Peningkatan Nilai Kekerasan Baja Karbon Rendah AISI 1018 melalui Proses Pack Karburizing dengan Media Batok Kelapa

Imam Prabowo, Muhammad Ichsanudin, Abdu Halim Wibowo, Fajar Paundra, Eko Pujiyulianto

Abstract


Low carbon materials are one of the steels which have a composition of carbon ranging from 0.005 to 0.3%. Generally, these materials have good ductility and flexibility so they are good enough to be applied for automotive industry’s components. Unfortunately, they do not possess an excellent hardness as well as wear resistance. Thus, in order to enhance the hardness and wear resistance, carburizing is obligatory required. The carburizing process is a diffusion of carbon from the higher to lower concentration in a high temperature condition, following the gradient concentration. In addition, the process demands a source of active carbons and energizer. In this study, the coconut shells are possibly harnessed as a high-rich carbon material besides charcoals due to its availability and environmentally-friendly materials. Hardness test is measured in ten distinct points by using vicker-hardness scale in accordance with ASTM E 384. The hardness of the AISI 1018 increases after pack carburizing process by nearly 20 HVN. It grows from 131 HVN before the process to 150 and 165 HVN after the heating by 900°C and 950°C respectively. The increase is affected by the diffusion of carbon from coconut shells into the layer of AISI 1018 in which the coconut shells are having a higher carbon content compared to the layer. Furthermore, the higher heating temperature will accelerate the diffusion rate of carbon. As a result, the hardness of AISI 1018 at the higher heating temperature will also become larger.


Keywords


AISI 1018, pack carburizing, hardness, coconut shell.

References


Tong, L., Dengzun, Y.,and Chungen, Z. (2010). Low-temperature formation of aluminide coatings on ni-base. Chinese Journal of Aeronautics, 381-385.

Emmanuel, J O and Bernard, N A. (2013). Experimental determination of the effect of wood charcoal as carburizing material on hardness, impact and tensile strength of mild steel. Journal of Sci., Tech., Math. & Edu.

(JOSTMED), 9, 9-17.

Iswadi Jauhari A., S. R., Masdeka, N. R., and b, O. H. (2007). Surface properties and activation energy analysis for. Materials Science and Engineering, 230-234.

Yingying Wei, Zurecki, Z., & Jr, R. D. (2015). Optimization of processing conditions in plasma activated. Surface & Coatings Technology, 190-197.

F. O. Aramide, S. A. Ibitoye, I. O. Oladele, and J. O. Borode. (2010). “Pack carburization of mild steel, using pulverized bone as carburizer: Optimizing process parameters,” Leonardo Electron. Journal. Practical. Technology, vol. 9, no. 16, pp. 1–12,

A. Oyetunji and S. O. Adeosun. (2012). “Effects of Carburizing Process Variables on Mechanical and Chemical Properties of Carburized Mild Steel,” Journal. Basic Applied. Science., vol. 8, pp. 319–324,

A. P. Ihom, G. B. Nyior, O. O. Alabi, S. Segun, J. Nor Iv, and J. Ogbodo. (2012). “The Potentials of Waste Organic Materials for Surface Hardness Improvement of Mild,” International. Journal. Science. Engineering. Res., vol. 3, no. 11, pp. 1–10,

Hurharyanto. Anwar, Ardiansyah. Dimas, and Surojo. Eko. (2019). “Perbandingan Nilai Kekerasan Baja Karbon Rendah pada Proses Pack Carburizing dengan Media Arang Sekam Padi dan Arang Tempurung Kelapa, Jurnal Teknika., vol 15, no. 1, pp. 39-48




DOI: https://doi.org/10.31315/jmept.v3i2.8701

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