基于物联网的太阳能发电厂跟踪器升级及MPPT控制

Proceedings of the 2nd International Conference on Applied Science, Engineering and Social Sciences Pub Date : 1900-01-01 DOI:10.5220/0009881602190223

D. Notosudjono, H. Samaulah, Muhamad Nopriansy, Bagus Dwi Ramadhon, D. Fiddiansyah, Asri

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引用次数: 0

摘要

:通过在太阳和太阳能板之间形成垂直的轴来最大限度地吸收阳光。需要一种可以在太阳能电池板系统上实现的可以跟随太阳运动的方法。在本设计中，系统采用光二极管传感器(LDR)作为光探测器，Atmega238P-PU微控制器作为命令逻辑存储，伺服电机作为移动器，利用物联网(IoT)实现太阳能电池板的位置错位。在使用双轴太阳能电池板跟踪器运行11小时的太阳能电池板测试中，输出功率为9.4 W，通过MPPT控制电池后，平均输出功率为10.6 W。与使用静态太阳能电池板方法相比，其功率仅为6.8瓦，通过MPPT控制电池后，其平均功率为9.25瓦

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Solar Power Plant Tracker Upgrade and MPPT Control with Internet of Things

: To maximize sunlight absorption by forming a perpendicular axis between the sun and the solar panel. A method which could be implemented on the solar panel system that could follow the sun’s movement is needed. On this design, the system uses a light diode sensor (LDR) that functions as the light detector, an Atmega238P-PU microcontroller as the command logic storage, and a servo motor as a mover to dislocate the position of the solar panel with Internet of Things (IoT). In the solar panel test which runs for 11 hours using the dual-axis solar panel tracker has yield a power of 9.4 W and after passing the MPPT control battery, it gives an average of 10.6 W. Compared to using a static solar panel method, it only yields a power of 6.8 Watt, and after passing the MPPT control battery, it gives an average power of 9.25 W.w

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Proceedings of the 2nd International Conference on Applied Science, Engineering and Social Sciences

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