Balancing Circuit for a 5-kV/50-ns Pulsed-Power Switch Based on SiC-JFET Super Cascode

In many pulsed-power applications, there is a trend to modulators based on semiconductor technology. For these modulators, high-voltage and high-current semiconductor switches are required in order to achieve a high pulsed power. Therefore, often, high-power IGBT modules or IGCT devices are used. Si...

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Bibliographic Details
Published inIEEE transactions on plasma science Vol. 40; no. 10; pp. 2554 - 2560
Main Authors Biela, J., Aggeler, D., Bortis, D., Kolar, J. W.
Format Journal Article
LanguageEnglish
Published New York IEEE 01.10.2012
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Capacitors
Electric power
Electrical equipment
Electrodes
Integrated circuits
JFETs
Logic gates
medium voltage switch
MOSFET circuits
Plasma physics
pulsed power systems
Resistors
Semiconductors
Switches
Transient analysis
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Summary:In many pulsed-power applications, there is a trend to modulators based on semiconductor technology. For these modulators, high-voltage and high-current semiconductor switches are required in order to achieve a high pulsed power. Therefore, often, high-power IGBT modules or IGCT devices are used. Since these devices are based on bipolar technology, the switching speed is limited, and the switching losses are higher. In contrast to bipolar devices, unipolar ones (e.g., SiC JFETs) basically offer a better switching performance. Moreover, these devices enable high blocking voltages in the case where wide-band-gap materials, for example, SiC, are used. At the moment, SiC JFET devices with a blocking voltage of 1.2 kV per JFET are available. Alternatively, the operating voltage could be increased by connecting N JFETs and a low-voltage MOSFET in series, resulting in a super cascode switch with a blocking voltage N times higher than the blocking voltage of a single JFET. For the super cascode, auxiliary elements are required for achieving a statically and dynamically balanced voltage distribution in the cascode. In this paper, a new balancing circuit, which results in faster switching transients and higher possible operating pulse currents, is presented and validated by measurement results.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2011.2169090