40 research outputs found
Direct Realization of Digital Differentiators in Discrete Domain for Active Damping of LCL-Type Grid-Connected Inverter
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Power electronics is a key technology that enables the revolution of electric power generation, transmission, and distribution in modern power systems for improved energy security, efficiency, and sustainability. In distribution systems, power electronic converters not only serve as the critical interfaces between the utility grid and distributed energy resources such as solar, wind, and energy storage, but also play a pivotal role in power quality control and management. In transmission systems, high voltage high power electronic converters are the ideal candidate for achieving flexible and efficient power flow in bulk interconnected power systems. On one hand, it is no doubt that more electronic apparatus will be integrated into future power systems to further reduce carbon emissions. On the other hand, power electronic converters exhibit significantly different characteristics with traditional power system components and may bring a number of challenging stability issues from both converter-level and system-level perspectives. The knowledge and theories for understanding and analysis of more electronics power systems are still lacking and deserve in-depth studies
A Highly Robust Single-Loop Current Control Scheme for Grid-Connected Inverter with an Improved LCCL Filter Configuration
Control Schemes for Reducing Second Harmonic Current in Two-Stage Single-Phase Converter: An Overview From DC-Bus Port-Impedance Characteristics
A rapid tracking method of maximum power point for solar units in series under uneven solar irradiance
When several solar units are combined into one branch in series, the multi-peak phenomenon of the output power of the branch would appear because of the bypass diodes. Based on analyzing the operation principle of the circuit, it was found that the number of peak points was determined by short-circuit currents and maximum-power- point currents of all the units in series. By use of the number of peak points and the values of the maximum-power-point currents, the power values of all the peak points were compared, then the approximate location of the global maximum power point was found, and finally the accurate point of maximum power was searched by incremental conductance method. This method has a rapid searching speed and an accurate result as well by applying a little calculation and using local-searching to replace global-searching. The proposed method is verified by experiments. Furthermore, the advantage of the faster searching speed is more obvious when more units are in series