Doris Chasokela*, Pilate Paringa, Kumbulani Matshe and Pedzisai Mazhanga

National University of Science and Technology, Faculty of Science and Technology Education, Department of Technical and Engineering Education and Training, Bulawayo, Zimbabwe

*Corresponding Author: Doris Chasokela, National University of Science and Technology, Faculty of Science and Technology Education, Department of Technical and Engineering Education and Training, Bulawayo, Zimbabwe.

Received: May 27, 2024; Published: June 10, 2024

Abstract

Although current motors are designed near saturation points for improved core material use, ancient motors had robust designs. Increasing the V/Hz ratio causes air gap flux saturation, which causes motor heating and, in turn, insulation breakdown, which causes the electric motor winding to burn. To prevent overheating, some motors use thermistors and thermal overload protection. The motor windings can burn out because the time it takes to utilize the bimetallic strip technique to shut off the power supply is sufficient to do so. The project's goals were to connect the ATmega328P to the current sensor, voltage sensor, and motor relay that controls the induction motor. It also aimed to design software for the ATmega328P that processed input signals from the ACS712CTR-30A-T current and voltage sensors to generate the desired output signal.

Keywords: Single-phase Induction Motor; Artificial Intelligence; Arduino Uno Technology

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Citation

Citation: Doris Chasokela., et al. “Monitoring and Controlling a Single-phase Induction Motor using Arduino Uno Technology".Acta Scientific Computer Sciences 6.6 (2024): 17-27.

Copyright

Copyright: © 2024 Doris Chasokela., et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.