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Effect of Temperature on Sliding Wear Mechanism under Lubrication Conditions
Nofal Al-Araji , Hussein Sarhan Sarhan
Pages - 176 - 184     |    Revised - 01-05-2011     |    Published - 31-05-2011
Volume - 5   Issue - 2    |    Publication Date - May / June 2011  Table of Contents
MORE INFORMATION
KEYWORDS
Dry sliding wear, Surface film, Friction coefficient, Wear particles, Oil type
ABSTRACT
Experimental program using ball-on-cylinder tester has been conducted to investigate the effects of temperature, normal load, sliding speed and type of lubricating oil on sliding wear mechanism. The worn surfaces and debris have been examined. Surface examination of the tested samples using scanning electron microscope SEM was used to study the wear particles and the wear surfaces. The results show that the temperature of the oils affects the probability of adhesion, oxidation, wear rates, and friction coefficient. At room temperature (40oC) and under lubrication conditions, friction and wear decreases with the increase of the running time. The increase in applied normal load tends to reduce the friction in all types of oils. The phosphorated oil SAE 90 was superior in minimizing friction and wear as compared with other oils. The results have shown that the lubricant temperature has a significant role in wear mechanism.
CITED BY (10)  
1 Maré, J. C. (2016). Requirement-based system-level simulation of mechanical transmissions with special consideration of friction, backlash and preload. Simulation Modelling Practice and Theory, 63, 58-82.
2 Farhanah, A. N., & Bahak, M. Z. (2015). Engine oil wear resistance. Jurnal Tribologi, 4, 10-20.
3 Nuraliza, N., Syahrullail, S., & Musa, M. N. (2015).Evaluation on the tribological properties of double fractionated palm olein at different loads using pin-on-disc machine. Jurnal Teknologi, 75(11).
4 Syahrullail, S., & Nuraliza, N. (2015, January). Effect of Surface Roughness Parameters and Surface Texture for Reduced Friction. In Applied Mechanics and Materials (Vol. 695, pp. 572-575).
5 Sapawe, N., Syahrullail, S., & Izhan, M. I. (2014). Evaluation on the tribological properties of palm olein in different loads applied using pin-on-disk tribotester. Jurnal Tribologi, 3, 11-29.
6 Syahrullail, S., Nuraliza, N., Izhan, M. I., Hamid, M. A., & Razaka, D. M. (2013). Wear Characteristic of Palm Olein as Lubricant in Different Rotating Speed. Procedia Engineering, 68, 158-165.
7 Samion, S., Ibrahim, M. I., Sidik, N. A. C., & Jaafar, M. N. M. (2013). Wear Behavior of Titanium Alloy Lubricated with Palm Olein as Bio-Lubricant Using Pin-On-Disk Tester. Jurnal Teknologi, 66(1).
8 Izhan, M. I., Wira, J. Y., Kadir, M. R. A., & Syahrullail, S. (2013, June). Experimental study on the effect of different speeds applied with palm olein using pin-on-disk tester. In Applied Mechanics and Materials (Vol. 315, pp. 946-950).
9 Razak, D. M., Syahrullail, S., Yahya, A., Mahmud, N., Hashim, N. L. S., & Nugroho, K. (2013). Lubrication on the Curve Surface Structure Using Palm Oil and Mineral Oil. Procedia Engineering, 68, 607-612.
10 Izhan, I. M., Syahrullail, S., Azwadi, C. S. N., & Jaafar, M. N. M. Wear behavior of titanium alloy lubricated with palm olein as bio-lubricant using pin-on-disk tester.
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Professor Nofal Al-Araji
- Jordan
Associate Professor Hussein Sarhan Sarhan
Faculty of Engineering technology - Jordan
sarhan_52@hotmail.com


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