Hafidah Rahmawati, Sheila (2025) Perancangan Fault Detection pada 1 Row Photovoltaic Module Menggunakan Sensor Magnetic Hall Effect Berbasis Bluetooth. S1 thesis, Fakultas Teknik Universitas Sultan Ageng Tirtayasa.

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Abstract

This study examines the use of solar panels as a potential renewable energy source due to the abundant availability of solar energy. However, solar cells often encounter issues such as cracks, damage during shipping, and micro-defects that are difficult to detect. To address these issues, this research developed a defect detection tool on photovoltaic module using a KY-024 magnetic hall effect sensor module connected via Bluetooth. The sensor works by detecting the magnetic field on the busbar carrying electric current. The device consists of several components, including an ESP32-C3 as the microcontroller and a Bluetooth HC-05 module for transmitting data to a laptop via the Data Streamer feature in Microsoft Excel. Testing was conducted once under indoor conditions and repeated five times in outdoor conditions, specifically from 11 a.m. to 3 p.m. The results indicate that this tool is able detect and measure the magnetic field on a single row of solar modules. This study analyzes that two degraded busbars were identified in cell 4, resulting in uneven current distribution within the cell. The magnetic field strength difference between normal and degraded busbars ranged from 0,6 to 0,8 x 10^-3 μT. The highest magnetic field detected in the abnormal cell was 3,3 x 10^-3 μT, while the lowest was 1,2 x 10^-3 μT. This study confirms that higher current flow corresponds to a stronger detected magnetic field.

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