Abstract
This paper proposes a fault-detection method for open-switch failures in hybrid active neutral-point-clamped (HANPC) rectifiers. The basic HANPC topology comprises two SiC-based metal-oxide-semiconductor field-effect transistors (MOSFETs) and four Si insulated-gate bipolar transistors (IGBTs). A three-phase rectifier system using the HANPC topology can produce higher efficiency and lower current harmonics. An open-switch fault in a HANPC rectifier can be a MOSFET or IGBT fault. In this work, faulty cases of six different switches are analyzed based on the current distortion in the stationary reference frame. Open faults in MOSFET switches cause immediate and remarkable current distortions, whereas, open faults in IGBT switches are difficult to detect using conventional methods. To detect an IGBT fault, the proposed detection method utilizes some of the reactive power in a certain period to make an important difference, using the direct-quadrant (dq)-axis current information derived from the three-phase current. Thus, the proposed detection method is based on three-phase current measurements and does not use additional hardware. By analyzing the individual characteristics of each switch failure, the failed switch can be located exactly. The effectiveness and feasibility of the proposed fault-detection method are verified through PSIM simulations and experimental results.
Highlights
The demands for higher efficiency and power have increased the research on topics related to power converters, in various industrial areas and energy-conversion fields [1,2,3,4]
For normal operation of the hybrid active neutral-point-clamped (HANPC) rectifier, the peak value of the 3-P phase current is controlled as 5 A, and there is a 120°
For normal operation of the HANPC rectifier, the peak value of the 3-P phase current is controlled as 5 A, and there is a 120◦ phase-angle difference between each phase
Summary
The demands for higher efficiency and power have increased the research on topics related to power converters, in various industrial areas and energy-conversion fields [1,2,3,4]. A multilevel power converter has several advantages such as low power loss, high power output, and higher voltage capability [5,6,7,8]. Among the various multilevel converters, the three-level voltage-source converter (3-L VSC) has the advantages of bidirectional power-flow capability and low voltage stress for each switching device. The 3-L VSC uses pulse-width modulation (PWM) techniques for controlling the output power when performing DC-AC or AC-DC conversions [9,10,11,12,13,14]. The diode neutral-point-clamped (DNPC) inverter was proposed in the 1980s; it has disadvantages such as the need for capacitor voltage balancing and relatively high switching losses [15].
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