This course focuses on operation and control technologies of an electric power system, on which modern society heavily depends, putting due emphasis on system technologies. Topics include control of active and reactive power, modeling of power apparatus, surge phenomena in a power system and analysis techniques for load flow and stability.
At the end of this course, students will be able to:
1) Understand basics on operation and control of an electric power system;
2) Understand various phenomena observed in an electric power system under normal and fault conditions;
3) Understand fundamental methods such as load flow and stability analyses for a power system.
frequency control, voltage control, economic load dispatch, load flow analysis, angle stability, cascaded outages, stabilizing control, overvoltage, surge, DC transmission.
Specialist skills | Intercultural skills | Communication skills | ✔ Critical thinking skills | Practical and/or problem-solving skills |
✔ ・Applied specialist skills on EEE |
1) Lectures are given based on the materials distributed through T2SCHOLA. Students are required to make preparation and review with the materials.
2) Students must submit a report on exercise problems assigned in each class.
3) Solutions to the problems assigned in the previous class are explained at the beginning of each class.
Course schedule | Required learning | |
---|---|---|
Class 1 | Outline of a power system and its recent trend | Calculation of complex power for a sample system |
Class 2 | Load flow analysis (1): AC Flow Method | Load flow calculation using Newton-Raphson method |
Class 3 | Load flow analysis (2): DC Flow Method | Load flow calculation using DC flow method |
Class 4 | Voltage stability | Calculation of a high and low voltage solution for a sample system |
Class 5 | Voltage and reactive power control | Evaluation of sensitivity of control equipment for voltage control |
Class 6 | Angle stability | Analysis on the impacts of falt conditions on power-angle curves |
Class 7 | Stabilizing control | Explanation of cascading outages in a power system |
Class 8 | Control and performance of synchronous generators | Analysis of control characteristics of synchronous generators. |
Class 9 | Load frequency control | Calculation of frequency change due to a generator trip |
Class 10 | Supply-and-demand barlance and economic load dispatch | Calculation of power-incremental cost characteristics for a sample system |
Class 11 | Reliability of a power system | Assessment of reliability of series/parrarel circuits |
Class 12 | Power system protection | Explanation of fault detection methods in a computer relay |
Class 13 | Overvoltage in a power system | Explanation on the causes of overvoltage in a power system |
Class 14 | Current interruption | Calculation of surge propagation under an assumed condition |
To enhance effective learning, students are encouraged to spend approximately 100 minutes preparing for class and another 100 minutes reviewing class content afterwards (including assignments) for each class.
They should do so by referring to textbooks and other course material.
Textbook is not required.
1) All the materials used in a class can be found on T2SCHOLA.
2) Reference
Sekine, Taiji, "Power System Engineering," Denki-Shoin;
Hasegawa, Jun, "Power System Engineering," IEEJ;
Hayashi, Izumi: "Power System," Shokoudoh;
Okubo, Hitosh, et al.i "Electric Power System Engineering," Ohm-sha.
The course grade will be based on exercises, reports, and/or assignments (100%).
Students must have successfully completed Electric Power Engineering I or have equivalent knowledge. Students are also required to have basic knowledge on electric circuit and electric machinery.