Rancang bangun prototype tungku induksi untuk proses perlakuan panas

Authors

  • Muchamad Fajrin Darmawan Mechanical Engineering Education, Universitas Sultan Ageng Tirtayasa
  • Sulaeman Deni Ramdani (Scopus ID: 5721267561) Universitas Sultan Ageng Tirtayasa http://orcid.org/0000-0001-8544-170X
  • Moch Fawaid Mechanical Engineering Education, Universitas Sultan Ageng Tirtayasa

DOI:

https://doi.org/10.30738/jtv.v8i2.8830

Keywords:

Induction Furnace, Temperature Minimum, Heat Treatment

Abstract

This research aims for 1). Performance of induction furnace used to heat test objects in the form of iron, stainless steel and aluminum 2). Efficiency of induction furnace in heating test objects in the form of iron, staineless and aluminum. The research method used in this study is purely experimental where data is obtained from the heating of test objects in the form of iron, aluminum and stainless steel. 1). At the time of the induction furnace performance test was conducted 13 experiments, out of 13 tests got the highest temperature of 650o C on the thirteenth experiment and failed on the second, fifth and ninth trials where MOSFET was damaged. 2). Induction furnace in heating iron weighing 5 grams produces a calorific 1302.57 joules and produces 49.16 Watts of power. Induction furnace in heating aluminum weighing 5 grams produces a 5.22 joule calorific and produces 0.029 Watts of power. Induction furnace in heating stainless steel weighing 5 grams produces a calorific 1440.52 joules and produces 42.66 Watts of power. so the induction furnace is more efficient when it is heating test objects in the form of iron and the induction furnace cannot heat test objects that do not have magnetic properties.

Author Biography

Sulaeman Deni Ramdani, (Scopus ID: 5721267561) Universitas Sultan Ageng Tirtayasa

Sinta ID: 75949 

Google Scholar: Sulaeman Deni Ramdani

References

Adi, I. M., Raharjo, W. P., & Surojo, E. (2014). RANCANG BANGUN TUNGKU PENCAIRAN LOGAM ALUMUNIUM BERKAPASITAS 2 KG DENGAN MEKANISME TAHANAN LISTRIK ( PENGUJIAN PERFORMANSI ) Keywords : Abstract : 13(September), 21–32.

Aswardi., Candra, O. and Saputra, Z. (2019) ' Sistem Pemanas Logam dengan Induction Heater Berbasis Atmega32', Jurnal Ilmiah Teknik Elektro Universitas Negeri Padang.

Bangun, Y. P. (2019) ' Pengaruh Induksi Magnetik (Dalam Perancangan Tungku Induksi) Terhadap Waktu yang Dibutuhkan untuk Meleburkan Aluminium pada Temperatur 750oC', Jurnal Ilmiah Teknik Mesin Universitas Sriwijaya.

Bambang, K and Wahyu, P. R. (2013) ' RANCANG BANGUN PEMANAS INDUKSI BERKAPASITAS 600 W UNTUK PROSES PERLAKUAN PANAS DAN PERLAKUAN PERMUKAAN', Jurnal Ilmiah Teknik Mesin UNS.

Budi, I,, Ridwan, A and Rilnanda, A. (2017). Optimasi Tungku Peleburan Logam Aluminium Kapasitas 10 Kg Berbahan Bakar Oli Bekas Skala Laboratorium. Pekanbaru: Universitas Muhammadiyah Riau

Itp Metal Casting. (2005). Advenced Melting Technologies : Energy Saving Concepts and Opportunities for The Metal Casting Industry. November, 46

Joseph, O and Irabodemeh, J. M. (2016). Design and Thermal Analysis of Crucible Furnace for Non-Ferrous Metal. Nigeria: Journal of Information Engineering and Aplications

Malvino, A., P. (1993). Elektronika Komputer Digital, Pengantar Mikrokomputer. Jakarta: Erlangga

Muhammad Firman Hakiki, D. R. (2018). Rancang Bangun Sistem Induction Heater Berbasis Mikrokontroller Atmega 328. Teknik Mesin, 4(3), 83–89.

Nugroho, E., & Utomo, Y. (2017). PERANCANGAN DAN PEMBUATAN DAPUR PELEBURAN ALUMINIUM BERBAHAN BAKAR GAS (LPG). Turbo : Jurnal Program Studi Teknik Mesin. https://doi.org/10.24127/trb.v6i2.623

Rahmat, M. R. (2015). Perancangan Dan Pembuatan Tungku Heat Treatment. Jurnal Ilmiah Teknik Mesin Unisma “45†Bekasi, 3(2), 133–148.

Rizal, A., Samantha, Y., & Rachmat, A. (2016). PEMBUATAN TUNGKU PEMANAS (MUFLLE FURNACE) KAPASITAS 1200 Celcius. J-Ensitec, 2(02), 13–16. https://doi.org/10.31949/j-ensitec.v2i02.301

Rudnev, V., Loveless, D., & Cook, R. L. (2018). Handbook of Induction Heating, Second Edition. In Boca Raton: CRC Press.

Schlesinger, M. (2013) ' Aluminium Recycling', Boca Raton: Taylor and Francis Group.

Sodiq, D. and Ardiansyah, R. (2014) ' Optimasi Frekuensi dan Temperatur Pemanasan pada Peleburan Timah dalam Tungku Induksi dengan Kapasitas 0,45 Kg', Jurnal Ilmiah Politeknik Negeri Bandung.

Surdia, T and Shinroku, S. (1992). Teknik Pengecoran Logam. Jakarta: Pradya Paramita

Surdia, T and Kenji C. (2006). Pengetahuan Bahan Teknik. Jakarta: Pradya Paramita

Sutarya, D. and Sartono, A. (2018) 'Perancangan Koil Pemanas untuk Tungku Induksi Menggunakan Konduktor Tembaga', Jurnal Ilmiah Pusat Teknologi Bahan Bakar Nuklir.

Syahbardia., Somantri, H, and Suryaman, A. (2018) ' Pembuatan Tungku Induksi Sederhana', Jurnal Ilmiah Teknik Mesin Undip.

Verran, G., O and Kurzawa, U. (2008). An Experimental Study of Aluminium can Recycling Using Fusion in Induction Furnace. Resources Conservation and Recycling.

Viviek R. Gandhewar, Satish V. Bansod & Atul B. Borade. 2011. Furnace Induksi.India: International Journal of Engineering and Technology

Zavertkin, A., S. (2008). Effects of Mixture Composition on the Linning Stability of a Crucible Induction Furnace. Refractories and Industrial Ceramics

Zhulkarnaen, Y. (2013). Perancangan dan Pembuatan Pemanas Induksi dengan Metode Pancake Coil Berbasis Mikrokontroller Atmega 8535. Teknik Elektro Universitas Brawijaya.

Zinn, S. and Semiatin, S. L. (1988) 'elements Of Induction Heating Design Control', ASM International

Published

2020-12-31

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