Design and implementation of a prototype DC photovoltaic power system simulator with Maximum Power Point Tracking system

V. Rajguru, K. Gadge, Soham Karyakarte, Supriya Kawathekar, Vishnu P. Menon
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引用次数: 5

Abstract

In future, solar energy will be an important energy source as it is renewable in nature. A solar cell being the smallest energy unit of any solar power system, an array of such solar cells constitutes a solar panel. The output of a solar panel follows a nonlinear current voltage characteristic which depends primarily on irradiance, temperature and load connected. A distinct point for fixed atmospheric conditions for which maximum power is extracted from the panel is the Maximum Power Point(MPP). A number of constraints are associated with installing, operating and thus studying the behaviour and designing a power system for solar panels. This paper thus discusses about the design of prototype indoor solar panel simulator along with the design of a Maximum Power Point Tracking (MPPT) System. Using this design efficiently, a large range of panels for various dynamic atmospheric conditions can be simulated. Various MPPT algorithms can be tested and analysed for their performance in actual solar power systems. The entire system consists of DC DC converter, a driver for the MOSFET, Voltage and Current Sensors, microcontroller, a DC programmable source and GUI on Visual Basic. Selection for each component is explained. The system sequential operation, flow of power and communication between various components is elaborated. Lastly, implementation results are discussed where Incremental Conductance MPPT algorithm is tested for a sample IV curve and thus Maximum Power Point is tracked.
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具有最大功率点跟踪系统的直流光伏发电系统仿真样机的设计与实现
在未来,太阳能将是一种重要的能源,因为它是可再生的。太阳能电池是任何太阳能发电系统中最小的能量单位,一组这样的太阳能电池构成了太阳能电池板。太阳能电池板的输出遵循非线性电流电压特性,主要取决于辐照度,温度和连接的负载。在固定大气条件下,从面板中提取最大功率的一个明显点是最大功率点(MPP)。安装、操作和研究太阳能电池板的性能以及设计太阳能电池板的电力系统都有很多限制。因此,本文讨论了室内太阳能板模拟器的原型设计以及最大功率点跟踪系统的设计。利用这种设计,可以有效地模拟各种动态大气条件下的大范围面板。各种MPPT算法可以在实际的太阳能发电系统中进行测试和分析。整个系统由直流变换器、MOSFET驱动、电压和电流传感器、微控制器、直流可编程源和Visual Basic图形用户界面组成。解释了每个组件的选择。阐述了系统的顺序操作、电源流向和各部件之间的通信。最后,讨论了实现结果,其中增量电导MPPT算法对样本IV曲线进行了测试,从而跟踪了最大功率点。
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