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Auto Transfer Switch (ATS) System on PLN and Genset Using DSE 4520 MKII Module Ryan Wicaksono
INAJEEE (Indonesian Journal of Electrical and Electronics Engineering) Vol. 5 No. 2 (2022)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Negeri Surabaya

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.26740/inajeee.v5n2.p56-60

Abstract

Energi listrik merupakan energi utama yang digunakan hampir di seluruh aktivitas dan kehidupan manusia, baik pada sektor perumahan, perkantoran dan industri. Semakin banyaknya penggunaan energi listrik, tentu akan timbul berbagai permasalahan terhadap pasokan listrik. Permasalahan yang sering terjadi yaitu terkait kontinuitas pelayanan listrik dan buruknya kualitas daya yang disalurkan ke konsumen. Oleh karena itu, alat ini bertujuan untuk mengatasi apabila pasokan energi listrik mengalami gangguan atau padam dengan menggunakan DSE 4520 MKII. Dengan sistem Auto Transfer Switch (ATS) dapat melakukan backup daya apabila pasokan listrik mengalami gangguan. Dengan sumber listrik utama dari PLN dan Genset sebagai backup apabila PLN mengalami gangguan. Hasil dari pembuatan alat ini menujukkan bahwa sistem ATS dapat bekerja bengan baik dan dapat beroperasi secara otomatis maupun manual.
MPPT (Maximum Power Point Tracker) System in PLTS And Micro hydro Based on IoT (Internet of Things) Ryan Wicaksono
INAJEEE (Indonesian Journal of Electrical and Electronics Engineering) Vol. 5 No. 2 (2022)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Negeri Surabaya

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.26740/inajeee.v5n2.p50-55

Abstract

Energi listrik dari pembangkit yang memanfaatkan pergerakan suatu benda. Seiring berjalannya waktu telah muncul inovasi pembangkit listrik yang ramah lingkungan. Salah satunya dengan memanfaatkan energi air dan energi cahaya matahari (surya). Energi air dapat dimanfaatkan untuk menggerakkan turbin pada mikrohidro, sedangkan energi surya dimanfaatkan untuk menyuplai solar cell. Mikrohidro dan solar cell dapat digabungkan menjadi satu sehingga menciptakan solusi yang lebih efektif bernama pembangkit hybrid. Namun rata-rata daya output yang keluar dari mikrohidro dan solar cell tidak dapat maksimal. Jadi untuk mengatasi hal tersebut kita perlu membuat sistem pengontrolan agar mendapatkan daya output yang maksimal, alat pengontrolan ini dinamakan Maximum Power Point Tracker (MPPT). Tegangan dan arus yang masuk maupun keluar dari MPPT dapat dimonitoring secara realtime menggunakan smartphone berbasis Internet of Things (IoT).    
Analysis of Transformer Protection Systems Using Smart Relays for Electrical Energy Stability Yuli Prasetyo; Dimas Nur Prakoso; Ryan Wicaksono; Budi Triyono; Santi Triwijaya
International Journal of Science, Engineering, and Information Technology Vol 7, No 02 (2023): IJSEIT Volume 07 Issue 02 29 July 2023
Publisher : Universitas Trunojoyo Madura

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.21107/ijseit.v7i02.20337

Abstract

A transformer is an electrical device that is used to change the voltage from one level to another in order to transfer electrical energy from one place to another. One of the main benefits of a transformer is to reduce power loss in the electrical network. Transformers can be used to stabilize the electric voltage and keep the electric voltage within safe limits. The protection system on the transformer is very important to prevent damage or failure to the transformer which can cause disruption of the electricity supply or even fire. This protection will work to cut off electrical connections and prevent damage to the transformer. Overload interference occurs if the current read on the Smart Relay LCD is more than 10 A so that the contactor will work after a disturbance of 5 seconds and the green indicator light will turn off. Whereas for Overheat interference on the transformer if the temperature exceeds 450C then the contactor will work to turn off the system with a duration of 1-2 seconds then the green indicator light and the system will OFF. The voltage drop disturbance occurs if the voltage read on the Smart Relay LCD is less than 15 kV on the primary side of the transformer and less than 300 V on the secondary side of the transformer so that the contactor will work to cut off the voltage after a disturbance occurs for 8-10 seconds then the green indicator light will turn off.
Peningkatan Keselamatan Gedung melalui Pemeriksaan MEP dalam Proses Sertifikat Laik Fungsi (SLF) Yuli Prasetyo; Basuki Winarno; Kumala Mahda H; Ryan Wicaksono; R. Oktav Yama; Narava Kansha Putra P
JURNAL PENGABDIAN MASYARAKAT INDONESIA Vol. 4 No. 3 (2025): Oktober : Jurnal Pengabdian Masyarakat Indonesia (JPMI)
Publisher : Lembaga Pengembangan Kinerja Dosen

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.55606/jpmi.v4i3.6040

Abstract

This activity begins with checking the mechanical, electrical, and plumbing (MEP) systems at the Gunung Mas Building in Madiun City, to assist in the process of issuing a Certificate of Functional Worthiness (SLF). The inspection included electrical power capacity, main distribution panels (MDP and SDP), lightning protection systems, light fire extinguishers (APAR), and pipe or plumbing installations such as clean water channels, waste water channels, and rain drainage. The results showed that the installed power was 105 KVA from PLN, the distribution panel, and cable sizes generally met safety standards (SNI and IEEE). However, several problems were found such as a load imbalance exceeding 10%, the lack of measuring instruments on the panel, and cable sizes that needed to be adjusted to the rating of the protective device. Plumbing installations such as a clean water source with a 2000 liter roof tank, waste disposal to a septic tank, and rainwater channels to the city channel were still running well, although repairs were needed to the bathroom in the putty area. Overall, the building was declared suitable, with recommendations for improving load distribution, adjusting cable sizes, and routine maintenance.
Perancangan Time Synchronization Sebagai Alat Bantu Pengujian Intertrip Relay Distance Ryan Wicaksono; R Jasa Kusumo Haryo; Apriando Ravi Dwi Santoso; Endrik Dwi Wibowo; Pembri Ridho Hanafi
Jurnal JEETech Vol. 5 No. 2 (2024): Nomor 2 November
Publisher : Universitas Darul Ulum

