Title :
Design and technology of compact high-power converters
Author :
Shenai, Krishna ; Neudeck, Philip G. ; Schwarze, Gene
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Illinois Univ., Chicago, IL, USA
fDate :
3/1/2001 12:00:00 AM
Abstract :
New material technologies such as Silicon Carbide (SiC) are promising in the development of compact high-power converters for next-generation power electronics applications. This paper presents an optimized converter design approach that takes into consideration non-linear interactions among various converter components, source and load. It is shown that with the development of high-temperature, high-power SiC power module technology, magnetic components and capacitors become important technology challenges, and cannot be ignored. A 50% improvement in power density is calculated for a 100 V-2 kV, 7 kW SiC DC-DC power converter operating at 150°C compared to a silicon power converter. The SiC power converter can be operated at junction temperatures in excess of 300°C (as compared to 150°C for a silicon power converter) with reasonable efficiency that potentially leads to a significant reduction in thermal management
Keywords :
DC-DC power convertors; power supply circuits; semiconductor materials; silicon compounds; space vehicle power plants; 100 V to 2 kV; 150 C; 150°C; 300 C; 300°C; 7 kW; 7 kW SiC; DC-DC power converter; Si power converter; SiC; SiC power module; efficiency; high-power converters; high-temperature power module; junction temperatures; magnetic components; material technologies; non-linear interactions; optimized converter design; power density; spacecraft; thermal management; Capacitors; DC-DC power converters; Design optimization; Energy management; Materials science and technology; Multichip modules; Power electronics; Silicon carbide; Temperature; Thermal management;
Journal_Title :
Aerospace and Electronic Systems Magazine, IEEE
