Custom Power Devices for Efficient Distributed Energy Systems
- 1st Edition - May 23, 2024
- Imprint: Elsevier
- Editors: Ahmed Al-Durra, Sabha Raj Arya, Ashutosh K. Giri
- Language: English
- Paperback ISBN:9 7 8 - 0 - 4 4 3 - 2 1 4 9 1 - 2
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 2 1 5 0 1 - 8
Custom Power Devices for Efficient Distributed Energy Systems presents a range of novel ideas and concepts based on renewable energy-fed power generation and control, offering… Read more
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Request a sales quoteCustom Power Devices for Efficient Distributed Energy Systems presents a range of novel ideas and concepts based on renewable energy-fed power generation and control, offering avenues to efficient utilization and improved power quality and addressing power quality issues such as harmonics compensation, supply current balancing, and neutral current compensation. The book begins by introducing distributed power systems within the global renewable energy context, reviewing different types of renewable energy sources and distributed power generation systems, and detailing custom power device design and modeling.
This is followed by individual chapters, providing in-depth coverage of specific techniques and applications with insights into various topologies, as well as control algorithms, used for power control in a range of distributed energy conversion systems, such as solar, wind, hydro, and other power sources. Finally, power quality issues in renewable energy distributed generation are discussed and addressed in detail. This is a valuable resource for researchers, faculty, and advanced students with an interest in power generation systems, renewable energy, and power systems engineering, as well as practicing engineers, R&D professionals, managers, and other industry personnel in the renewable energy sector.
- Covers established as well as advanced control algorithms for the operation of custom power devices
- Extensively explains circuit design and its testing for solar and wind-based energy conversion systems
- Includes simulation results and mathematical modeling of control algorithms
- Presents applications of converter topologies in solar, wind, hydro, and other power generation systems
Academia: Advanced students, researchers, and faculty, with an interest in power generation systems, renewable energy, power systems engineering, and grid integration. Industry: Practicing engineers, R&D professionals, managers, and other industry personnel in the renewable energy sector
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- Chapter One. Introduction of custom power devices
- 1.1. General
- 1.2. The DSTATCOM development and application in distributed power system: An overview
- 1.3. State of art
- 1.4. Scope of work on DSTATCOM
- 1.5. Adaptive control algorithms
- 1.6. Application of DSTATCOM in distributed power generation
- 1.7. Power quality issues in distributed power generation system
- Chapter Two. DSTATCOM components modeling and control
- 2.1. General
- 2.2. Application of DSTATCOM in distributed generation
- 2.3. Operating principle of DSTATCOM
- 2.4. Configuration of DSTATCOM
- 2.5. Design calculation of DSTATCOM equipment
- 2.6. Control algorithm for DSTATCOM
- 2.7. Summary
- Chapter Three. Custom power device designing and modeling
- 3.1. Introduction
- 3.2. EAF distribution network simulation
- 3.3. Basic compensation principle
- 3.4. Design of reference voltage and control scheme
- 3.5. Series APF simulation
- 3.6. Performance evaluation of composite filter
- 3.7. State-space modeling
- 3.8. Summary
- Chapter Four. Design and development of PV-DVR system for solar photovoltaic energy harvesting and voltage power quality improvement
- 4.1. Introduction to PV-DVR system
- 4.2. System configuration of PV-DVR
- 4.3. Design of the PV-DVR systems parameters
- 4.4. Control strategy of PV-DVR system
- 4.5. Simulation of the PV-DVR system
- 4.6. Hardware setup details
- 4.7. Control of the PV-DVR system using generic 32-bit ARM Cortex-M4 microcontroller STM32F407VG
- 4.8. Experimentation results and discussion
- 4.9. Summary and conclusion
- Chapter Five. Design, modeling, and hardware development of coupled inductor-based high step-up gain DC–DC converter for photovoltaic source integration
- 5.1. Introduction
- 5.2. Basic coupled inductor boost converter
- 5.3. Two-phase interleaved coupled inductor boost converter
- 5.4. Design consideration for basic CIBC and two-phase interleaved CIBC
- 5.5. Small signal model results analysis and controller design
- 5.6. Simulation results
- 5.7. Hardware setup details and experimental results
- 5.8. Summary and conclusion
- Chapter Six. Development of control scheme for grid-tied PV system to enhance power quality
- 6.1. Introduction
- 6.2. Description of PV module and its characteristics
- 6.3. Configurations of PV energy conversion systems
- 6.4. Grid-tied PV systems
- 6.5. Requirements of a control scheme for GTPVS
