Optimal Control Of Wind Energy Systems Towards A Global Approach

From the Publisher

Owing to the shastic nature of their primary energy source, workable performance of wind energy conversion systems cannot be achieved without the contribution of automatic control.

Optimal Control of Wind Energy Systems presents a thoroughgoing review of the main control issues in wind power generation, offering a unified picture of the issues in optimal control of wind power generation. A series of optimal control techniques are analyzed, assessed and compared, starting with the classical ones, like PI control, maximum power point strategies and gain-scheduling techniques, and continuing with some modern ones: sliding-mode techniques, feedback linearization control and robust control. Discussion is focused on a global dynamic optimization approach to wind power systems using a set of optimization criteria which comply with a comprehensive group of requirements including: energy conversion efficiency; mechanical reliability; and quality of the energy provided.

The main results are presented along with illustration by case studies and MATLAB^®/Simulink^® simulation assessment. The corresponding programmes and block diagrams can be downloaded from the book’s page at springer.com. For some of the case studies presented, real-time simulation results are also available, illustrative examples which will be useful in easing technology transfer in control engineering associated with wind power systems.

Control engineers, researchers and graduate students interested in learning and applying systematic optimization procedures to wind power systems will find this a most useful guide to the field.

Editorial Reviews -

Optimal Control of Wind Energy Systems

From the Publisher

Owing to the shastic nature of their primary energy source, workable performance of wind energy conversion systems cannot be achieved without the contribution of automatic control.

Optimal Control of Wind Energy Systems presents a thoroughgoing review of the main control issues in wind power generation, offering a unified picture of the issues in optimal control of wind power generation. A series of optimal control techniques are analyzed, assessed and compared, starting with the classical ones, like PI control, maximum power point strategies and gain-scheduling techniques, and continuing with some modern ones: sliding-mode techniques, feedback linearization control and robust control. Discussion is focused on a global dynamic optimization approach to wind power systems using a set of optimization criteria which comply with a comprehensive group of requirements including: energy conversion efficiency; mechanical reliability; and quality of the energy provided.

The main results are presented along with illustration by case studies and MATLAB^®/Simulink^® simulation assessment. The corresponding programmes and block diagrams can be downloaded from the book’s page at springer.com. For some of the case studies presented, real-time simulation results are also available, illustrative examples which will be useful in easing technology transfer in control engineering associated with wind power systems.

Control engineers, researchers and graduate students interested in learning and applying systematic optimization procedures to wind power systems will find this a most useful guide to the field.

Features -

Optimal Control of Wind Energy Systems

• Table of Contents

Table of Contents

1 Wind Energy 1

2 Wind Energy Conversion Systems 9

3 WECS Modelling 29

4 Basics of the Wind Turbine Control Systems 71

5 Design Methods for WECS Optimal Control with Energy Efficiency Criterion 109

6 WECS Optimal Control with Mixed Criteria 169

7 Development Systems for Experimental Investigation of WECS Control Structures 219

8 General Conclusion 239

App. A Features of WECS Used in Case Studies 243

App. B Elements of Theoretical Background and Development 247

App. C Photos, Diagrams and Real-time Captures 261

References 269

Index 281

Synopsis

Owing to the shastic nature of their primary energy source, workable performance of wind energy conversion systems cannot be achieved without the contribution of automatic control.

Optimal Control of Wind Energy Systems presents a thoroughgoing review of the main control issues in wind power generation, offering a unified picture of the issues in optimal control of wind power generation. A series of optimal control techniques are analyzed, assessed and compared, starting with the classical ones, like PI control, maximum power point strategies and gain-scheduling techniques, and continuing with some modern ones: sliding-mode techniques, feedback linearization control and robust control. Discussion is focused on a global dynamic optimization approach to wind power systems using a set of optimization criteria which comply with a comprehensive group of requirements including: energy conversion efficiency; mechanical reliability; and quality of the energy provided.

The main results are presented along with illustration by case studies and MATLAB^®/Simulink^® simulation assessment. The corresponding programmes and block diagrams can be downloaded from the book’s page at springer.com. For some of the case studies presented, real-time simulation results are also available, illustrative examples which will be useful in easing technology transfer in control engineering associated with wind power systems.

