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Predictive Analysis for Radiated Electromagnetic Disturbance in MMC-HVDC Valve Hall

Guishu Liang

2020CPSS Transactions on Power Electronics and Applications25 citationsDOIOpen Access PDF

Abstract

The radiated electromagnetic interference (EMI) in the valve hall of the modular multilevel converter (MMC) station must be limited below a certain value to ensure the normal operation of the equipment and the safety of the engineers. In this paper, a method for predicting the radiated EMI is proposed, which takes all the necessary factors, such as the physics-based characteristics for IGBT module, sub-module topology, and converter space structure into consideration. This method involves the improved physical model of semiconductor devices, which discards the non-physical feedback parameter introduced by some previous research. At the same time, through the decoupling of the submodule and the bridge arm circuit, the order of the large-scale system is reduced so that the sub-modules can be calculated in parallel, greatly reducing the overall calculation burden of the model and accelerating the nonlinear small time-step simulation. The wideband characteristics of the converter valve tower are fully considered, with each of the bridge arms regarded as a two-port network with independent sources. The parameter integration and distribution process can also achieve complete parallel calculation. The converter valve tower is modeled as a complex antenna structure with the output voltage of each sub-module as the excitation, the calculation of near-field radiation intensity for the converter valve tower is performed in Alteir FEKO. The measurement conducted inside an actual 49-level converter station verifies the accuracy of the model.

Topics & Concepts

HVDC converterEMIElectromagnetic interferenceEngineeringElectronic engineeringTopology (electrical circuits)Decoupling (probability)Electrical engineeringVoltageTransformerControl engineeringHVDC Systems and Fault ProtectionElectromagnetic Compatibility and Noise SuppressionLightning and Electromagnetic Phenomena