|
Lecturer(s)
|
-
Klímek Miroslav, Ing. Ph.D.
-
Šebela Jan, doc. Ing. Ph.D.
-
Schorník Jiří, Ing. Ph.D.
-
Poór Daniel, doc. Ing. Ph.D.
-
Volf Tomáš, Ing. Ph.D.
-
Daněček Jan, Ing. Ph.D.
|
|
Course content
|
1. Power electronic components, basic concepts. 2. DC converters 3. Voltage source converters 4. Multilevel converters 5. Rectifiers 6. Current source converters 7. Frequency converters 1 8. Frequency converters 2 9. AC converters and resonant converters 10. Power electronics for road transport 11. Power electronics for rail transport 12. Power electronics for air and sea transport 13. Electromagnetic compatibility
|
|
Learning activities and teaching methods
|
Laboratory work, Lecture
- Preparation for comprehensive test (10-40)
- 10 hours per semester
- Graduate study programme term essay (40-50)
- 10 hours per semester
- Contact hours
- 26 hours per semester
- Practical training (number of hours)
- 26 hours per semester
- Preparation for an examination (30-60)
- 30 hours per semester
- Preparation for laboratory testing; outcome analysis (1-8)
- 6 hours per semester
|
| prerequisite |
|---|
| Knowledge |
|---|
| describe an electrical circuit |
| describe the operation and properties of basic electronic components |
| evaluate the influence of the circuit's electrical components on its function |
| Skills |
|---|
| define requirements for power semiconductor converters |
| explain the function of voltage and current types of converters |
| explain control principles of voltage and currents source converters |
| design a basic control algorithm for a drive with a power semiconductor converter |
| prepare a laboratory workplace and perform an experiment in power electronics |
| Competences |
|---|
| N/A |
| N/A |
| N/A |
| learning outcomes |
|---|
| Knowledge |
|---|
| describe in detail the schematic and function of power semiconductor converters used in electromobility |
| describe selected power semiconductor converter control algorithms |
| describe the effect of converters on electromagnetic compatibility with other systems |
| Skills |
|---|
| use known inverter topologies to design your own power circuit |
| use advanced converter control algorithms |
| design a simulation model of the inverter including control algorithms for the defined system |
| evaluate obtained experimental or simulation results |
| Competences |
|---|
| N/A |
| N/A |
| N/A |
| teaching methods |
|---|
| Knowledge |
|---|
| Lecture |
| Interactive lecture |
| Individual study |
| Laboratory work |
| Skills |
|---|
| Practicum |
| Laboratory work |
| Interactive lecture |
| Individual study |
| Competences |
|---|
| Lecture |
| Interactive lecture |
| Individual study |
| assessment methods |
|---|
| Knowledge |
|---|
| Combined exam |
| Test |
| Skills demonstration during practicum |
| Skills |
|---|
| Combined exam |
| Skills demonstration during practicum |
| Continuous assessment |
| Seminar work |
| Competences |
|---|
| Combined exam |
| Continuous assessment |
|
Recommended literature
|
-
Bin Wu. High-power converters and AC drives. Hoboken, 2006. ISBN 978-0-471-73171-9.
-
Kumar, L. Ashok. Power Converters for Electric Vehicles. Velká Británie, 2020. ISBN 9780367626853.
-
Vondrášek František. Výkonová elektronika. Svazek 3, Měniče s vlastní komutací a bez komutace. Část 2, Měniče kmitočtu a střídavého napětí. Plzeň. 2017.
|