Abstract :
Novel dynamic voltage-sharing schemes have been developed to allow any high-voltage power-semiconductor device, e.g. thyristor, IGCT, IGBT or power MOSFET, to be series-connected in strings, and switched as simply and rapidly in high-voltage applications as single devices. The circuits have many of the advantages of simply using RC or RCD snubbers, including being easily applicable to both low- and high-side switches. However, because the snubber capacitors are not fully discharged their associated reset current and power-losses are minimized. To illustrate the principle of operation experimentally, a string of three series-connected power MOSFETs switching 100 A from 330 V has been used to obtain practical waveforms. The schemes are discussed and illustrated, using SPICE simulation results. The new, relatively simple voltage-sharing schemes are much easier to design and optimize than recently reported active gate-control and regenerative-snubber methods, allow very rapid turn-on and turn-off switching, and give composite- device switches a usable voltage rating similar to the aggregated voltage ratings of the string.
Keywords :
power MOSFET; power capacitors; power conversion; snubbers; RCD snubbers; active gate-control; dynamic voltage-sharing schemes; high-side switches; high-voltage power conversion; high-voltage power-semiconductor device; regenerative-snubber methods; series connecting devices; series-connected power MOSFET; snubber capacitors; turn-off switching; turn-on switching; voltage-sharing schemes; Insulated gate bipolar transistors; Joining processes; MOSFET circuits; Power MOSFET; Power conversion; Snubbers; Switches; Switching circuits; Thyristors; Voltage; series connected IGBT; series connected IGCT; series connection; voltage balancing; voltage sharing;
