Master Thesis: Online-Junction-Temperature Estimation of Double-Side-Cooled SiC Power-Module

Job Number: 49475
Group: Magna Powertrain
Division: ECV
Job Type: Student
Location: ST. VALENTIN
Group Introduction
Advancing mobility. Making automotive technology that is smarter, cleaner, and safer, while still fun to drive. And making it for everyone. That's what we're passionate about at Magna Powertrain. We do it by creating world-class powertrain solutions for conventional, hybrid, and pure electric vehicles. We're making electrification more than a buzzword, we're bringing it to the road. Innovation is what drives us and we drive innovation. Dream big and create the future of mobility at Magna Powertrain.
Work description
Due to their low thermal resistance and therefore better Chip utilization, double side cooled (DSC) power-modules gained significant attention in latest applications. Especially the rapidly accelerating trend towards silicon carbide semiconductors (SiC) promotes DSC-technology as total phase current per Die area can be significantly increased, where the raw semiconductor material Silicon Carbide is still expensive.
Even tough DSC-power-modules offer significant advantages in terms of Chip utilization, there are still major drawbacks related to testing the devices inside the power-inverter. Most prominent disadvantage is the lack of an easy to implement option to monitor junction temperature in operation, which is the main influencing factor for power-module degradation and limited lifetime.
This is related to the sandwich structure of the thermal stack, where the bare dies (power chips) are arranged between two individual DBC-Substrates. Above mentioned sandwich structure impedes any optical path with direct visibility to the dies. To overcome this issue TSEP (Temperature-Sensitive-Electrical Parameters) methods are usually adopted, where the thermal state of the device is monitored using one or more temperature dependent electrical parameters.
Scope of this work is the selection modelling and practical application of a suitable TSEP-method in real Inverter application using a DSC-silicon carbide module. Theoretical results should be evaluated by modelling and on a hardware demonstrator which should be designed as part of this work.
Your Responsibilities
• Literature research on available TSEP-methods• Modelling and simulation of different TSEP-methods• Selection of a suitable method for a hardware build-up• Design of a hardware demonstrator with focus on EMI-robustness• Build-up of the demonstrator• Measurements• Documentation
Your Qualifications
• Literature research on available TSEP-methods• Modelling and simulation of different TSEP-methods• Selection of a suitable method for a hardware build-up• Design of a hardware demonstrator with focus on EMI-robustness• Build-up of the demonstrator• Measurements• Documentation
Further information
For writing a master thesis you will receive a monthly fee of gross € 700,--
Start: by arrangement (duration approx. 6 months)
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We are always happy to offer our graduates the opportunity to start a career at Magna Powertrain after completing their studies.
Contact person:
Theresa Rittenschober, Tel.: +43 664 / 783 397 57, LinkedIn / Xing
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