Your search keyword '"LCL type"' showing total 2 results

1. Investigation on filter requirements and stability effects of SiC MOSFET-based high-frequency grid-connected converters

Author

Blessy John, Arindam Ghosh, and Firuz Zare

Subjects

frequency convertors, silicon compounds, power semiconductor devices, switching convertors, electromagnetic compatibility, wide band gap semiconductors, power grids, power conversion harmonics, power harmonic filters, power MOSFET, carbon compounds, wide bandgap device-based high-frequency power converters, silicon carbide-based power semiconductors, output filter requirements, silicon devices, third-order LCL filter, LCL type, filter parameters, L-type filter, resonance frequency, high-frequency region, wide bandgap devices, high bandwidth processors, measurement devices, computer-based simulation study, switching frequencies, switching loss, conduction loss, silicon carbide MOSFET-based high-frequency grid-connected converters, communication signals, Cree silicon carbide devices, PSCAD, MATLAB, frequency 15.0 kHz, SiC, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The new era of power semiconductor devices is exploiting the high potential of wide bandgap device-based high-frequency power converters. The advanced capabilities of Silicon carbide (SiC) semiconductors allow the power converters to switch at higher switching frequencies with lower switching and conduction losses. Operation under higher switching frequencies can drastically reduce the output filter requirements in grid-connected converters. At higher frequencies, an L-type filter can sufficiently eliminate the switching frequency harmonics. This will reduce the size and cost of the filter, which eventually results in the optimised system cost. In this paper, the filter requirements of SiC based high-frequency converters are investigated. Usage of LCL filters to remove high-frequency harmonic will shift the resonance frequency to high-frequency region, where these harmonics can create electromagnetic compatibility issues. In industries, passive damping is utilised for mitigating these oscillations. This will result in additional losses and compromise the advantages of SiC devices. Even though active damping can be utilised to eliminate resonance oscillations, the high bandwidth processors and measurement devices may increase the cost further. Simulation study is conducted on PSCAD/MATLAB and the experimental verification using Cree SiC devices verify the filter requirements, stability issues, and possible mitigating solutions for high-frequency grid converters.

Published

2019

2. Investigation on filter requirements and stability effects of SiC MOSFET-based high-frequency grid-connected converters.

Author

John, Blessy, Ghosh, Arindam, and Zare, Firuz

Subjects

CONVERTERS (Electronics), METAL oxide semiconductor field-effect transistors, SEMICONDUCTOR devices, SILICON carbide, ELECTRIC power system harmonics

Abstract

The new era of power semiconductor devices is exploiting the high potential of wide bandgap device-based high-frequency power converters. The advanced capabilities of Silicon carbide (SiC) semiconductors allow the power converters to switch at higher switching frequencies with lower switching and conduction losses. Operation under higher switching frequencies can drastically reduce the output filter requirements in grid-connected converters. At higher frequencies, an L-type filter can sufficiently eliminate the switching frequency harmonics. This will reduce the size and cost of the filter, which eventually results in the optimised system cost. In this paper, the filter requirements of SiC based high-frequency converters are investigated. Usage of LCL filters to remove high-frequency harmonic will shift the resonance frequency to high-frequency region, where these harmonics can create electromagnetic compatibility issues. In industries, passive damping is utilised for mitigating these oscillations. This will result in additional losses and compromise the advantages of SiC devices. Even though active damping can be utilised to eliminate resonance oscillations, the high bandwidth processors and measurement devices may increase the cost further. Simulation study is conducted on PSCAD/MATLAB and the experimental verification using Cree SiC devices verify the filter requirements, stability issues, and possible mitigating solutions for high-frequency grid converters. [ABSTRACT FROM AUTHOR]

Published

2019