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Design of Monitoring Battery Solar Power Plant and Load Control System based Internet of Things

Rancang Bangun Sistem Monitoring Daya Baterai Pembangkit Listrik Tenaga Surya (PLTS) dan Kontrol Beban Berbasis Internet of Things

*Riza Alfita  -  Jurusan Teknik Elektro, Fakultas Teknik, Universitas Trunojoyo Madura, Indonesia
Koko Joni  -  Jurusan Teknik Elektro, Fakultas Teknik, Universitas Trunojoyo Madura, Indonesia
Fajar Dwika Darmawan  -  Jurusan Teknik Elektro, Fakultas Teknik, Universitas Trunojoyo Madura, Indonesia
Open Access Copyright (c) 2021 TEKNIK

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Abstract
Internet of Things technology in this research is utilized on solar power plant (Case Study: Electrical Engineering Department of Trunojoyo Madura University) as a battery power monitoring and load control system. All of these systems were built to make it easier for users to manage the power consumption while preventing battery damage so that lifetime can last longer and the use of PLTS than more optimal. All of these systems are designed to use several integrated components with their respective functions, including Raspberry as a data processing, smartphone as an interface, and sensors actuator as input-output. From the results of the monitoring accuracy test, the average error value is 1.56%. After ensuring the system has a high level of accuracy, The charge-discharge test is conducted in real-time for 7 days, which shows that the system works according to the research objectives as evidenced by the nothingness of power consumption exceeding the SOC standard limit battery used by 30%. Meanwhile, for the control system test, the wifi connection has the fastest average delay for 10,30 s, provider A 11,17 s, and provider B 12,60 s.
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Keywords: Internet of Things; monitoring; control; power; solar power plant

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  1. Abdi, H., Ivatlo, B. M., Javedi, S., Khodaei, A. R., & Dehnavi, E. (2017). Energy Storage Systems. In G. B. Gharehpetian & S. M. M. Agah (Eds.), Distributed Generation Systems (333–368). Oxford: Butterworth-Heinemann
  2. Aritonang, C. L., Maison, & Hais, Y. F. (2020). Sistem Monitoring Tegangan, Arus, dan Intensitas Cahaya pada Panel Surya dengan Thingspeak. Jurnal Engineering, 2(1), 11–24
  3. Fachri, M. R., Sara, I. D., & Away, Y. (2015). Pemantauan Parameter Panel Surya Berbasis Arduino secara Real Time. Jurnal Rekayasa Elektrika, 11(4), 123
  4. Fadlur, R., & Iqbal, M. (2016). Implementasi Iot Dalam Rancang Bangun Sistem Monitoring Panel Surya Berbasis Arduino. Prosiding Seminar Nasional Teknologi Dan Informatika 3, 189–196
  5. Fitriandi, A., Komalasari, E., & Gusmedi, H. (2016). Rancang Bangun Alat Monitoring Arus dan Tegangan Berbasis Mikrokontroler dengan SMS Gateway. Jurnal Electrician, 10(2), 87–98
  6. International Telecommunication Union. (2012). An overview of internet of things (ITU-T Y.20). Geneva: International Telecommunication Union
  7. Salkind, A. J. S., Hammel, R. O., Cannone, A. G., & Trumbore, F. A. (2001). Valve Regulated Lead-Acid Batteries. In D. Linden & T. B. Reddy (Eds.), Handbook of Batteries Third Edition (24.1-24.46). New York: McGraw-Hill
  8. Mahanta, D., Ahmed, M., & Bora, J. (2013). A study of Bandwidth Management in Computer Networks. International Journal of Innovative Technology and Exploring Engineering (IJITEE), 2(2), 69–73
  9. Margana. (2019). Solar Tracking Dual - Axis Berbasis Arduino Uno dengan menggunakan Lensa Fresnel guna Meningkatkan Efisiensi Pengfokusan Cahaya Matahari. Jurnal Teknik Energi, 15(2), 77–80
  10. Muzawi, R., Efendi, Y., & Sahrun, N. (2018). Prototype Pengendalian Lampu Jarak Jauh Dengan Jaringan Internet Berbasis Internet of Things(IoT) Menggunakan Rasberry Pi 3. Jurnal INFORM, 3(1), 46–50
  11. Nugraha, I. M. A., Giriantari, I. A. D., & Kumara, I. N. S. (2013). Studi Dampak Ekonomi dan Sosial PLTS Sebagai Listrik Pedesaan Terhadap Masyarakat Desa Ban Kubu Karangasem. Prosiding Conference on Smart-Green Technology in Electrical and Information Systems, A-010, 43–46
  12. Pasha, S. (2016). Thingspeak Based Sensing and Monitoring System for IoT with Matlab Analysis. IJNTR (International Journal of New Technology and Research), 2(6), 19–23
  13. Patton, E. W., Tissenbaum, M., & Harunani, F. (2019). MIT App Inventor : Objectives, Design, and Development. In S. C. Kong & H. Abelson (Eds.), Computational Thinking Education (pp. 31–49). Singapore: Springer
  14. Rivaldo, R., Bustami, I., & Siswanto, A. (2020). Perancangan Keamanan Pintu Gudang Menggunakan Rfid Dan Kamera Berbasis Raspberry Pi (Studi Kasus : Gudang V-Tech Jambi). Jurnal Ilmiah Mahasiswa Teknik Informatika, 2(2), 96–106
  15. Sugiyono. (2011). Pendekatan Kuantitatif, Kualitatif dan R&D. Bandung: Alpabeta
  16. Suryawinata, H., Purwanti, D., & Sunardiyo, S. (2017). Sistem Monitoring Pada Panel Surya Menggunakan Data Logger Berbasis Atmega 328 Dan Real Time Clock DS1307. Jurnal Teknik Elektro, 9(1), 30–36

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