{"title":"基于Arduino Mega 2560,Triacs蓝牙和GSM的Swift自动传输开关","authors":"Marius Alembong, I. Essiet, Yanxia Sun","doi":"10.1109/SeFet48154.2021.9375773","DOIUrl":null,"url":null,"abstract":"A ceaseless supply of electricity is essential for all developmental sectors and even more important nowadays, as the globe evolves through a call for artificially intelligent systems in the fourth industrial revolution. Power interruptions lead to unpleasant human situations as well as great losses within all health, education, and industrial facilities requiring constant electricity. For this reason, we propose the design of an automatic transfer switch (ATS) for power transfer applications to maximize uptime. The ATS ensures the transfer of power between two power sources, hydroelectric and solar, during blackouts or power failures. The design is principally based on an Arduino Mega 2560, triacs, LEDs, as well as an LCD, SD card, Bluetooth, and GSM modules. The Arduino is powerful enough to support all the ATS modules and sustain the combined system processes required for the ATS’s automatic operation. Triacs, which are semiconductor switching devices, were utilized for high-speed switching between the two power supplies. The LEDs and LCD played a signalization role, indicating the state of the ATS at all times. Also, the SD card stores the system’s generated data whilst the Bluetooth modules ensure wireless connectivity between the ATS and a mobile device. The GSM module is for short messages (SMS). The results prove the functioning of the designed ATS, which ensures the transfer of power between two power sources with switching speeds less than 2.58 msec during blackouts or power failures. Furthermore, the ATS is a reliable, fast, and automatic system capable of protecting its internal components from surges. 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引用次数: 4
摘要
不间断的电力供应对所有发展部门都至关重要,在当今世界,随着第四次工业革命对人工智能系统的呼唤,电力供应变得更加重要。电力中断会导致不愉快的人类状况,并给所有需要持续供电的卫生、教育和工业设施造成巨大损失。因此,我们建议设计一种用于电力传输应用的自动转换开关(ATS),以最大限度地延长正常运行时间。ATS确保在停电或电力故障期间在水电和太阳能两种电源之间传输电力。该设计主要基于Arduino Mega 2560, triac, led以及LCD, SD卡,蓝牙和GSM模块。Arduino功能强大,足以支持ATS的所有模块,并维持ATS自动运行所需的组合系统进程。triac是一种半导体开关器件,用于两个电源之间的高速开关。led和LCD起到信号的作用,随时显示ATS的状态。此外,SD卡存储系统生成的数据,而蓝牙模块确保ATS与移动设备之间的无线连接。GSM模块主要用于发送短消息。实验结果证明了所设计的ATS的功能,在停电或断电情况下,可以保证两个电源之间的功率传输,切换速度小于2.58 msec。此外,ATS是一个可靠、快速和自动化的系统,能够保护其内部组件免受浪涌的影响。仿真结果表明,所提出的自动控制系统具有良好的应用前景。
Swift Automatic Transfer Switch based on Arduino Mega 2560,Triacs Bluetooth and GSM
A ceaseless supply of electricity is essential for all developmental sectors and even more important nowadays, as the globe evolves through a call for artificially intelligent systems in the fourth industrial revolution. Power interruptions lead to unpleasant human situations as well as great losses within all health, education, and industrial facilities requiring constant electricity. For this reason, we propose the design of an automatic transfer switch (ATS) for power transfer applications to maximize uptime. The ATS ensures the transfer of power between two power sources, hydroelectric and solar, during blackouts or power failures. The design is principally based on an Arduino Mega 2560, triacs, LEDs, as well as an LCD, SD card, Bluetooth, and GSM modules. The Arduino is powerful enough to support all the ATS modules and sustain the combined system processes required for the ATS’s automatic operation. Triacs, which are semiconductor switching devices, were utilized for high-speed switching between the two power supplies. The LEDs and LCD played a signalization role, indicating the state of the ATS at all times. Also, the SD card stores the system’s generated data whilst the Bluetooth modules ensure wireless connectivity between the ATS and a mobile device. The GSM module is for short messages (SMS). The results prove the functioning of the designed ATS, which ensures the transfer of power between two power sources with switching speeds less than 2.58 msec during blackouts or power failures. Furthermore, the ATS is a reliable, fast, and automatic system capable of protecting its internal components from surges. The proposed ATS is validated based on simulations, and the results show that the proposed ATS is promising.
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