The voltage rise of the low voltage (LV) power distribution grid to which multiple solar photovoltaic (PV) systems are integrated is a critical technical problem that should be addressed. With PV systems that are integrated to the LV power distribution grid (with an $R$ to $X$ ratio greater than unity) via voltage source converters, the opportunity exists to regulate the respective point of common coupling (PCC) voltages by dynamically controlling the active and reactive power response of PV systems. In this paper, two closed-loop controllers that are able to regulate the PCC voltage by dynamically controlling the active and reactive power response of the PV system are presented. The design methodology is presented with considerable detail. The plant model of each controller is derived and the design procedure of each controller is explained in detail. By combining the dynamic active and reactive power controllers proposed in this paper, two novel operating strategies for PV systems, fixed minimum power factor operation and fixed maximum apparent power operation, are introduced. The latter operating strategy has been identified as the most efficient way of regulating the PCC voltage of a PV system. The simulation results and experimental validation confirm the accuracy of the derived plant models, the robustness of the designed controllers and the feasibility of implementing the proposed novel operating strategies in PV systems.
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机译:集成了多个太阳能光伏(PV)系统的低压(LV)配电网的电压上升是应解决的关键技术问题。使用通过电压源转换器集成到LV配电网($ R $与$ X $之比大于1)的PV系统,就有机会通过动态控制来调节公共耦合(PCC)电压的相应点光伏系统的有功和无功功率响应。在本文中,提出了两个能够通过动态控制光伏系统的有功和无功响应来调节PCC电压的闭环控制器。详细介绍了设计方法。推导出每个控制器的工厂模型,并详细说明每个控制器的设计过程。通过结合本文提出的动态有功和无功功率控制器,介绍了两种新的光伏系统运行策略,即固定最小功率因数运行和固定最大视在功率运行。后者的运行策略已被认为是调节光伏系统PCC电压的最有效方法。仿真结果和实验验证证实了派生工厂模型的准确性,所设计控制器的鲁棒性以及在光伏系统中实施所提出的新颖操作策略的可行性。
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