Pemanfaatan Tenaga Surya Dan Iot Untuk Menjaga Kualitas Air Dalam Budidaya Ikan Berbasis Web
DOI:
https://doi.org/10.56795/fortech.v6i2.6107Keywords:
Fish Farming, Water Quality, Internet of Things (IoT), Solar EnergyAbstract
Water turbidity is a critical factor affecting fish growth and health in aquaculture, thus requiring an efficient and automated water quality monitoring system. This study developed an Internet of Things -based system powered by solar energy to monitor and control water quality in real-time. The system uses an ESP32 microcontroller integrated with turbidity, pH, and temperature sensors, as well as water level control, automatic feeder, and an INA219 power monitoring module. Sensor data is transmitted via Wi-Fi to a Firebase-based web dashboard. When turbidity exceeds 25 NTU or pH falls outside the 6.5–8.5 range, the system automatically activates a solenoid valve to discharge dirty water, runs a pump to refill clean water, and injects a pH balancing solution, while sending notifications to the user. Test results show an average response time of 2–3 seconds, with sensor accuracy of ±0.2 for pH, ±0.5°C for temperature, and ±5 NTU for turbidity. The system demonstrates high energy efficiency, consuming approximately 12.6 Watts, with solar panel voltage maintained between 12.9–13.5 Volts, and battery capacity stable at 87–95%. Data transmission is stable, with synchronization to the server occurring in less than 1 second. With reliable performance, quick responsiveness, and energy efficiency, this system proves to be effective in supporting sustainable fish farming, especially in areas with limited access to conventional electricity.
References
R. Pramana, “Jurnal Sustainable: Jurnal Hasil Penelitian dan Industri Terapan,” vol. 07, no. 01, 2018.
M. Irwansyah and D. Istardi, “Pompa Air Aquarium Menggunakan Solar Panel”.
S. Novianto, S. Supriyadi, A. A. Adji, and M. F. Ammar, “Pembuatan Aerator Dengan Menggunakan Tenaga Surya Untuk Pemeliharaan Ikan Pada Kolam Berdimensi Kecil,” jamin, vol. 4, no. 1, Apr. 2022, doi: 10.25105/jamin.v4i1.9652.
L. C. Han, “Automatic Aquarium Water Change System With Real Time Monitoring Through IoT,” vol. 7, no. 2, 2023.
B. D. Waluyo, M. A. Rahman Sembiring, N. Sinaga, A. A. Lubis, and S. V. Br Tarigan, “Sistem Monitoring Plts Berbasis Iot Sebagai Media Pembelajaran,” JTIKP, vol. 11, no. 1, Jun. 2024, doi: 10.24114/jtikp.v11i1.60282.
K. Masykuroh, F. T. Syifa, and F. A. Pamungkas, “Rancang Bangun Prototipe Pemantau Kekeruhan Air dan Pengaturan Pakan Ikan pada Akuarium Menggunakan Nodemcu ESP32,” J. Telecomm. Electr. Control Eng., vol. 5, no. 1, pp. 31–40, Jan. 2023, doi:
20895/jtece.v5i1.917.
M. R. Rasyid, Nurhadiyah, and M. F. Rustan, “Sistem MonitoringKualitas AirPembudidayaan Ikan Tawar MenggunakanESP 32 dan ESP 8266,” JASEE.
T. Rikanto, “Sistem Monitoring Kualitas Kekeruhan Air Berbasis Internet Of Thing,” JF, vol. 11, no. 2, pp. 87–90, Aug. 2021, doi: 10.37859/jf.v11i2.2714.
R. Pramana, “Perancangan Sistem Kontrol dan Monitoring Kualitas Air dan Suhu Air Pada Kolam Budidaya Ikan,” sustainable, vol. 7, no. 1, pp. 13–23, Aug. 2018, doi: 10.31629/sustainable.v7i1.435.
A. B. Pulungan, A. M. Putra, H. Hamdani, and H. Hastuti, “Sistem Kendali Kekeruhan Dan Ph Air Kolam Budidaya Ikan Nila,” ELKHA, vol. 12, no. 2, p. 99, Oct. 2020, doi: 10.26418/elkha.v12i2.40688.
R. Syahrial, “Prototipe Sistem Monitoring Dan Controlling Suhu, Ketinggian Dan Kualitas Air Menggunakan Esp32 Berbasis Web,” 2022.
