"Wide-bandgap power switches offer higher temperature, higher frequency and higher voltage operation capability with lower losses compared to the currently used silicon-based power switches," professor Iqbal Husain at NC State told EE Times.
In addition to approaching the DoE mandate, NC State's wide-bandgap silicon-carbide inverter can also be packaged in a significantly smaller, lighter module, which it claims will increase the fuel efficiency and, thus, the range of both hybrid and all-electric vehicles.
"Efficiency, size and weight reduction are the most important aspects of our inverter,” said Husain. “This was built with all commercial off-the-shelf available components. We can reach the DoE target with some development at the component level, which we can do or the industry is expected to deliver in the near future."
Conventional inverters rely on the narrower bandgap of traditional silicon semiconductors, but the researchers at NC State's Future Renewable Electric Energy Distribution and Management (FREEDM) systems center claim that their wide-bandgap silicon-carbide inverters attained 99 percent efficiency — two percent higher than conventional converters today. They also used off-the-shelf components, giving hope of even better results from highly optimized components made especially for inverters.
In fact, the FREEDM lab is already hard at work manufacturing ultra-high-density silicon-carbide components that they hope will allow them to reach the DoE's goal long before 2020. The researchers are also working on stripping out the liquid cooling systems required by today's inverters because the wide-bandgap materials produce much less heat than narrow-bandgap materials. The current prototype is a 55-kW model, but air-cooled versions will probably be possible for smaller motors of about 35 kW — the kind used for motorcycles and small hybrid automobiles. The lab is also working on scaling up its