- 6.6. System configuration of a single-stage GTPVS
- 6.7. Development of VSSHQCAF control scheme for GTPVS
- 6.8. MATLAB/Simulink results and discussion
- 6.9. Conclusion
- Chapter Seven. Superior power conversion efficiency of novel solar cell and multi-response optimization of spray coated SnO2 thin films
- 7.1. Introduction
- 7.2. Experimental section
- 7.3. Result and discussion
- 7.4. Conclusions
- Chapter Eight. Compositional engineering and additive engineering for enhanced performance of hybrid solar cells
- 8.1. Introduction
- 8.2. Generations of solar cells
- 8.3. Mix cationic perovskite and its enhanced efficiency and stability
- 8.4. Materials and methodology
- 8.5. Results and discussion
- 8.6. Conclusions
- Chapter Nine. Electric vehicles charging using renewable distributed generation
- 9.1. Introduction
- 9.2. Overview of battery charging using PV technology for EV
- 9.3. Power electronic converters for EV charging
- 9.4. Prospects of V2H, V2G and V2V
- 9.5. Power quality issues using electric vehicles
- 9.6. Contribution of EVs in improvement of power quality in the smart grids
- Chapter Ten. Power quality issue in renewable distributed generation
- 10.1. Introduction
- 10.2. The current state of the electrical distributed energy resource and their topology
- 10.3. Various types of challenges and technological innovations are involved in the development of power quality
- 10.4. Conclusion
- Index
- Edition: 1
- Published: May 23, 2024
- No. of pages (Paperback): 312
- No. of pages (eBook): 300
- Imprint: Elsevier
- Language: English
- Paperback ISBN: 9780443214912
- eBook ISBN: 9780443215018
AA
Ahmed Al-Durra
Prof. Ahmed Al-Durra received his BSc, MSc, and PhD in Electrical & Computer Engineering from Ohio State University, with Summa Cum laude in all three degrees, and joined the Electrical Engineering Department of the Petroleum Institute (PI), UAE, as an Assistant Professor in 2010, before being promoted to Associate Professor in 2015. Since 2020, he is a Professor at the Electrical Engineering and Computer Science Department, Khalifa University, UAE, where he is also now the Associate Provost for Research. His research interests are in applications of control and estimation theory on power system stability, micro and smart grids, renewable energy systems and integration, and process control. Prof. Al-Durra has worked on several international and national research projects, and is the head of the Energy Systems, Control and Optimization Lab at ADRIC as well as the Industry Engagement Theme lead for the Advanced Power and Energy Center. He has one US patent, one edited book, 12 book chapters, and over 250 scientific articles in top-tier journals and refereed international conference proceedings. He is involved in various journal editorial boards and has received numerous awards.
Affiliations and expertise
Professor, Electrical Engineering and Computer Science Department, Khalifa University, Abu DhabiSR
Sabha Raj Arya
Dr. Sabha Raj Arya received his Bachelor of Engineering degree in Electrical Engineering from Government Engineering College Jabalpur, Master of Technology in Power Electronics from Motilal National Institute of Technology, Allahabad, and Ph.D. degree in Electrical Engineering from Indian Institute of Technology (IIT) Delhi, in 2014. He became Assistant Professor in the Department of Electrical Engineering, Sardar Vallabhbhai National Institute of Technology, Surat, India, and was promoted to Associate Professor at the same institute in 2019. His fields of interest include power electronics, power quality, design of power filters, and distributed power generation. Dr. Arya has published over 100 research papers in journals and at conferences in the field of electrical power quality. He also serves as an Associate Editor for the IET Renewable Power Generation.
Affiliations and expertise
Associate Professor, Department of Electrical Engineering, Sardar Vallabhbhai National Institute of Technology, IndiaAK
Ashutosh K. Giri
Dr. Ashutosh K. Giri received his Bachelor of Engineering in Electrical Engineering at G. B. Pant University of Agriculture and Technology, India, M.E in Electrical Engineering with specialization in Power Systems from the L.D. College of Engineering, Ahmedabad, and PhD from Sardar Vallabh National Institute of Technology. He is an Assistant Professor at the Department of Electrical Engineering, Government Engineering College, Bharuch, since 2011. Dr. Giri has authored or co-authored more than 40 research papers in reputed journals, co-authored one book chapter, and co-edited two books. He has delivered over 25 national and international level talks at various reputed universities across India and acts as a reviewer for several journals.
Affiliations and expertise
Assistant Professor, Electrical Engineering Department, Government Engineering College, IndiaRead Custom Power Devices for Efficient Distributed Energy Systems on ScienceDirect