frequency regulation strategies in modern electricity market
7.3: Various control strategies for effective control under price-based frequency regulation scenario
7.4: Issues and technical challenges in renewable integrated modern power system operation and control under price-based scenario
7.5: The proposed control scheme
7.6: Test system
7.7: Results and discussion
7.8: Conclusions
7.9: Future scope
Appendix
References
Chapter 8: Provision of kinetic energy support from wind turbines for frequency regulation services in the modern grid
Abstract
8.1: Introduction
8.2: Grid integration and wind energy production in India and the world
8.3: Integrating large-scale wind energy into the electrical system
8.4: The significance of variable speed variable pitch wind turbines to frequency regulation and enhanced load-frequency control
8.5: Power quality issues and difficulties with the expanded entrance of wind energy to the grid
8.6: Up-to-date methods for resolving frequency control challenges brought on by wind generation in contemporary power networks
8.7: Conclusions and future scope
References
Chapter 9: Robust frequency regulation against cyberattack uncertainties in modern power system grids
Abstract
9.1: Introduction
9.2: Modern power system grid structure
9.3: Cyberattack uncertainty representation
9.4: Proposed control scheme
9.5: Simulations and demonstrations
9.6: Conclusions
References
Chapter 10: Transient performance study in a rural microgrid: Influence of various energy storage options
Abstract
10.1: Introduction
10.2: Rural microgrid configuration
10.3: Rural microgrid control techniques
10.4: Simulation results and discussions
10.5: Conclusion
References
Chapter 11: Frequency control of hybrid autonomous microgrids comprising electric vehicles aggregator based on lightning attachment procedure optimizer
Abstract
11.1: Introduction
11.2: Modeling of HAMGS under study
11.3: Lightning attachment procedure optimization
11.4: Mathematical formulations of objectives and constraints
11.5: Simulation results and discussions
11.6: Conclusions and future prospects
Appendix 11.A
References
Chapter 12: Demand side energy management algorithms integrated with the IoT framework in the PV smart grid system
Abstract
12.1: Introduction
12.2: Demand response
12.3: DSM techniques and strategies
12.4: DSM implementation problems
12.5: Progress in DSM optimization models and algorithms applications
12.6: Benefits of DR
12.7: Challenges in DR implementation
12.8: Practical examples of DSM application in India and abroad
12.9: PV technologies for active demand side management
12.10: Case studies showing the impact of DSM on frequency regulation in modern power systems
12.11: Conclusion
References
Further reading
Chapter 13: Design of self-healing techniques and strategies for smart microgrids
Abstract
13.1: Introduction
13.2: Modeling of microgrid with different renewables and energy storages
13.3: Challenges of accurate modeling of MGs on frequency and dynamic analysis
13.4: Formulation of adapted FF and associated constraints
13.5: Intelligent control techniques
13.6: Case studies and numerical examples
13.7: State-of-art of self-healing strategies
13.8: Conclusions and future prospective
References
Chapter 14: Impacts of FACTS controllers in frequency regulation services of modern restructured power system
Abstract
14.1: Introduction
14.2: Mathematical modeling of multiarea power system
14.3: Introduction to facts controllers
14.4: Mathematical model of various facts controllers
14.5: Harris Hawks optimization
14.6: Results and validation
14.7: Conclusion
14.8: Future prospective
Appendix 1
Appendix 2
References
Chapter 15: A novel intelligent distributed model predictive control scheme for load frequency control of a multimicrogrid system incorporating electric vehicles
Abstract
15.1: Introduction
15.2: Dynamic modeling of the MMG system
15.3: Model predictive control scheme
15.4: Optimization algorithm
15.5: Discussion of the simulation results and their analysis
15.6: Conclusion
References
Chapter 16: Frequency regulation strategies in renewable energy-dominated power systems: Issues, challenges, innovations, and future trends
Abstract
16.1: Introduction of LFC strategies in modern power systems
16.2: Literature review of LFC schemes
16.3: Advanced strategies for frequency regulation
16.4: Advancements and innovations in LFC
16.5: Conclusions and future trends
References
Index

Sandeep Dhundhara

Sandeep Dhundhara is an Assistant Professor (Electrical Engineering) in the Department of Basic Engineering, College of Agricultural Engineering and Technology, CCS Haryana Agricultural University, Hisar, Haryana, India. He completed his Ph.D. in Electrical Engineering from Panjab University Chandigarh, India. He has been a visiting Research Fellow at the Department of Electrical and Electronics Engg., University of Nottingham, Nottingham, United Kingdom (2017-2018). He has a total of 8 years of teaching and research experience in Electrical Engineering. His areas of interest are power system controls and stability, AGC, and electrical energy storage systems. He has published several papers in various international journals and conferences. He is a member of IEEE, UACEE, and INAEG.

Affiliations and expertise

Department of Basic Engineering, COAE&T, CCS Haryana Agricultural University, Hisar, Haryana, India

Yogendra Arya

Yogendra Arya did his A.M.I.E. in Electrical Engineering from The Institution of Engineers (India), in 2008, his M. Tech. in Electrical Engineering (I&C) from Deenbandhu Chhotu Ram University of Science & Technology, Sonepat, Haryana, in 2010, and his Ph.D. in Electrical Engineering from Delhi Technological University, Delhi, India, in 2018. He is currently working as an Associate Professor with the Department of Electrical Engineering, J.C. Bose University of Science and Technology, YMCA, Faridabad, India. He has published 50 research papers in accredited journals and conferences. He has published a total of 30 SCIE research papers in reputed international journals, out of which 13 are written as sole authors. He has received the “MSIT Best Faculty Award” in 2018 and the “MSIT Certificate of Excellence in Research” in 2018 and 2019. He has been placed among “Top 2% of Researchers in the World” for 2019 by Stanford University, USA.

Affiliations and expertise

Department of Electrical Engineering, J.C. Bose University of Science and Technology, YMCA, Faridabad, India

Ramesh C. Bansal

Ramesh C. Bansal is a Professor at University of Sharjah and Extraordinary Professor at University of Pretoria. He has over 25 years of teaching and research experience, and previously worked at University of Pretoria, University of Queensland, University of South Pacific, and BITS, Pilani. He has published over 400 journal/conf. papers, books/book chapters, and is he AE/Editor of many reputed journals. He has Google citations of over 16000 and h-index of 60. He has supervised 25 PhD, 5 Post Docs. He is a Fellow of IET-UK, IE (India), SAIEE (South Africa).

Affiliations and expertise

Professor, University of Sharjah, United Arab Emirates

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