Dynamics and Modeling of Electrical Machines
Energy Systems Engineering
Institute of Natural and Applied Sciences
Second Cycle (Master's Degree)
| Course Unit Title | Course Unit Code | Type of Course Unit | Level of Course Unit | Year of Study | Semester | ECTS Credits |
|---|---|---|---|---|---|---|
| Dynamics and Modeling of Electrical Machines | FBE527 | Elective | Master's degree | 1 | Fall | 8 |
Name of Lecturer(s)
Prof. Dr. Ercüment KARAKAŞ
Associate Prof. Dr. Abdulhakim KARAKAYA
Learning Outcomes of the Course Unit
1) Recognizes the direct current machinery and the dynamic behavior and explain the principals
2) Defines the mathematical model of a direct current machine, shows and finds the system dynamic response
3) Defining the d-q-0 axis the set of synchronous machines, performs the numerical simulations of the reduced unit
4) Shows thevariable reference of synchronous machines, finds the numerical simulation of mathematical model of machines.
5) Recognizes the special electrical machines.
Program Competencies-Learning Outcomes Relation
| Program Competencies | ||||||||||||||||||||||||||||
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | 19 | 20 | 21 | 22 | 23 | 24 | 25 | 26 | 27 | ||
| Learning Outcomes | ||||||||||||||||||||||||||||
| 1 | Middle | Low | Middle | Middle | Middle | Low | Middle | Middle | Low | Middle | Low | Middle | Low | Middle | Low | Middle | Low | Middle | Middle | Low | Middle | Middle | Middle | Middle | Middle | Middle | Middle | |
| 2 | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 3 | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 4 | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 5 | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
Mode of Delivery
Face to Face
Prerequisites and Co-Requisites
None
Recommended Optional Programme Components
Not Required
Course Contents
1- Basic concepts, 2- The dynamic behavior of DC machines, 3- Direct current machines, circuit models, mathematical models, 4- Direct current machines, transfer functions, block diagrams, and system dynamic response, 5- d-q-0 axis synchronous machine modeling, unit quantities, and numerical simulations are reduced. 6- Mathematical models of induction machines at variable reference 7- Induction machine models and numerical simulations are reduced to unit
Recommended or Required Reading
Planned Learning Activities and Teaching Methods
Assessment Methods and Criteria
Contribution of Presentation/Seminar to Course Grade |
40% |
|---|---|
Contribution of Final Examination to Course Grade |
60% |
Total |
100% |
Language of Instruction
Turkish
Work Placement(s)
Not Required