Dersin Adı
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Türkçe |
Güç Elektroniği End. Uyg.
|
| İngilizce |
Ind. Appl. of Power Electron. |
Dersin Kodu
|
ELK 453E |
Kredi |
Ders
(saat/hafta) |
Uygulama
(saat/hafta) |
Labratuvar
(saat/hafta) |
| Dönem |
6
|
3 |
3 |
- |
- |
| Dersin Dili |
İngilizce |
| Dersin Koordinatörü |
Salih Barış Öztürk
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| Dersin Amaçları |
1. To recognize the components of power electronics and learn their key characteristics.
2. To recognize the basic operation, losses and efficiency of the power electronics converters.
3. To use various methods to analyze power electronics circuits.
4. To develop a good insight about the practical issues in power electronics circuit design.
5. To explain and demonstrate operational issues and limitations of practical converters in industrial applications.
6. To explain the application requirements of converters in given applications.
7. To develop students' ability to analyze and solve power electronics problems/designs using advanced computer simulation platforms.
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| Dersin Tanımı |
The course focuses on presenting the fundamental concepts on conversion, control and monitoring of electric energy using power semiconductor devices.
Methods for analyzing power electronic converters suitable for DC/DC and DC/AC electrical energy conversions including resonant converters/inverters are presented.
Additionally, principles for designing power electronic converters, including their power semiconductors and passive elements are established. Computer-aided analysis and simulations of the electrical performance of power electronic converters are also among the course objectives.
The application of power electronic converters in the fields of sustainable/renewable energy technologies such as wind and solar energy are described. Furthermore, industrial applications like SMPSs, UPSs and induction heating (resonant converters), as well as, application of power electronics for electric motor drives, transmission, distribution and control in the future power system, including micro and smart grids are described.
Details of the Course Description:
Characteristics of power electronic devices, switching characteristics of devices and review of power losses. Classes of power converters and their operations: DC/DC converters. Voltage and current source converters. Hard and soft-switching and resonant circuits. Power supplies (uninterruptible, switch-mode), power-factor-correction (PFC) circuits and designing the feedback controller, review of AC motor control theory (fundamentals of vector/field-oriented control), power electronics control principles, fundamentals of modulation methods (e.g. SPWM vs. SVPWM) for AC drives. Utility applications of power electronics, system design, implementation, control, and computer interfacing.
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| Dersin Çıktıları |
Knowledge:
After completing the course, the student will
1. have an in-depth understanding of the theory of electrical energy conversion using power electronic systems that perform AC/DC, DC/DC and DC/AC conversion, including applications within renewable energy, energy storage, micro grid and industrial applications.
2. be able to identify the most important design parameters and to recognize the impact of operating parameters on the planning and use of power electronics converters in the existing and future electric power grid infrastructure and in industrial installations.
3. understand operating principles and modulation strategies for switch-mode DC/DC power electronic converters.
4. understand operating principles, modulation strategies and PWM control of DC/AC inverters including resonant inverters.
5. understand advanced modeling and control of power electronic converters.
6. model and simulate the electrical performance of power electronics systems using power electronics circuits simulation tools (MATLAB®/Simulink®, OrCAD/Capture, PSpice, LTSpice, PLECS, PSIM, SIMBA, etc.).
Skills:
After the conclusion of the course, the student will be able to:
- recognize, define, and analyze power electronic converters that perform DC/DC and DC/AC electrical energy conversions.
- model and simulate the electrical, thermal and electromagnetic performance of power electronic systems using advanced electric circuits simulation tools.
- design power electronic converters exhibiting high-performance operation with argument criteria.
- analyze the operating principles and modulation strategies for switch-mode DC/DC power electronic converters and PWM control of DC/AC inverters including resonant inverters.
- plan and operate the use of power electronic converters in the present and future electric grid and industrial installations.
- use computer simulation platforms (MATLAB®/Simulink®, OrCAD/Capture, PSpice, LTSpice, PLECS, PSIM (powersimtech.com), SIMBA, VisSim, etc.).