Control engineers, researchers and graduate students interested in learning and applying systematic optimization procedures to wind power systems will find this a most useful guide to the field.

About The Author:

Biography

The authors are with the Advanced Control System Research Centre at "Dunarea de Jos" University of Galati in Romania. Their research interests are in the domain of static and dynamic optimizations, with a focus on dynamic system optimal control. The interest in the control of the wind energy conversion systems dates back to 1993.

Iulian Munteanu received a B.Eng. degree in applied electronics from "Dunarea de Jos" University of Galati in Romania in 1996, a M.Sc. degree in instrumentation and control from Université du Havre in France in 1997 and a Ph.D. degree in automatic control systems from "Dunarea de Jos" University of Galati in Romania in 2006, by defending a dissertation on the optimal control of wind power systems. From 1998 he is with the Department of Electronics and Telecommunications from "Dunarea de Jos" University of Galati in Romania. Between 2000 and 2005 he has had three doctoral stages at Laboratoire d'Électrotechnique de Grenoble in France, where he has worked on controlling the variable-speed asynchronous-machine-based wind power systems. He has authored and co-authored 1 book, 7 research reports, about 10 papers at international conferences and 5 papers in international journals. At the present he is a post-doctoral researcher at Grenoble Génie Électrique Laboratory in France.

Antoneta Iuliana Bratcu received a M.Sc. degree in electrical engineering from "Dunarea de Jos University of Galati in Romania in 1996 and a doctoral degree in automatic control and computer science from Université de Franche-Comté de Besançon in France in 2001. Her research interests include both discrete and continuous optimization. Between 2002 and 2005 she has had two post-doctoral stages respectively at Université de Technologie de Troyes and École Nationale Supérieure des Mines de Saint Étienne in France. She has authored and co-authored 2 books, 3 research reports, more than 25 papers at international conferences and 9 papers in international journals. In 2007 she joined the Department of Electrical Energy Conversion Systems from "Dunarea de Jos" University of Galati in Romania, where she is an associate professor. She is presently working as a post-doctoral researcher at Grenoble Génie Électrique Laboratory in France.

Nicolas-Antonio Cutululis received a M.Sc. degree in advanced automatic control and artificial intelligence and a Ph.D. degree in automatic control systems, both from "Dunarea de Jos" University of Galati in Romania in 1999 and 2005 respectively. His Ph.D. dissertation thesis concerns the design of control strategies for hybrid wind energy conversion systems. He has authored and co-authored 1 book, 5 research reports, 5 papers at international conferences and 7 papers in international journals. From 1999 he joined the Department of Electrical Energy Conversion Systems at "Dunarea de Jos University of Galati in Romania. At the present he is a scientist with the Wind Energy Department at Risø National Laboratory in Denmark.

Emil Ceanga received a M.Sc. degree in electronics and a Ph.D. degree in automatic control systems, both from Bucharest Polytechnic Institute in Romania, in 1961 and 1969 respectively. Between 1993 and 2004 he has been five times visiting professor at Groupe de Recherche en Automatique et Électrotechnique at Université du Havre in France and one time visiting professor at Université du Québec à Rimouski in Canada. In 2004 he received the distinction "Palmes Académiques" from the French Government. He has advised 15 Ph.D. dissertations and has authored and co-authored 15 books and more than 130 papers at international conferences and in international journals. Between 2001 and 2006 he was Director of the Advanced Control System Research Centre at "Dunarea de Jos University of Galati in Romania. He is presently a professor of electrical engineering at the Department of Electrical Energy Conversion Systems at the same university.

Special Features:

Features -

Optimal Control of Wind Energy Systems

• Table of Contents

Table of Contents

1 Wind Energy 1

2 Wind Energy Conversion Systems 9

3 WECS Modelling 29

4 Basics of the Wind Turbine Control Systems 71

5 Design Methods for WECS Optimal Control with Energy Efficiency Criterion 109

6 WECS Optimal Control with Mixed Criteria 169

7 Development Systems for Experimental Investigation of WECS Control Structures 219

8 General Conclusion 239

App. A Features of WECS Used in Case Studies 243

App. B Elements of Theoretical Background and Development 247

App. C Photos, Diagrams and Real-time Captures 261

References 269

Index 281