Monitoreo de instalación fotovoltaica usando bus CAN

Revista de Energías Renovables Pub Date : 2020-12-31 DOI:10.35429/JRE.2020.12.4.32.40

Carlos Alberto Luján-Ramírez, Jesús Sandoval-Gío, Mario Renán Moreno-Sabido, José Ramón Atoche-Enseñat

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Abstract

This paper addresses the problem of developing a system to monitor the behavior of solar modules using a CAN network. It is desired to measure current, voltage, and temperature under different operating conditions of a photovoltaic installation, in order to obtain the necessary information to later use it to determine its energy efficiency. In this work, current, voltage and temperature data are transmitted over a CAN network based on devices from the Microchip® family of microcontrollers. The network design is made up of slave nodes in charge of carrying out data acquisition and leading them to a CAN Central master node. This master node receives them, oversees timing tasks and connects via serial port to a personal computer. The programming environment used is MikroC® for dsPIC®. The process of sending the data can be observed through the MikroC® USART terminal, these are saved in a .txt file for later analysis with a scientific software. Experimental tests carried out with a group of commercial panels are reported under two operating conditions: short circuit and open circuit. The graphs are shown, and to validate the information provided by the acquired data, the relationships between the monitored variables are verified considering the knowledge obtained from the literature.

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本文讨论了利用CAN网络开发太阳能组件行为监控系统的问题。需要测量光伏装置在不同工作条件下的电流、电压和温度，以便获得必要的信息，以便以后使用它来确定其能源效率。在这项工作中，电流，电压和温度数据通过基于Microchip®系列微控制器的设备的CAN网络传输。网络设计由负责数据采集的从节点组成，并将其引导到CAN中心主节点。这个主节点接收它们，监督计时任务，并通过串行端口连接到个人计算机。使用的编程环境是MikroC®for dsPIC®。发送数据的过程可以通过MikroC®USART终端观察，这些数据保存在。txt文件中，供以后用科学软件分析。本文报道了一组商用面板在短路和开路两种工况下进行的试验。如图所示，为了验证所获取的数据所提供的信息，考虑从文献中获得的知识，验证被监测变量之间的关系。

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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Revista de Energías Renovables

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