General competence:
After completing the course, the candidate has increased:
- skills in cooperation and interdisciplinary collaboration
- ability to represent himself/herself to professionals and non-specialists alike through reports
- ability to contribute to innovation and innovation processes |
| Önkoşullar |
ELK331 (Güç Elektroniği Devreleri)/ELK331E (Power Electronics Systems) MIN DD
To succeed in this course depends on the good knowledge of the following fundamental electrical engineering topics:
1. Steady-state and transient analysis of linear electric circuits containing resistors, inductors, and capacitors.
2. The behavior of RLC circuits involving switches.
3. Solution of differential equations with initial conditions.
4. Phasor analysis of AC circuits, computing RMS and average values, power factor, meaning of leading and lagging power factors.
5. Apparent, real, and reactive powers in single- and three-phase power system.
6. Algebra with complex numbers, transformation from rectangular to polar coordinate and vice-versa.
7. Control systems with loop stability analysis (Bode plots, etc.), derivation of system transfer functions in s-domain and develop proper controller theoretically and analyze the system using simulation software platform (PSIM (powersimtech.com), MATLAB®/Simulink®).
8. Good knowledge of MATLAB®/Simulink® including SimscapeTM, Simscape ElectricalTM, Simscape Electrical > Specialized Power Systems (formerly known as SimPowerSystemsTM) to model and simulate electronic, mechatronic, and electrical power systems, Control Systems ToolboxTM.
9. Use of power electronic circuit design and analysis including system/control level simulations using MATLAB®/Simulink®, PSpice, LTSpice, PSIM, etc., may be required for assignments.
10. Electromechanical energy conversion and/or electrical machines related courses.
Note1: Simscape™ Electrical™ (formerly SimPowerSystems™ and SimElectronics®) provides component libraries for modeling and simulating electronic, mechatronic, and electrical power systems. It includes models of semiconductors, motors, and components for applications such as electromechanical actuation, smart grids, and renewable energy systems. You can use these components to evaluate analog circuit architectures, develop mechatronic systems with electric drives, and analyze the generation, conversion, transmission, and consumption of electrical power at the grid level.
Simscape™ Electrical™ helps you develop control systems and test system-level performance. You can parameterize your models using MATLAB® variables and expressions and design control systems for electrical systems in Simulink®. You can integrate mechanical, hydraulic, thermal, and other physical systems into your model using components from the Simscape™ family of products. To deploy models to other simulation environments, including hardware-in-the-loop (HIL) systems, Simscape™ Electrical™ supports C-code generation.
https://www.mathworks.com/help/physmod/sps/getting-started-with-simscape-electrical.html
Note2: Control System Toolbox™ provides algorithms and apps for systematically analyzing, designing, and tuning linear control systems. You can specify your system as a transfer function, state-space, zero-pole-gain, or frequency-response model. Apps and functions, such as step response plot and Bode plot, let you analyze and visualize system behavior in the time and frequency domains.
https://www.mathworks.com/help/control/index.html?searchHighlight=control%20systems&s_tid=doc_srchtitle
Note3: The above subjects will not be directly covered/explained in the class - this course assumes you have sufficient knowledge of these topics. If you feel that your background on the above material is insufficient, you are advised to take a look at your circuit's, mathematics’ and control systems notes and/or books as well as MATLAB®/Simulink® help documents and related resources on the web. |
| Gereken Olanaklar |
Use of power electronic circuit design and analysis, including system/control level simulations using MATLAB®/Simulink®, OrCAD/Capture, PSpice, LTspice, PLECS, PSIM, SIMBA, etc., may be required for assignments and the project.
