Modul "Practical Course Power Electronics DC/DC Converter"
| Lecturer | |
| ECTS | 6 |
| Content | Practical Training: 4 SWS |
| Cycle | Summerterm |
| Time & Room | Room 0901 time schedule |
| Links | TUMonline |
| Language of instruction | English |
|---|
Objectives
After successful participation in the module, the student is able to:
• Work independently and safely in a power electronics laboratory
• Understand the behavior and operating mechanism of switched-mode power converters
• Understand the concept of systematic hardware debugging
• Understand the concept of electromagnetic compatibility analysis of DC/DC converters
• Apply the concept of efficiency analysis of DC/DC converters
• Evaluate different DC/DC converter topologies regarding efficiency, cost, electromagnetic compatibility
• Create a magnetic coil for a simple DC/DC converter
• Work independently and safely in a power electronics laboratory
• Understand the behavior and operating mechanism of switched-mode power converters
• Understand the concept of systematic hardware debugging
• Understand the concept of electromagnetic compatibility analysis of DC/DC converters
• Apply the concept of efficiency analysis of DC/DC converters
• Evaluate different DC/DC converter topologies regarding efficiency, cost, electromagnetic compatibility
• Create a magnetic coil for a simple DC/DC converter
Description
This module consists of a series of hands-on laboratory experiments with the following content being covered:
• Understanding the working principle of a buck-converter by measuring and testing a working prototype (12V-to-5V converter)
• Designing and building a magnetic coil for a boost converter and including this coil in an existing setup
• Analyzing an industrial DC/DC converter and its design criteria
• Experimental evaluation of a state-of-the-art load resonant converter (LLC)
• Experimental comparison of the different topologies regarding efficiency, electromagnetic compatibility, thermal behavior, and topology-dependent advantages
• Understanding the working principle of a buck-converter by measuring and testing a working prototype (12V-to-5V converter)
• Designing and building a magnetic coil for a boost converter and including this coil in an existing setup
• Analyzing an industrial DC/DC converter and its design criteria
• Experimental evaluation of a state-of-the-art load resonant converter (LLC)
• Experimental comparison of the different topologies regarding efficiency, electromagnetic compatibility, thermal behavior, and topology-dependent advantages