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RANCANG BANGUN MESIN PEMBANGKIT LISTRIK TANPA BBM BERKAPASITAS 3000 WATT DENGAN MEMANFAATKAN PUTARAN FLYWHEEL Razali Razali; Stephan Stephan
Jurnal Media Elektro Vol 6 No 2 (2017): OKTOBER 2017
Publisher : Universitas Nusa Cendana

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (385.365 KB) | DOI: 10.35508/jme.v0i0.585

Abstract

Akhir-akhir ini, kebutuhan energi meningkat tetapi ketersediaan sangat terbatas. Oleh karena itu, sangat penting untuk melakukan penelitian lebih lanjut energi alternatif. Generator adalah salah satu energi alternatif yang digunakan oleh masyarakat, tapi itu memiliki kekurangan seperti ketidakstabilan tegangan dan rendah efisiensi generator. Berdasarkan isu-isu tersebut, sehingga kami membuat flywheel aplikasi dalam generator listrik, yang bertujuan untuk menghasilkan suatu konsep efisiensi daya meningkat, menstabilkan tegangan keluaran Generator dan mulai proses pembangkit listrik. Proses pembuatan mesin aplikasi flywheel generator mulai dari perancangan mekanik flywheel, mencari jumlah rotasi per menit dari generator (dengan percobaan), menemukan elemen mesin yang menggunakan (poros, bantalan dan roda gila), nilai output generator. dari hasil desain mesin adalah diperlukan maksimal 2.5 KW - 3 KW dengan 3000 rpm yang diberikan motor listrik dengan sistem transmisi yang menggunakan balt, massa roda gila 60 kg x 2 kg dan daya output maksimum dari generator 3 KW.
Implementation of an IoT-Based Control and Monitoring System for Neon Box Conditions in the Electrical Engineering Building Hikmatul Amri; Zulkifli Zulkifli; Stephan Stephan; Hardi B; Ilham Haris; Azzahra Zulaika; Riski Kurniansyah; Jefri Lianda; Marzuarman Marzuarman
PROtek : Jurnal Ilmiah Teknik Elektro Vol 13 No 2 (2026): Protek : Jurnal Ilmiah Teknik Elektro
Publisher : Program Studi Teknik Elektro Universitas Khairun

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.33387/protk.v13i2.11082

Abstract

The implementation of an Internet of Things (IoT)-based control and monitoring system for the neon box at the Electrical Engineering Department Building aims to improve operational efficiency, installation safety, and the effectiveness of outdoor lighting maintenance. As an information medium and building identity, the neon box requires real-time monitoring of power, voltage, current, light intensity, and operational status. In this study, a system was designed and implemented using a NodeMCU ESP8266 microcontroller as the main controller, a PZEM-004T sensor to measure voltage, current, and power, a TSL2561 lux sensor to read the light intensity produced by the neon box, and a relay module as an actuator to control the neon box lamp. The Blynk IoT platform is used as the interface to display monitoring data and control the neon box remotely. The system is capable of sending data periodically to the server and displaying information such as voltage, current, power, energy, and illumination levels through a digital dashboard, allowing users to monitor the neon box condition at any time via a smartphone. In addition to monitoring functions, the relay module integrated with the IoT system enables operators to remotely turn the neon box on or off through the Blynk IoT application. The Blynk IoT interface successfully displays four main parameters: voltage, electrical power, lumen, and neon box status at the Electrical Engineering Building. The PZEM-004T sensor achieved an average reading error of 0.66% for voltage and 2.53% for current, while the TSL2561 sensor had an average error of 1.42%. The system can detect lamp failure through combined voltage and power readings, with a response time of 0.856 seconds on the Blynk IoT application, which is influenced by internet network quality.