Monitoring and Control of 3 Phase Electrical Energy Internet of Things (IoT) Based



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Submitted Mar 23, 2023
Published Jun 27, 2023
10.24018/ejece.2023.7.3.522

Abstract viewed = 413 times

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Monitoring the use of electrical energy is generally done by looking at the kWh meter on the installed panel. Power consumption can also be done by measuring directly on the network or electrical load using a Watt meter. Monitoring of 3-phase electrical energy needs to be monitored, especially to find out the amount of energy used in each phase, and on the other hand, it needs to be controlled so that energy use can be controlled, both for each phase or 3 phases. This study aims to design an IoT-based 3-phase electrical energy monitoring and control application. Data on the flow of electrical energy flowing to the load can be monitored from the android, and vice versa can be controlled by disconnecting and reconnecting the energy flow. The PZEM004T component is used as an energy flow sensor, buttons on the application function to disconnect and connect energy flows, and LCD12C and smartphones are used as monitoring devices. The Blynk application is equipped with several switch buttons used to control energy use, along with electronic device control. The data read by the tool can be retrieved and stored in Blynk using the superchart widget so that the operator can see previous history record data sent to emails that have been linked to the Blynk application according to the operator's wishes. The results of the research show that the research tool can display voltage, current, power, energy, and frequency data that can be displayed on a smartphone and LCD. The average error of the mains power compared to the reference meter is 0.02%.
Keywords: Control Energy IoT Monitoring

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  1. Habibi FN, Setiawidayat S, M. Mukhsim M. Alat Monitoring Pemakaian Energi Listrik Berbasis Android Menggunakan Modul PZEM-004T. Repository Universitas Widyagama Malang. https://repository.widyagama.ac.id/items/show/188.
     Google Scholar
  2. Biasrori R, Arimbawa IWA, I. Wedashwara IW. Sistem Pendukung Keputusan Konsumsi Listrik Dengan Implentasi IoT Dan Fuzzy Rule Minning. J. Inform. Dan Rekayasa Elektron., 2019; 2(1): 60. doi: 10.36595/jire.v2i1.91.
     Google Scholar
  3. Samsugi S, Kastutara D. Internet Of Things (IoT): Sistem Kendali Jarak Jauh Berbasis Arduino Dan Modul Wifi Esp8266. Pros. Semin. Nas. XII ?Rekayasa Teknol. Ind. Dan Inf. 2017 Sekol. Tinggi Teknol. Nas. Yogyak., p. 8, 2017.
     Google Scholar
  4. Priyanto, Setiawidayat S, Rofii F. Design and Build an IoT Based Prepaid Water Usage Monitoring System and Telegram Notifications. JEEE-U J. Electr. Electron. Eng.-UMSIDA, 2021; 5(2): 197?213. doi: 10.21070/jeeeu.v5i2.1527.
     Google Scholar
  5. Nurhadi A, Darlis D, Murti MA. Implementasi Modul Komunikasi LoRa RFM95W Pada Sistem Pemantauan Listrik 3 Fasa Berbasis IoT,? Ultima Comput. J. Sist. Komput., 2021; 13(1): 17?21. doi: 10.31937/sk.v13i1.2065.
     Google Scholar
  6. Yusuf MS, Priyandoko G, Setiawidayat S. Prototipe Sistem Monitoring dan Controlling HSD Tank PLTGU Grati Berbasis IoT. Jambura J. Electr. Electron. Eng., p. 10.
     Google Scholar
  7. Anwar S, Artono T, Fadli A. Pengukuran Energi Listrik Berbasis PZEM-004T. Proceeding Semin. Nas. Politek. Negeri Lhokseumawe, 2019; 3(1): 5.
     Google Scholar
  8. Permadi YY. Sistem Online Monitoring Besaran Listrik 3 Fasa Berbasis Single Board Computer BCM 8235.
     Google Scholar
  9. Handarly D, Lianda J. Sistem Monitoring Daya Listrik Berbasis IoT (Internet of Thing). JEECAE J. Electr. Electron. Control Automot. Eng., 2018; 3(2): 205-208. doi: 10.32486/jeecae.v3i2.241.
     Google Scholar
  10. Raafi?ul B, Iskandarianto FA, Darwito PA, Fadilah TN, Alam RAB, Adhim FA, Ash-Shiddieqy RH. Rancang Bangun Sistem Monitoring Tegangan, Arus, Dan Frekuensi Keluaran Generator 3 Fasa Pada Modul Mini Power Plant Departemen Teknik Instrumentasi. Jurnal AMORI, 2020; 1(2).
     Google Scholar
  11. Fajri F, Suhendi A, Fathonah IW. Rancang Bangun Website Untuk Monitoring Penggunaan Daya Listrik Tiga Fasa Berbasis Power Meter Di Gedung Deli Universitas Telkom. E-Proceeding Eng., 2021; 8(2): 1905.
     Google Scholar
  12. Hudan S. Rancang Bangun Sistem Monitoring Daya Listrik Pada Kamar Kos Berbasis Internet Of Things (IoT). J. Vol. 2019; 8(1): 919-99.
     Google Scholar
  13. Setiono A, Puranto P, Widiyatmoko B. Pembuatan Dan Uji Coba Data Logger Berbasis Mikrokontroler Atmega32 Untuk Monitoring Pergeseran Tanah. Jurnal Fisika Himpunan Fisika Indonesia, 2010; 10(2): 83-94.
     Google Scholar
  14. Berlianti R. Perancangan Alat Pengontrolan Beban Listrik Satu Phasa Jarak Jauh Menggunakan Aplikasi Blynk Berbasis Arduino Mega. J. Sain Energi Teknol. Ind., 2020; 5(1): 17-26.
     Google Scholar
  15. Prasetiyo EE, Ma?ruf F. Rancang Bangun Sistem Pemantauan Dan Pengendalian Beban Listrik Berbasis Internet Of Things(IoT). Pros. Semin. Nas. Apl. Sains Teknol. SNAST 2018, p. 11, 2018.
     Google Scholar
  16. Buwana DP, Setiawidayat S, Mukhsin M. Sistem Pengendalian Lampu Penerangan Jalan Umum (PJU) Melalui Jaringan Internet Berbasis Android. JOINTECS J. Inf. Technol. Comput. Sci., 2018; 3(3). doi: 10.31328/jointecs.v3i3.820.
     Google Scholar
  17. Kalosa MS, Setiawidayat S, Mukhsim M. Pengaruh Sistem Pentanahan Terhadap Arus Gangguan Tanah Pada Sister Distribusi 20 KV. Circuit J. Ilm. Pendidik. Tek. Elektro, 2020; 4(2): 138. doi: 10.22373/crc.v4i2.7067.
     Google Scholar