Uncertainties in Modern Power Systems

1st Edition - October 22, 2020
Imprint: Academic Press
Authors: Ahmed F. Zobaa, Shady Abdel Aleem
Language: English
Paperback ISBN:
9 7 8 - 0 - 1 2 - 8 2 0 4 9 1 - 7
eBook ISBN:
9 7 8 - 0 - 1 2 - 8 2 0 8 9 3 - 9

Uncertainties in Modern Power Systems combines several aspects of uncertainty management in power systems at the planning and operation stages within an integrated framework… Read more

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Uncertainties in Modern Power Systems combines several aspects of uncertainty management in power systems at the planning and operation stages within an integrated framework. This book provides the state-of-the-art in electric network planning, including time-scales, reliability, quality, optimal allocation of compensators and distributed generators, mathematical formulation, and search algorithms. The book introduces innovative research outcomes, programs, algorithms, and approaches that consolidate the present status and future opportunities and challenges of power systems. The book also offers a comprehensive description of the overall process in terms of understanding, creating, data gathering, and managing complex electrical engineering applications with uncertainties.

This reference is useful for researchers, engineers, and operators in power distribution systems.

Cover image
Title page
Table of Contents
Copyright
Contributors
Preface
Chapter 1. Overview of uncertainties in modern power systems: uncertainty models and methods
1. Introduction
2. Uncertainty models of parameters in power systems
3. Uncertainty modeling methods
4. Future trends
Chapter 2. Expansion planning of transmission networks
1. Introduction
2. Definition of uncertainties in the structure of modern power systems
3. Deterministic programing–based expansion planning of transmission networks
4. Stochastic programing–based expansion planning of transmission networks
5. Robust programming–based expansion planning of transmission networks
6. Hybrid robust/stochastic programming–based expansion planning of transmission networks
7. Conclusion
Chapter 3. A stochastic robust approach to deal with the generation and transmission expansion planning problem embedding renewable sources
1. Introduction
2. Mathematical uncertainty
3. Problem formulation
4. Solution approach
5. Study case
6. Conclusions
Chapter 4. Data-driven robust stochastic optimization for power systems operations
1. Uncertain optimization in the operation of modern power systems
2. RO-based distribution network reconfiguration
3. Data-driven ACOPF with wind power uncertainty
4. Wasserstein metric-based DRO for unit commitment problem
5. RSO model for dynamic economic dispatch problem
6. Conclusion
Chapter 5. Optimal power flow for distribution systems with uncertainty
1. Introduction
2. Distributed generator's benefits and uncertainty
3. Problem formulation
4. The uncertainties of load demand, solar, and wind power resources
5. Equilibrium optimizer
6. Simulation results
7. Conclusion
Chapter 6. Distributed demand-side management for microgrids in modern power system
1. Introduction
2. Distributed DR literature review
3. Distributed demand response in campus microgrids
4. Distributed demand response for microgrid-aided restoration
5. Case study
6. Summary
A. Section in appendix
Chapter 7. Evaluation of DG impacts on distribution networks
1. Introduction
2. Network losses
3. Voltage profile of the system
4. Reliability
Chapter 8. A comprehensive review of islanding detection methods
1. Introduction
2. International standards
3. Criteria to evaluate islanding detection methods
4. Islanding detection methods
5. Conclusions and future scope
Chapter 9. Protection system failure and power system blackout
1. Introduction
2. Performance evaluation of distance relay under power system disturbances
3. Performance of conventional techniques during system stressed conditions
4. Available solutions
5. Conclusion
Chapter 10. Testing of influence of SVC and energy storage device’s location on power system using GAMS
1. GAMS
2. SVC devices
3. Energy storage systems
4. Optimal location of SVC and ESS devices in a power network
Chapter 11. DG investment and allocation in active distribution networks
1. Introduction
2. Allocation of DGs in distribution networks
3. Modeling and simulation
4. Modifications in Newton–Raphson load flow
5. Average load demand and renewable generation pattern with uncertainty modeling
6. Objective functions with technical constraints
7. Mixed discrete particle swarm optimization
8. Uncertainty analysis with renewable generation and load
9. Annual cost–benefit analysis for DG placement
10. The methodology of DGs placement using the proposed method
11. Essential assumptions and parameters
12. Case study (33 bus RDNR)
13. Conclusions
Appendix
Chapter 12. Technical assessment of the impacts of distributed energy resources on distribution feeders
1. Introduction
2. Framework for impact assessment studies
3. A stochastic–probabilistic approach
4. Case studies
5. Conclusion
Chapter 13. Large-scale integration of distributed generation in reconfigured distribution networks considering load uncertainty
1. Introduction
2. Problem statement
3. Problem formulation
4. Simulation results and discussions
5. Conclusions
Chapter 14. Steady-state and time-varying harmonics in distribution system
1. Introduction
2. Harmonic data acquisition systems
3. Steady-state harmonic analysis
4. Design of harmonic analyzer
5. Time-varying harmonics analysis
6. Results and discussions
7. Estimation of time constant, time varying, and interharmonics
8. Mitigation of harmonics
9. Conclusions
Chapter 15. A case study with power quality analysis on building integrated PV (BIPV) system
1. Introduction to power quality issues
2. Solar photovoltaic as a renewable source of energy
3. Power quality standards
4. Voltage disturbances on electrical equipment
5. Guilty party for the power quality issues
6. Solar photovoltaic energy system incorporation
7. A case study on power quality analysis
8. Discussion of building integrated photovoltaic system issues of chosen building—Chennai automobile showroom
9. System and component description
10. Connected load for automobile showroom
11. Battery design consideration and sizing method
12. Procedure to estimate energy delivered by a photovoltaic panel
13. Example case
14. Conclusion
Chapter 16. Reliability evaluation of Li-ion batteries for electric vehicles applications from the thermal perspectives
1. Introduction
2. Electric vehicles trend
3. Effects of the temperature and control strategies on the reliability of the Li-ion batteries
4. Passive and active battery thermal management systems and their limitations
5. Case study: thermal management system and reliability assessment in Li-ion batteries
6. Conclusion
Chapter 17. Role of compensators' hybrid participation for isolated wind-driven electrical system in presence of input and load uncertainties
1. Introduction
2. Operational issues for wind-driven renewable energy system
3. Policy framework for wind-driven renewable energy–based system
4. Introduction to wind-diesel based isolated hybrid electrical system
5. Reactive power compensation issues in isolated hybrid electrical system
6. Reactive power compensation as techno-economic issues
7. Mathematical study of isolated hybrid electrical system
8. Challenges in load modeling
9. Modeling for composite loads
10. Effect of load and input uncertainties on system dynamics
11. Load and input uncertainties’ related findings for system
12. Modeling of load and input uncertainties for system
13. Role of compensators to mitigate the load and input disturbances
14. Importance of tuning methods for probabilistic load model
15. Investigations of hybrid compensation for economic benefits
16. Conclusion
Chapter 18. Bidding strategies of a power producer in power market: measurement indices and evaluation
1. Introduction
2. Problem formulation
3. Sinusoidal function–enabled chaotic grasshopper optimization algorithm
4. Sinusoidal function–enabled chaotic grasshopper optimization algorithm
5. Results analysis
6. Conclusion
Author Index
Subject Index

