Small-scale renewable energy use is crucial for supplying the world's electrical needs. Utilizing these renewable energy sources requires a device that can transform mechanical power into electrical power. The purpose of this research is to construct a simple AC generator by converting mechanical power into electricity by varying the copper wire's diameter and rotational speed. The outcomes of the investigation include information on the electrical power, torque, mechanical power, and efficiency of the generator. The technical details of the generator employed are 12 poles, a rotor diameter of 9.25 cm, and a stator diameter of 9 cm. The results of the investigation reveal that the generator with the 0.15 mm variation in copper wire diameter performs better than the generators with the 0.75 mm variation in wire diameter. It can generate 80,6 watts of electric power, 1,231 N.m. of torque, 193,468 watts of mechanical force, and 41.66% of efficiency at a rotational speed of 1500 rpm. The result shows that the generator's performance will vary depending on the diameter of the wire at different rotating speeds.

Cangkara, C. H., & Ansori, A. (2022). Pengaruh Variasi Diameter Kawat Kumparan Generator Linier Terhadap Performa Generator Linier. Jurnal Teknik Mesin. https://ejournal.unesa.ac.id/index.php/jtm-unesa/article/view/43871%0Ahttps://ejournal.unesa.ac.id/index.php/jtm-unesa/article/download/43871/37373

Hendra, O. :, Syaiful, M., & Indriani, A. (2014). Pembuatan Generator Sinkron Untuk Pembangkit Listrik Tenaga Mikrohidro Dari Magnet Motor Bekas Di Desa Kemumu Bengkulu Utara Manufacturing of Generator Sincron By Using the Recycle of Magnet Motorcycle for Micro Hydro Power Plant in the Kemumu Village Nor. 104–117.

Herlambang, Y. D., & Suwoto, G. (2010). Unjukkerja Turbin Air Mikro Aliran Silang Terhadap Variasi Sudut Sudu Jalan (Runner) Pada Debit Konstan Untuk PLTMH. Prosiding SNST …, 1, 76–82. https://www.publikasiilmiah.unwahas.ac.id/index.php/PROSIDING_SNST_FT/article/view/228

Nauval Fauzi, M., Harbintoro Balai Besar Logam dan Mesin, S., & Perindustrian Jl Sangkuriang No, K. (2016). Regression Analysis To Determine Correlation of Power and Torsion for Pelton Turbine. METAL INDONESIA Journal Homepage, 38(2).

Nugroho, S., Diana, L., & Ariyanti, D. P. (2019). The effect of axial distance on dual rotor wind turbine’s performance. Journal of Physics: Conference Series, 1367(1). https://doi.org/10.1088/1742-6596/1367/1/012031

Sakura, A., Supriyanto, A., & Surtono, A. (2017). Rancang Bangun Generator Sebagai Sumber Energi Listrik Nanohidro. Universitas Lampung, 05(02), 129–134.

Supardi, A., Budiman, A., & Khairudin, N. R. (2016). Pengaruh Kecepatan Putar dan Beban terhadap Keluaran Generator Induksi 1 Fase Kecepatan Rendah. Emitor: Jurnal Teknik Elektro, 16(1), 26–31. https://doi.org/10.23917/emitor.v16i1.2680

Susilo, S., Yusuf, Y., Ula, S., Hermawan, B. A., & Ghifari, M. R. (2021). Pengaruh Variasi Diameter dan Jumlah Lilitan Tembaga terhadap Tegangan Listrik yang Dihasilkan pada Alat Peredam Kejut Regeneratif Skala Laboratorium. J-Proteksion, 5(2), 25–31. https://doi.org/10.32528/jp.v5i2.4356

Wahab, H., Agustina, S., Sariman, & Dwi Rahma, D. (2023). Efek Sudut Kemiringan Alur Rotor Motor Arus Searah terhadap Torsi dan Daya Luaran. Jurnal Rekayasa Elektro Sriwijaya, 4(2), 83–92. https://doi.org/10.36706/jres.v4i2.88

Wahyu, D. (2019). Uji Kinerja Mesin Fiat 4-Tak dengan Kapasitas 1.100 CC Menggunakan Automotive Engine Test Bed T101D. Jurnal Teknik Mesin, 9(2), 2089–4880. https://e-journal.itp.ac.id/index.php/jtm

Zainal Abidin, T. P. D. (n.d.). Pengujian Performance Motor Listrik Ac 3 Fasa Dengan Daya.