Braking System Design with Electromagnetic Field Technology on Vehicles at Muhammadiyah University of Sidoarjo
Perencanaan Sistem Pengereman dengan Teknologi Medan Elektromagnetic pada Kendaraan Universitas Muhammadiyah Sidoarjo
DOI:
https://doi.org/10.21070/ups.8262Keywords:
electromagnetic, conventional braking, magnetic field, Braking, vehicleAbstract
The braking system is one of the main components in a vehicle that plays an important role in driving safety. Ts to design and develop an electromagnetic field-based brake system as an alternative to conventional brake systems. The system utilises the magnetic field generated by the solenoid to create braking force through the principle of electromagnetic induction. Simulation results show that the system is able to generate optimal braking force with faster response and higher energy efficiency. Prototypes tested on small-scale vehicles show improved braking performance with reduced braking distance compared to conventional brake systems. In addition, the system successfully reduced mechanical component wear and demonstrated good reliability However, the research also found challenges in the form of relatively high energy consumption and the need for more heat-resistant conductive materials. In conclusion, electromagnetic brake systems have great potential to improve the safety, efficiency and sustainability of transport in the future.
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References
P. T. Santoso et al., “RANCANG BANGUN ALAT OTOMATISASI PENGEREMAN,” vol. 19, no. September, pp. 225–232, 2024.
I. Teknologi and N. Malang, “PADA MOBIL LISTRIK,” vol. 08, pp. 156–168, 2024.
Dzikrullah dkk, “1. Analisa Gesekan Pengereman Hidrolis,” Pros. SNATIF, pp. 667–678, 2017.
H. Judul, “Otomatis Berbasis Fuzzy Pid Pada,” 2018.
A. R. Dayus, J. E. Hutagalung, and I. R. Harahap, “Penerapan Sistem Pengereman dan Parkir Mobil Listrik Menggunakan Sensor Ultrasonik Berbasis Arduino UNO,” J-Com (Journal Comput., vol. 2, no. 2, pp. 101–106, 2022, doi: 10.33330/j-com.v2i2.1728.
K. Diyanto and M. Anwar Satrio Andhy, “Pengembangan Sistem Pengereman Dan Catu Daya Sepeda Listrik Roda Dua,” 2023.
M. H. Pradipta, T. Sukmadi, and M. Facta, “Pengereman Dinamis Konvensional pada Motor Induksi Tiga Fasa,” J. Nas., vol. 3, pp. 1–7, 2014.
Abdulelektro, “Sistem Pengereman Regeneratif: Prinsip Kerja & Aplikasinya.” [Online]. Available: https://abdulelektro.blogspot.com/2021/04/sistem-pengereman-regeneratif-prinsip.html
M. Jhoni, O. Selviana, and S. Damayanti, “Menganalisis Gaya Lorentz dalam Sistem Listrik dan Magnetik,” Tarbiatuna J. Islam. Educ. Stud., vol. 4, no. 1, pp. 302–306, 2024.
H. R. Al Malik, “Elektromagnetik pada Kendaraan: Prinsip Kerja dan Komponennya,” Ksayd.com. [Online]. Available: https://ksayd.com/pada-kendaraan-prinsip-kerja-elektromagnetik-digunakan-pada-komponen/#respond
D. Handoyo and A. Rudiretna, “Prinsip umum dan pelaksanaan Polymerase Chain Reaction (PCR),” Unitas, vol. 9, no. 1, pp. 17–29, 2001.
F. Trinovat, “Rancang Bangun Sistem Pengereman Otomatis Dan Blind Spot Warning Pada Sepeda Motor,” UIN Alauddin Makassar, pp. 3–18, 2018.
M. Waruwu, “Metode Penelitian dan Pengembangan (R&D): Konsep, Jenis, Tahapan dan Kelebihan,” J. Ilm. Profesi Pendidik., vol. 9, no. 2, pp. 1220–1230, 2024, doi: 10.29303/jipp.v9i2.2141.
I. Maulana, I. P. Handayani, and A. Qurthobi, “Rancang Bangun Mini Plant Regenerative Braking SebagaiSumber Daya Listrik,” e-Proceeding Eng., vol. 3, no. 3, pp. 4943–4947, 2016.
A. Bintang Damara, A. Qurthobi, and K. Bani Adam, “Rancang Bangun Purwarupa Pengereman RegeneratifMenggunakan Motor Dc My1016,” e-Proceeding Eng., vol. 8, no. 5, pp. 5883–5889, 2021.
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