Ahmed F. Zobaa

Ahmed Faheem Zobaa received his B.Sc.(Hons), M.Sc. and Ph.D. degrees in electrical power and machines from Cairo University, Egypt. After being a senior lecturer in renewable energy at University of Exeter, U.K, he became associate professor and then Professor at Cairo University. Currently, he is a Senior Lecturer in power systems, an MSc course director and a full member of the Institute of Energy Futures at Brunel University London, U.K. His main areas of expertise are power quality, (marine) renewable energy, smart grids, energy efficiency, and lighting applications. Dr. Zobaa is involved in the editorial activities of many international journals, including as editor-in-chief, editor and associate editor. He is a registered Chartered Engineer, Chartered Energy Engineer, European Engineer, and International Professional Engineer. He is also a registered member of the Engineering Council U.K., Egypt Syndicate of Engineers, and the Egyptian Society of Engineers. He is a senior fellow of the Higher Education Academy of U.K. He is a fellow of the Institution of Engineering and Technology, the Energy Institute of U.K., the Chartered Institution of Building Services Engineers, the Royal Society of Arts, the African Academy of Science, and the Chartered Institute of Educational Assessors. He is a senior member of the Institute of Electrical and Electronics Engineers. Also, He is a member of the International Solar Energy Society, the European Power Electronics and Drives Association, and the IEEE Standards Association.

Affiliations and expertise

College of Engineering, Design and Physical Sciences, Brunel University London, Uxbridge, UK

Shady Abdel Aleem

Shady Hossam Eldeen Abdel Aleem (MIEEE'12) and (MIET'16) received the B.Sc. and M.Sc. and Ph.D. degrees in Electrical Power and Machines from the Faculty of Engineering, Helwan University, Helwan, Egypt, in 2002, and the Faculty of Engineering, Cairo University, Egypt, in 2009 and 2013 respectively. Currently, he is an Associate Professor at 15th of May Higher Institute of Engineering. He is working in the field of electric machines, power quality, electric circuits, and renewable energy systems.

Affiliations and expertise

Mathematical, Physical and Engineering Sciences Department, 15th of May Higher Institute of Engineering, Cairo, Egypt

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