New cost-effective silicon carbide high voltage switch created

October 4, 2016 by Alex Huang, North Carolina State University
The new NC State high-power switch has the potential to work more efficiently and cost less than conventional solutions. Credit: North Carolina State University

Researchers at North Carolina State University have created a high voltage and high frequency silicon carbide (SiC) power switch that could cost much less than similarly rated SiC power switches. The findings could lead to early applications in the power industry, especially in power converters like medium voltage drives, solid state transformers and high voltage transmissions and circuit breakers.

Wide bandgap semiconductors, such as SiC, show tremendous potential for use in medium- and high-voltage power devices because of their capability to work more efficiently at higher voltages. Currently though, their high cost impedes their widespread adoption over the prevailing workhorse and industry standard – insulated-gate bipolar transistors (IGBT) made from silicon – which generally work well but incur large energy losses when they are turned on and off.

The new SiC power switch, however, could cost approximately one-half the estimated cost of conventional high voltage SiC solutions, say Alex Huang and Xiaoqing Song, researchers at NC State's FREEDM Systems Center, a National Science Foundation-funded engineering research center. Besides the lower cost, the high-power switch maintains the SiC device's high efficiency and high switching speed characteristics. In other words, it doesn't lose as much energy when it is turned on or off.

The power switch, called the FREEDM Super-Cascode, combines 12 smaller SiC power devices in series to reach a power rating of 15 kilovolts (kV) and 40 amps (A). It requires only one gate signal to turn it on and off, making it simple to implement and less complicated than IGBT series connection-based solutions. The power switch is also able to operate over a wide range of temperatures and frequencies due to its proficiency in heat dissipation, a critical factor in power devices.

"Today, there is no high voltage SiC device commercially available at voltage higher than 1.7 kV," said Huang, Progress Energy Distinguished Professor and the founding director of the FREEDM Systems Center. "The FREEDM Super-Cascode solution paves the way for power switches to be developed in large quantities with breakdown voltages from 2.4 kV to 15 kV."

The FREEDM Super-Cascode switch was presented by Xiaoqing Song, a Ph.D. candidate at the FREEDM Systems Center under Huang's supervision, at the IEEE Energy Conversion Congress & Exposition (ECCE 2016) held in Milwaukee from Sept. 18-22, 2016.

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More information: "15kV/40A FREEDM Super-Cascode: A Cost Effective SiC High Voltage and High Frequency Power Switch." IEEE Energy Conversion Congress & Exposition in Milwaukee

Abstract: High voltage wide bandgap (WBG) semiconductor devices like the 15kV SiC MOSFET have attracted great attentions because of its potential applications in high voltage and high frequency power converters. However, these devices are not commercially available at the moment and their high cost due to expensive material growth and fabrication may limit their widespread adoption in the future. In this paper, a 15kV/40A three terminal power switch, the FREEDM Super-Cascode, is reported for the first time which is based on series connection of 1.2kV SiC power devices. The design and operation principle of the FREEDM Super-Cascode are introduced and the performance including the static blocking capability, conduction characteristics over a wide range of temperatures, and dynamic switching performances are analyzed. In addition, the thermal resistance of the FREEDM Super-Cascode is measured and the power dissipation capability is projected. The FREEDM Super-Cascode costs only one third of the estimated high voltage SiC MOSFETs, and will facilitate early applications of SiC in very high voltage and high frequency power converters.

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5 / 5 (1) Oct 04, 2016
So if I understand this article correctly, they simply took bunch of smaller IGBT devices and integrated them in a Cascode fashion. Parallel groups of cascoded IGBTs would probably require ballasting, but it probably does work. The only concern I have is that if/when it fails, it could actually get explosive. Of course, that would be the case with most semiconductor switches.

It is a clever reapplication of an old idea. Good work!
Oct 05, 2016
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