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.32492/jeetech.v5i2.5206

Abstract

At the company PT. PLN (Persero) ULTG Madiun carried out many tests relay, one of which is intertrip testing relay distance. Intertrip testing relay distance is a test carried out between 2 (two) relay distance conducting bays in main substations that face each other. Intertrip testing relay distance must be done if replacement occursrelay, replacement of teleprotection equipment, changes to protection schemes, and changes to logic circuitsrelay which is related to the send or receive signal from the opposite substation. However, this test requires synchronization between two intertrip test tools relay distance at each substation. In this final project, it will be designed Time Syncronization As A Tool For Intertrip Relay Distance Testing, to make things easier for PT employees. PLN (Persero) ULTG Madiun when synchronizing two intertrip test equipment relay distance. All process control of this tool uses ESP32 Devkit V1. Meanwhile for displaying setting time for testing can be seen on the web assisted by GPS NEO-6M. The results obtained when testing the Dolopo by Ponorogo R and S phase distance intertrip relay were carried out at 12.00.00, experiencing a delay time of 0.0553 seconds when the PMT tripped. Meanwhile, the Dolopo by Ponorogo T phase distance intertrip relay test was carried out on 12.09.00 and experienced a delay of 0.0529 seconds when the PMT tripped. From two intertrip relay distance tests, the trip time delay is no more than 0.1 second.
Sistem Monitoring dan Kontrol Penjernih Greywater Bertenaga Photovoltaic Berbasis Internet of Things (IoT) Hanifah Nur Kumala Ningrum; Raden Jasa Kusumo Haryo; Ryan Wicaksono; Yudhi Rizstu Nurcahyanto; Kaisar Bintang Putra
Nucleus Journal Vol. 4 No. 2 (2025): November
Publisher : Universitas Darul Ulum

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.32492/nucleus.v4i2.4202

Abstract

Water pollution due to human activities causes high levels of household wastewater called greywater. To reduce the impact of water pollution from greywater, wastewater needs to be processed to be safer for the environment. By utilizing technology and independent energy sources from Photovoltaics, a system was created that can purify wastewater and can be controlled and monitored using the Internet of Things. The research entitled "Monitoring and Control System for Photovoltaic Powered Greywater Purifiers Based on the Internet of Things (IoT)" aims to monitor and control water to obtain processed wastewater that produces cleaner water quality. This system can monitor battery charging for pump sources on filters in real time using IoT integrated with an Android application. The way this tool works is by utilizing the ESP8266 nodeMCU as a communication intermediary, Arduino as the tool control center, relays for control, voltage sensors to detect battery and pump voltage, ACS712 sensors to detect charging and pump currents, turbidity and pH sensors to detect water conditions. The results of this research are that the system can monitor water conditions, voltage, and pump current when filtering while controlling the pump based on water conditions, as well as monitoring the charging voltage and current from the PV to the battery.
Perancangan dan Pengujian PLTS Off-Grid Portabel Berbasis IoT untuk Aplikasi Darurat Infrastruktur Transportasi Budi Triyono; Dimas Nur Prakoso; Yuli Prasetyo; Basuki Winarno; Ryan Wicaksono; Santi Triwijaya; Satrio Nugroho
Nucleus Journal Vol. 5 No. 1 (2026): May
Publisher : Universitas Darul Ulum

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.32492/nucleus.v5i1.5109

Abstract

Ketersediaan catu daya yang andal pada infrastruktur transportasi sangat penting untuk menjaga keselamatan, ketertiban, dan kontinambungan layanan, khususnya pada kondisi darurat ketika pasokan listrik dari jaringan terganggu. Penelitian ini bertujuan merancang dan menguji sistem Pembangkit Listrik Tenaga Surya (PLTS) off-grid portabel berbasis Internet of Things (IoT) sebagai sumber daya darurat untuk infrastruktur transportasi berkelanjutan. Metode penelitian menggunakan pendekatan rekayasa sistem yang meliputi studi literatur, perancangan perangkat keras, integrasi sistem monitoring IoT, perakitan prototipe, serta pengujian laboratorium dan lapangan. Sistem yang dikembangkan terdiri atas tiga panel surya dengan total kapasitas 300 Wp, baterai lithium 12 V 100 Ah, solar charge controller PWM 20 A, inverter 1000 W, serta dashboard monitoring berbasis Ubidots. Hasil pengujian menunjukkan bahwa tegangan keluaran panel surya berada pada rentang 19,5–20,5 V dengan daya tertinggi mencapai 89,3 W pada pukul 11.00. Tegangan keluaran solar charge controller relatif stabil pada rentang 13,37–13,43 Vdc selama proses pengisian. Pada pengujian baterai saat pelepasan beban, tegangan menurun dari 13,46 Vdc menjadi 13,37 Vdc, diikuti penurunan tegangan AC inverter dari 205 Vac menjadi 198 Vac. Sistem IoT berhasil menampilkan parameter kelistrikan secara real-time, meliputi tegangan, arus, daya, status charging-discharging, dan state of charge baterai. Hasil penelitian menunjukkan bahwa sistem yang dikembangkan layak digunakan sebagai solusi catu daya darurat yang portabel, efisien, dan mudah dipantau