DESIGN OF TURBINE SUPERVISORY INSTRUMENT PROTOTYPE BASED ON INTERNET OF THINGS
DOI:
https://doi.org/10.31963/elekterika.v23i1.6304Keywords:
Instrument, Spped, Temperature, Turbine, VibrationAbstract
Internet of Things-based Turbine Monitoring System is composed of main components including sensors, controllers, alarms and interface applications for monitoring parameters. The sensors used are LM393 IR speed sensor, SW420 Vibration Sensor and DHT11 Temperature Sensor. While the controller used is Wemos D1. Output Alarm uses the Buzzer and the Thingspeak platform as a medium for monitoring the measurement results. The test results that the author can convey are that the Internet Of Things-based Turbine Supervisory Instrument Simulator has been functioning properly. For testing the speed and temperature sensors, they have been compared with standard measuring instruments. Through system testing in the time range of 16.05 to 16.11, we found speed measurement data from 0 to 4425 rpm, vibration measurement data from 0 to 734,401 microseconds or 0.7 seconds and temperatures from 28.6 degrees Celsius to 33 degrees Celsius. The alarm is activated according to the setpoint specified in the program, namely over speed alarm at 2000 rpm, over vibration alarm at 100,000 microseconds and over heat alarm at 38 degrees Celsius. As for the shortcomings that exist in order to be corrected in the development of the system in the future.References
[1] B.F.Mahendra, S.Mulyanto, Prihastono, “Sistem Monitoring Prototype Energi Listrik Hybrid menggunakan Panel Surya, Turbin Angin & Piezoelektrik Diatas Kapal”, Publikasi Ilmu Teknik, Teknologi Kebumian dan Ilmu Perkapalan, vol.3 no.4, 2025.
[2] M. Zaini, S. Safrudin, and M. Bachrudin, "Perancangan sistem monitoring tegangan, arus dan frekuensi pada pembangkit listrik tenaga mikrohidro berbasis IoT," TESLA, vol. 22, no. 2, pp. 139-150, Nov. 2020.
[3] A. Akhwan, B. Gunari, S. Sunardi, and W. A. Wirawan, "Rancang bangun pembangkit listrik tenaga mikrohidro (PLTMH) Politeknik Perkeretaapian Indonesia Madiun," Eksergi: Jurnal Teknik Energi, vol. 17, no. 1, pp. 15-24, 2021. S.
[4] Aida, S. Sahrul, T. Lety, and T. Tahdid, "Prototipe pembangkit listrik tenaga mikro hidro (PLTMH) turbin Pelton kapasitas 300 watt kajian debit dan arah aliran pada alat," Prosiding SENIATI, vol. 5, no. 4, pp. 118-122, 2019.
[5] H. Hamira, A. I. Pawelloi, R. Rudy, and M. I. Halim, "Pengaruh jumlah sudu terhadap tegangan output pada pengujian turbin Pelton prototipe PLTMH," in Seminar Nasional Teknik Elektro dan Informatika (SNTEI), vol. 9, no. 1, pp. 53-58, 2023.
[6] I. P. A. Wiranata, I. G. N. Janardana, and I. W. A. Wijaya, "Rancang bangun prototype pembangkit listrik tenaga mikro hidro menggunakan turbin cross-flow," Spektrum, vol. 7, no. 4, 2020.
[7] I. G. N. Saputra, L. Jasa, and I. W. A. Wijaya, "Pengaruh jumlah sudu pada prototype PLTMH dengan menggunakan turbin Pelton terhadap efisiensi yang dihasilkan," Jurnal SPEKTRUM, vol. 7, no. 4, 2020.
[8] J. Lambert, R. Monahan, and K. Casey, "Power consumption profiling of a lightweight development board: Sensing with the INA219 and Teensy 4.0 microcontroller," Electronics, vol. 10, no. 7, p. 775, 2021.
[9] Z. B. Abilovani, W. Yahya, and F. A. Bakhtiar, "Implementasi protokol MQTT untuk sistem monitoring perangkat IoT," Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer, vol. 2, no. 12, pp. 7521-7527, 2018.
[10] A. E. Elwakeel, “A smart automatic control and monitoring system for environmental control in poultry houses integrated with earlier warning system,” Sci. Rep., vol. 15, no. 1, p. 31630, Aug. 2025
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