Abstract :
A detailed experimental evaluation is reported of DC-DC power electronic converters operating at cryogenic temperatures; the motivation for the study being the eventual integration of a converter with a superconducting electrical machine or energy storage device, SMES, with the benefit of increasing power density. The performance is examined of 120 V and 500 V, 500 W prototypes operating at temperatures down to 20 K; in particular the semiconductor losses are analyzed. Several designs are considered for each voltage level involving different power MOSFET devices, different power diodes, including a silicon carbide Schottky diode, a diode-less synchronous rectifier topology, and a zero voltage resonant transition DC-DC converter. The overall reduction of semiconductor losses at cryogenic temperatures compared with room temperature was up to 85%, depending on the particular circuit
Keywords :
DC-DC power convertors; Schottky diodes; cryogenics; losses; power MOSFET; power semiconductor diodes; rectifiers; resonant power convertors; superconducting machines; superconducting magnet energy storage; 120 V; 500 V; 500 W; DC-DC power electronic converters; cryogenic DC-DC converters; cryogenic power electronics; cryogenic temperature; diode-less synchronous rectifier topology; energy storage device; power MOSFET devices; power density; power diodes; semiconductor losses; silicon carbide Schottky diode; superconducting electrical machine; zero voltage resonant transition DC-DC converter; Cryogenics; DC-DC power converters; Energy storage; Power electronics; Samarium; Schottky diodes; Semiconductor diodes; Superconducting magnetic energy storage; Temperature dependence; Voltage; cryogenic power electronics;