Inkscape, MS Word, Excel, PowerPoint, Beamer, and LaTeX for the reports and presentations. |
| Diğer |
For detailed and up-to-date information please visit ninova site: https://ninova.itu.edu.tr/Sinif/13227.99979 as well as the course website at http://web.itu.edu.tr/ozturksb (not active yet !) and MATLAB® help documents, and MATLAB® File Exchange at https://www.mathworks.com/matlabcentral/fileexchange/ |
| Ders Kitabı |
• Daniel W. Hart, Introduction to Power Electronics, Int. Ed., 1st Ed., McGraw-Hill, 2013, ISBN-13: 978-0071321204
• Ned Mohan, Power Electronics: A First Course, 1st Ed., Hoboken, NJ: John Wiley & Sons, Inc., 2011, ISBN-13: 978-1118074800 |
| Diğer Referanslar |
• M. H. Rashid, Power Electronics: Circuits, Devices, and Applications, 4th Ed., Pearson, 2013, ISBN-13: 978-0133125900
• N. Mohan, T. M. Undeland, and W. P. Robbins, Power Electronics: Converters, Applications, and Design, Int. Ed., 3rd Ed., John Wiley & Sons, Inc., 2003, ISBN-13: 978-0471429081
• R. W. Erickson and D. Maksimovic, Fundamentals of Power Electronics, Springer, 2nd Ed., 2001, ISBN-13: 978-0792372707
• Muhammad H. Rashid, Power Electronics Handbook, 4th Ed., Butterworth-Heinemann, 2017, ISBN-13: 978-0128114070
• Sanjaya Maniktala, Switching Power Supplies A - Z, 2nd Ed., Newnes, 2012, ISBN-13: 978-0123865335
• Mahesh Patil and Pankaj Rodey, Control Systems for Power Electronics A Practical Guide, Springer, 2015, ISBN-13: 978-81-322-2327-6
• Euzeli dos Santos, Edison R. da Silva, Advanced Power Electronics Converters: PWM Converters Processing AC Voltages, Hoboken, NJ: John Wiley & Sons, Inc., 2014, ISBN: 978-1-118-88094-4
• Muhammad H. Rashid, Alternative Energy in Power Electronics, Butterworth-Heinemann, 2015, ISBN 978-0-12-416714-8
• Bogdan M. Wilamowski, J. David Irwin, Power Electronics and Motor Drives, 1st Ed., CRC Press, 2017, ISBN-13: 978-1-138-07747-8
• Haitham Abu-Rub, High Performance Control of AC Drives with Matlab/Simulink, Hoboken, NJ: John Wiley & Sons, Inc., 2012, ISBN-13: 978-0470978290
• Issa Batarseh, Ahmad Harb, Power Electronics: Circuit Analysis and Design, 2nd Ed., Springer, 2018, ISBN-13: 978-3319683652
• Muhammad Aamir, Design of a Non-isolated Single Phase Online UPS Topology with Parallel Battery Bank for Low Power Applications, Springer Theses, 1st Ed., Springer Nature Singapore Pte Ltd., 2019
• Adel Nasiri, 24 - Uninterruptible Power Supplies, Editor(s): Muhammad H. Rashid, Power Electronics Handbook (Third Edition), Butterworth-Heinemann, 2011, Pages 627-641
• Kim,E.-H. et al, Transformerless three-phase on-line UPS with high performance. IET Power Electronics (2009),2(2):103 http://dx.doi.org/10.1049/iet-pel:20070422
• Ned Mohan, Advanced Electric Drives: Analysis, Control, and Modeling Using MATLAB/Simulink, NJ: John Wiley & Sons, Inc., September 2014, ISBN-13: 978-1-118-48548-4
• Bin Wu, Yongqiang Lang, Navid Zargari, Samir Kouro, Power Conversion and Control of Wind Energy Systems, John Wiley & Sons, Inc., Hobokeni New Jersey, 2011, ISBN-13 978-1-118-02899-5
• Bogdan M. Wilamowski, J. David Irwin, Power Electronics and Motor Drives, 1st Ed., CRC Press, 2017, ISBN-13: 978-1-138-07747-8
• Bin Wu, High-Power Converters and AC Drives, IEEE Press, John Wiley & Sons, Inc., Hoboken, New Jersey, ISBN-13 978-0-471-73171-9.
• George Ellis, Control System Design Guide: A Practical Guide, 3rd ed., Elsevier Academic Press, 2004, ISBN-10: 0-12-237461-4
• P. Vas, Sensorless Vector and Direct Torque Control, Oxford University Press, 1998, ISBN: 198564651
• Sang-Hoon Kim, Electric Motor Control: DC, AC, and BLDC Motors, Elsevier Science, 2017, 1st ed., eBook ISBN: 9780128123195, Paperback ISBN: 9780128121382 |
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