针对不平衡电网下并联混合有源电力滤波器APF(active power filter)和无功补偿装置体积过大和系统损耗的问题,提出一种在不平衡电网下的静止无功发生器SVG(static var generator)和APF并直流母线联合运行系统。其中,SVG主要用来快速补...针对不平衡电网下并联混合有源电力滤波器APF(active power filter)和无功补偿装置体积过大和系统损耗的问题,提出一种在不平衡电网下的静止无功发生器SVG(static var generator)和APF并直流母线联合运行系统。其中,SVG主要用来快速补偿无功和电网不平衡,APF滤出电网和SVG的特定次谐波。该联合系统通过并直流母线减小了电容的体积,使系统总体积减小;降低SVG的开关频率使系统损耗减少。对系统环流抑制策略进行了分析,确定了在从模块上加入环流进行抑制环节,并解决了并联系统中出现的环流问题。最后通过Matlab/Simulink仿真验证了该联合系统的可行性。展开更多
This paper focuses on the implementation of a three-phase four-wire current-controlled Voltage Source Inverter (CC-VSI) as both power quality improvement and Photovoltaic (PV) energy extraction. For power quality ...This paper focuses on the implementation of a three-phase four-wire current-controlled Voltage Source Inverter (CC-VSI) as both power quality improvement and Photovoltaic (PV) energy extraction. For power quality improvement, the CC-VSI works as a grid current-controller shunt active power filter. Then, the PV array supported by the Hill- Climbing maximum power point tracking (MPPT) controller is coupled to the DC bus of the CC-VSI. The output of the MPPT controller is a DC voltage that determines the DC-bus voltage according to the PV maximum power. From computer simulation results, the CC-VSI is able to compensate for the harmonic and reactive power as well as to extract the PV maximum power.展开更多
文摘针对不平衡电网下并联混合有源电力滤波器APF(active power filter)和无功补偿装置体积过大和系统损耗的问题,提出一种在不平衡电网下的静止无功发生器SVG(static var generator)和APF并直流母线联合运行系统。其中,SVG主要用来快速补偿无功和电网不平衡,APF滤出电网和SVG的特定次谐波。该联合系统通过并直流母线减小了电容的体积,使系统总体积减小;降低SVG的开关频率使系统损耗减少。对系统环流抑制策略进行了分析,确定了在从模块上加入环流进行抑制环节,并解决了并联系统中出现的环流问题。最后通过Matlab/Simulink仿真验证了该联合系统的可行性。
文摘This paper focuses on the implementation of a three-phase four-wire current-controlled Voltage Source Inverter (CC-VSI) as both power quality improvement and Photovoltaic (PV) energy extraction. For power quality improvement, the CC-VSI works as a grid current-controller shunt active power filter. Then, the PV array supported by the Hill- Climbing maximum power point tracking (MPPT) controller is coupled to the DC bus of the CC-VSI. The output of the MPPT controller is a DC voltage that determines the DC-bus voltage according to the PV maximum power. From computer simulation results, the CC-VSI is able to compensate for the harmonic and reactive power as well as to extract the PV maximum power.