Jurnal Teknik Mesin dan Pembelajaran

This study aims to design and evaluate the performance of a portable motorcycle tire repair tool based on a nickel-chromium (Ni–Cr) heating element as an efficient solution for on-site tire patching. The device was developed using an engineering experimental approach, which included stages of design, prototype fabrication, and performance testing of both thermal and mechanical aspects. The results showed that the heating system achieved an optimal working temperature range between 86°C and 168°C, with an average heating time of 5.2 minutes under a 12V DC power supply—meeting the requirements of rubber vulcanization during tire patching. In terms of efficiency, the system demonstrated thermal efficiency of 80–85% with relatively low power consumption. Mechanical analysis of the frame and locking bolts indicated adequate structural strength with a safety factor greater than three. Overall, the tool exhibited advantages in time efficiency, portability, and ease of operation compared to conventional repair methods. These findings are significant as a foundation for further development of next-generation portable tire repair devices featuring automatic temperature control and more flexible power sources.

Keywords— nichrome heating wire, portable tire repair tool, thermal efficiency, mechanical analysis, engineering experiment

Arsana, I. M. (2018). Analysis of tire filling results on tire patch with automatic temperature controller. Jurnal Saintek, 12(2), 55–61.

BPS. 2023. Perkembangan Jumlah Kendaraan Bermotor Menurut Jenis (Unit), 2022. Jakarta. Badan Pusat Statistik

Drozd, K., Tarkowski, S., Caban, J., Nieoczym, A., Vrábel, J., & Krzysiak, Z. (2022). Analysis of truck tractor tire damage in the context of the study of road accident causes. Applied Sciences, 12(23), 12333.

Maidawati, D., Purnama, E., & Mahendrawan, A. (2024). Investigation on the performance in tire repair operation: A case study for semi automation in MSMEs. Journal of Innovation in Technology, 5(1), 22–30.

Mustofa, A., Istiasih, N., & Santoso, S. (2020). Rancang bangun alat tambal ban otomatis menggunakan pemanas elektrik. Prosiding Seminar Nasional Inovasi Teknologi (Inotek), 1(1), 45–52.

Pudin, I. A., Akbar, A., & Pramesti, Y. S. (2020, December). Sistem Otomasi Mikrocontroler Untuk Furnace dengan Kapasitas 7000 Watt. In Prosiding SEMNAS INOTEK (Seminar Nasional Inovasi Teknologi) (Vol. 4, No. 1, pp. 1-6).

Ramadani, V., Nasution, M. I., & Mastura, M. (2024). Sistem Pemantau Suhu Tambal Ban Berbasis Mikrokontroler Nodemcu Esp8266. Jurnal Fisika Unand, 13(3), 379-384.

Restu, F., Hakim, R., & Ramadhana, H. K. (2020). Rancang Bangun Alat Tambal Ban Dalam Sepeda Motor. Jurnal Technopreneur (JTech), 8(1), 18-25.

Yusuf, M. A., Pramono, S., & Hastuti, D. (2022). Pengembangan alat tambal ban elektrik otomatis dengan sensor suhu berbasis Arduino. Prosiding Seminar Nasional Sains dan Terapan (SENASTER), 3(1), 115–122.