Title :
Thermal performance of a dual 1.2 kV, 400 a silicon-carbide MOSFET power module
Author :
Boteler, Lauren ; Urciuoli, Damian ; Ovrebo, Gregory ; Ibitayo, Dimeji ; Green, Ron
Author_Institution :
Power Components Branch, Army Res. Lab., Adelphi, MD, USA
Abstract :
Power electronics are reaching the temperature limits of silicon; therefore alternative materials such as silicon carbide (SiC) are currently being explored. An all SiC 1.2 kV, 400 A dual MOSFET power module has been fabricated and tested for thermal performance. The module was designed as a dropin replacement for standard commercial modules with an integrated liquid cooling system that reduces thermal resistance. The heat sink has been experimentally tested up to 400 A (158 W/cm2) showing a device temperature rise of as little as 24°C. Thermal modeling was also performed and the results were compared to experimental data.
Keywords :
cooling; heat sinks; power MOSFET; silicon compounds; thermal resistance; wide band gap semiconductors; SiC; current 400 A; dual MOSFET power module; heat sink; integrated liquid cooling system; thermal modeling; thermal performance; thermal resistance; voltage 1.2 kV; Heat sinks; Liquid cooling; MOSFET circuits; Multichip modules; Power MOSFET; Power electronics; Silicon carbide; Temperature; Testing; Thermal resistance; MOSFET; Silicon carbide; power module; thermal modeling; thermal performance;
Conference_Titel :
Semiconductor Thermal Measurement and Management Symposium, 2010. SEMI-THERM 2010. 26th Annual IEEE
Conference_Location :
Santa Clara, CA
Print_ISBN :
978-1-4244-9458-3
Electronic_ISBN :
1065-2221
DOI :
10.1109/STHERM.2010.5444297
