Standalone single phase photo voltaic system as on-grid reactive power compensator

2015 International Conference on Power and Advanced Control Engineering (ICPACE) Pub Date : 2015-09-24 DOI:10.1109/ICPACE.2015.7274910

R. Prabhu, N. Prabhu

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引用次数: 0

Abstract

Demand for electricity is ever increasing and the conventional sources of energy are limited. Electricity generated using photovoltaic cells is pollution free. Grid connected PV systems generate power from the sun light and supply power to utility grid. Grid connected PV system is composed of a DC/DC converter, PWM inverter and a step-up transformer. A boost converter is used to stabilize the output voltage of the PV cells, which provides power to the SPWM inverter. Zero crossing PLL is used to synchronize the inverter with the grid. The active and reactive power can be transferred by controlling the phase angle and magnitude of the inverter output voltage. The local load connected to the system will receive the active and reactive power. At the same time, reactive power can be transferred to the grid by increasing the inverter voltage slightly keeping the phase angle between inverter voltage and grid voltage zero. The variation in inverter voltage to allow reactive power compensation is restricted by the voltage tolerance of the local load. Simulation study of this system is carried out with MATLAB/Simulink toolbox and simulation results are provided.

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独立式单相光伏系统并网无功补偿器

对电力的需求不断增加，而传统的能源是有限的。使用光伏电池发电是无污染的。并网光伏发电系统利用太阳光发电，并向公用电网供电。并网光伏系统由DC/DC变换器、PWM逆变器和升压变压器组成。升压变换器用于稳定PV电池的输出电压，为SPWM逆变器提供电力。过零锁相环用于使逆变器与电网同步。通过控制逆变器输出电压的相位角和幅值，实现有功和无功功率的传递。连接到系统的本地负载将接收有功和无功功率。同时，通过略微提高逆变器电压，保持逆变器电压与电网电压相角为零，将无功功率输送到电网。允许无功补偿的逆变器电压变化受到局部负载电压容限的限制。利用MATLAB/Simulink工具箱对该系统进行了仿真研究，并给出了仿真结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 International Conference on Power and Advanced Control Engineering (ICPACE)

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