Litcius/Paper detail

A Hypothesis Method for T-Type Three-Level Inverters Open-Circuit Fault Diagnosis Based on Output Phase Voltage Model

Weiwei Zhang, Yigang He

2022IEEE Transactions on Power Electronics31 citationsDOI

Abstract

The open-circuit (OC) faults for T-type three-level inverters often share similar distorted output features, which are usually distinguished by adopting invasive methods. The purpose of this article is to locate the OC fault by rebuilding the established phase voltage model according to the hypothesis method. Based on the vector decomposition principle and voltage-second balancing theory, the output phase voltage model is established considering neutral point voltage unbalance and time-offset injection. The hypothetical phase voltage vector and residual for fault reasoning can be obtained by inputting the suspected OC faults positions to the model. The hierarchical fault diagnosis scheme involves two steps. First, the group-level fault can be located according to voltage residual vector amplitude and angle. Considering the impact of parameter error, dead time, and delay time, an adaptive residual vector amplitude threshold is designed. Next, the device-level fault can be located by building two suspected phase voltage models to approximate the real system. Furthermore, the fault location rules under zero-crossing (ZC) and non-ZC conditions are summarized. Especially, the proposed hypothesis method has correctness verification ability to avoid misdiagnosis. Experimental results show the robustness and effectiveness of the proposed low coupling fault diagnosis method.

Topics & Concepts

ResidualControl theory (sociology)Robustness (evolution)VoltageCorrectnessFault (geology)Stuck-at faultOffset (computer science)AmplitudeComputer scienceEngineeringAlgorithmFault detection and isolationPhysicsArtificial intelligenceControl (management)Electrical engineeringActuatorProgramming languageGeologyBiochemistryGeneQuantum mechanicsSeismologyChemistryMultilevel Inverters and ConvertersSilicon Carbide Semiconductor TechnologiesAdvanced DC-DC Converters