Experimentally validated methodology for real-time temperature cycle tracking in SiC power modules

© 2018 Elsevier Ltd The ability to monitor temperature variations during the actual operation of power modules is key to reliability investigations and the development of lifetime prediction strategies. This paper proposes an original solution, specifically devised with novel fast-switching silicon carbide (SiC) power MOSFETs in mind. The results show ability to track temperature variations resulting from active power cycling of the devices, including high speed transients, thus enabling to discriminate among different potential failure mechanisms. Validation of the proposed methodology and its accuracy is carried out with the support of infrared thermography

V-I Curve Based Condition Monitoring System for Power Devices

According to gaining importance of power electronics systems in the society, reliability issues of power semiconductor devices are the constrains on availability of the system operations. Regular interval based maintenance for higher availability, on the other hand, increases operation cost since the lifetime of power devices have a large deviation with production lots or conditions which they are used. Condition based maintenance (CBM) of power semiconductor devices will be a promising solution for both the availability and cost of power electronics system maintenance. In this study, a high signal resolution condition monitoring system board has been demonstrated. The system monitors real time V-I curve for both switching device and diode with case temperature and the data is stored on board memory and can be monitored on-line. The board was mounted on the gate driver board being supplied power from the gate driver board and demonstrated on a commercial 60kVA inverter.32nd International Symposium on Power Semiconductor Devices and ICs (ISPSD 2020), 13-18 September, 2020, Vienna, Austria （新型コロナ感染拡大に伴い、現地開催中止

Experimentally validated methodology for real-time temperature cycle tracking in SiC power modules

The ability to monitor temperature variations during the actual operation of power modules is key to reliability investigations and the development of lifetime prediction strategies. This paper proposes an original solution, specifically devised with novel fast-switching silicon carbide (SiC) power MOSFETs in mind. The results show ability to track temperature variations resulting from active power cycling of the devices, including high speed transients, thus enabling to discriminate among different potential failure mechanisms. Validation of the proposed methodology and its accuracy is carried out with the support of infrared thermography

Experimentally validated methodology for real-time temperature cycle tracking in SiC power modules

The ability to monitor temperature variations during the actual operation of power modules is key to reliability investigations and the development of lifetime prediction strategies. This paper proposes an original solution, specifically devised with novel fast-switching silicon carbide (SiC) power MOSFETs in mind. The results show ability to track temperature variations resulting from active power cycling of the devices, including high speed transients, thus enabling to discriminate among different potential failure mechanisms. Validation of the proposed methodology and its accuracy is carried out with the support of infrared thermography