Desain dan Evaluasi Unjuk Kerja Pemanas Induksi sebagai Sumber Panas pada Alat Pirolisis

Authors

  • Suhardi Makmur Universitas Malikussaleh Author
  • Muhammad Daud Universitas Malikussaleh Author
  • Adi Setiawan Universitas Malikussaleh Author

Keywords:

renewable energy, pyrolysis, induction heater, biomass, heating element

Abstract

The use of renewable energy for rural electrification in Indonesia has great potential, including the potential for energy from biomass. One way to convert biomass into renewable energy is through the pyrolysis process. Heating technology in pyrolysis is currently under development, one of which uses electrical energy with induction heating technology. Therefore, the aim of this research is to design a pyrolysis tool with a suitable induction heater, where this tool is powered by an electrical energy source. The pyrolysis tool is designed to use an induction heater that is varied by using a three-coil and a seven-coil heating element. The pyrolysis tool design was then realised in prototype form with a length of 1500 mm, width of 1000 mm and height of 1400 mm. Prototype testing was carried out using one heater, with each coil variation operated until the pyrolysis reactor reached the design temperature of 500°C within 120 minutes. The test results of the prototype pyrolysis unit using an induction heater with a three-coil heating element showed that the reactor temperature could not reach the desired target, but only reached a temperature of about 305.6°C in 120 minutes, with the electrical energy required for one test being about 5 kWh. Meanwhile, tests using an induction heater with a seven-coil heating element showed that the reactor temperature target of 500°C in 120 minutes could be well achieved. The electrical energy required for a test using a seven-coil heater is approximately 8 kWh.

References

[1] M. Daud, A Hasibuan, W.V. Siregar, Mursalin, R. Fachroji, “Analisis Perhitungan Penggunaan Energi Listrik Sumber DC Pada Rumah Tinggal Tipe 54 Bersumber Energi Terbarukan,” 2023, doi: 10.30596/rele.v1i1.13088.

[2] Tharo, Zuraidah, Hamdani Hamdani, and Melly Andriana. "Pembangkit listrik hybrid tenaga surya dan angin sebagai sumber alternatif menghadapi krisis energi fosil di sumatera." Prosiding Seminar Nasional Teknik UISU (Semnastek). Vol. 2. No. 1. 2019.

[3] Budiarto, Arif Wahyu. "Rancang Bangun Pemanas Induksi dengan Metode Multiturn Helical Coil." Journal of Applied Electrical Engineering 3.1 (2019): 1-4.

[4] Hasibuan, Arnawan, et al. "Pemanfaatan Energi Bayu Sebagai Sumber Energi Listrik Untuk Penerangan Pada Perahu Nelayan." RELE (Rekayasa Elektrikal Dan Energi): Jurnal Teknik Elektro 3.2 (2021): 85-88.

[5] A. Gani, E. Munawar, M. Faisal, M. D. Rozan Arkan, dan M. Reza, “Pengaruh Pemberian Tekanan dan Pemanasan Terhadap Densitas Bahan Bakar (Bio-Coke) Berbasis Biomassa Bonggol Jagung." Jurnal Serambi Engineering 8.3 (2023).

[6] Yokoyama, Shinya. "Panduan untuk Produksi dan Pemanfaatan Biomassa." The Japan Institute of Energy (2008).

[7] A. Setiawan, F. Muhammad, S. Nurjannah, S. Riskina, Muhammad, dan L. Hakim, “Physical Properties of Biochar Produced from Pyrolysis of Arabica Coffee Pulp: The Effect of Pre-Washing Process,” dalam Journal of Physics: Conference Series, Institute of Physics, 2024. doi: 10.1088/1742-6596/2739/1/012001.

[8] Setiawan, Adi, et al. "Pemanfaatan Limbah Sekam Padi Menjadi Bioarang untuk Pembenah Tanah Lahan Pertanian di Desa Pande Kecamatan Tanah Pasir Aceh Utara." Jurnal Solusi Masyarakat Dikara 1.1 (2021): 27-31.

[9] Inayat, Abrar, et al. "Techno-economical evaluation of bio-oil production via biomass fast pyrolysis process: a review." Frontiers in Energy Research 9 (2022): 770355.

[10] M. Kumar, S. Sabbarwal, P. K. Mishra, dan S. N. Upadhyay, “Thermal degradation kinetics of sugarcane leaves (Saccharum officinarum L) using thermo-gravimetric and differential scanning calorimetric studies,” Bioresour Technol, vol. 279, hlm. 262–270, Mei 2019, doi: 10.1016/j.biortech.2019.01.137.

[11] Restanti, Rr Bella Alda, and Mohamad Mirwan. "Pengolahan Sampah Plastik Menjadi Bahan Bakar Minyak Alternatif dengan Metode Pirolisis." Jurnal Serambi Engineering 8.4 (2023).

[12] P. Jutakridsada, R. Sriprasoed, N. Patikarnmonthon, dan K. Kamwilaisak, “Comparison Study of Sugarcane Leaves and Corn Stover as a Potential Energy Source in Pyrolysis Process,” dalam Energy Procedia, Elsevier Ltd, Nov 2016, hlm. 26–29. doi: 10.1016/j.egypro.2016.10.142.

[13] Harahap, Ardiansyah, Adi Sucipto, and Jupriyadi Jupriyadi. "Pemanfaatan Augmented Reality (Ar) Pada Media Pembelajaran Pengenalan Komponen Elektronika Berbasis Android." Jurnal Ilmiah Infrastruktur Teknologi Informasi 1.1 (2020): 20-25

[14] Wahid, Mazlan Abdul, et al., eds. Advances in Heat Transfer, Flow Engineering and Energy Installations. Trans Tech Publications Ltd, 2016.

[15] Moran, Michael J., et al. Fundamentals of engineering thermodynamics. John Wiley & Sons, 2010.

Downloads

Published

21/09/2024

How to Cite

[1]
“Desain dan Evaluasi Unjuk Kerja Pemanas Induksi sebagai Sumber Panas pada Alat Pirolisis”, jse, vol. 9, no. 4, Sep. 2024, Accessed: Dec. 03, 2024. [Online]. Available: https://jse.serambimekkah.id/index.php/jse/article/view/413

Similar Articles

1-10 of 77

You may also start an advanced similarity search for this article.