Model PLTA Skala Kecil dengan Generator DC 24 Volt
DOI:
https://doi.org/10.55606/jurritek.v4i2.6094Keywords:
24-volt DC generator, energy efficiency, modeling, renewable energy, small scale generatorAbstract
Small-scale Hydropower Plants (HPP) are an effective renewable energy alternative to meet electricity needs in remote areas. This study aims to develop and test a small-scale HPP model using a 24-volt DC generator as the main component. The development process involves analyzing water flow rates, head height, and the conversion of mechanical energy into electrical energy. The 24-volt DC generator was chosen due to its availability, high efficiency, and ease of integration with energy storage systems.This small-scale HPP model is expected to provide a reliable electricity solution for households or small communities, particularly in areas not yet connected to conventional power grids. This study also paves the way for further development, especially in optimizing design and utilizing more efficient components. With a generator capacity of 24 volts, the voltage produced will tend to be stable compared to a generator with a capacity of 12 volts. So that this study is able to provide an accurate impact given by the water discharge that drives the.
Downloads
References
Andrews, M. (2007). A survey of scheduling theory in wireless data networks. Wireless Communications, 143, 1–17.
Anggoro, B. (2014). Pembangkit listrik tenaga mikrohidro (PLTMH). Jakarta: Universitas Terbuka.
Arismunandar, W., & Djokosetyardjo, S. (1996). Penggerak mula: Mesin fluida dan mesin konversi energi. Jakarta: Pradnya Paramita.
Firmansyah, I. (2008). Studi pembangunan PLTMH Dompyong 50 kW di Trenggalek (Tugas akhir, Institut Teknologi Sepuluh Nopember).
Ibrahim, S. (2012). Energi baru dan terbarukan: Pembangkit listrik tenaga mikrohidro. Bandung: ITB Press.
Indra, Z. (2012). Analisis debit Sungai Munte dengan metode Mock. Jurnal Sipil Statik, 1(1), 34–38.
Khamid, A. (2015). Efisiensi generator DC pada sistem PLTMH skala rumah tangga. Jurnal Teknik Elektro, 4(2), 20–27.
Komariah, L., & Ramadhan, S. (2016). Analisis potensi mikrohidro sebagai energi listrik terbarukan di Indonesia. Jurnal Energi Terbarukan, 8(2), 78–89.
Putro, Y. S. S. (2015). Studi perencanaan PLTMH di Sungai Atei, Kalimantan Tengah (Skripsi, Universitas Brawijaya Malang).
Sugiyono. (2015). Teknologi mikrohidro dan implementasinya di Indonesia. Jurnal Rekayasa Energi Terbarukan, 12(1), 45–52.
Sutaryo, B. (2020). Desain dan pengujian sistem mikrohidro dengan turbin overshot. Jurnal Energi dan Kelistrikan, 15(3), 120–129.
Syamsuddin, A. (2009). Pembangkit listrik tenaga mikrohidro: Konsep, desain, dan implementasi. Jakarta: Gramedia Pustaka Utama.
Xu, Y., & Fischione, C. (2012). Real-time scheduling in LTE for smart grids. In Proceedings of the 5th International Symposium on Communications, Control and Signal Processing (pp. 2–4).
Yulianto, D., & Sari, M. (2018). Pemanfaatan energi terbarukan di daerah terpencil. Jurnal Teknologi Energi, 9(1), 55–62.
Zainuddin, I. (2017). Studi kelayakan pembangunan PLTMH di pedesaan. Jurnal Teknik Energi, 10(3), 133–145.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2025 JURAL RISET RUMPUN ILMU TEKNIK
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
_001.jpg)
