Analysis of Surface Roughness and Micro-hardness in Roller Burnishing of Aluminum Alloy 6061
الموضوعات :
1 - Department of Mechanical Engineering, Dehaghan Branch, Islamic Azad University, Dehaghan, Isfahan, Iran
الکلمات المفتاحية: Surface Roughness, Micro-Hardness, Roller Burnishing, Minimum quantity lubrication (MQL),
ملخص المقالة :
Burnishing is a chip-less finishing process, in which a hard roller or ball presses the surface layer of part to perform plastic deformation in the surface layer and produce improved finish, enhanced hardness and compressive residual stresses on the surface of special materials such as Aluminum and Brass. In the following research, the effect of input parameters such as feed rate, cutting speed, number of passes , burnishing force and cooling system which is applying by minimum quantity of lubrication (MQL) on surface roughness and micro-hardness in roller burnishing of Aluminum alloy 6061 has been investigated. Taguchi method is used for design of experiments and special burnishing tool is used for this research. The optimization results show that the effect of feed rate and burnishing speed is significant on surface roughness and burnishing force and the number of passes plays important role in micro-hardness. The minimum surface roughness in burnishing of aluminum alloy 6061 was 0.138 μm and the maximum was 0.475 μm. The maximum micro-hardness in roller burnishing Aluminum alloy 6061was found 122 HB and the minimum was 100 HB.
[1] Mahajan, D. and Tajane, R. 2013. A Review on Ball Burnishing Process. International Journal of Scientific and Research Publications. 3(4): 1-8.
[2] Hassan, A. M. and Maqableh, A. M. 2000. The Effects of Initial Burnishing Parameters on Non-Ferrous Components. Journal of Materials Processing Technology. 102(1-3): 115-121.
[3] Tian, Y. and Shin, C. Y. 2007. Laser-assisted Burnishing of Metals. International Journal of Machine Tools & Manufacture. 47(1): 14–22.
[4] Gardin, C., Courtin, S., Bertheau, D., Bezine, G. and Ben Hadj Hamouda, H. 2007. The Influence of Roller Burnishing on the Fatigue Crack Propagation in Notched Round Bars –Experimental Observations under Three-point Bending. Fatigue & Fracture of Engineering Materials & Structures journal. 30(4): 342-350.
[5] El-Axira, M.H., Othmanb, O.M. and Abodiena, A.M. 2008. Improvements in Out of Roundness and Micro Hardness of Inner Surfaces by Internal Ball Burnishing Process. Journal of Materials Processing Technology. 196(1-3): 120–128.
[6] Korzynski, M. 2009. A Model of Smoothing Slide Ball-Burnishing and an Analysis of the Parameter Interaction. Journal of Materials Processing Technology. 209(1): 625–633.
[7] Sagbas, A. 2011. Analysis and Optimization of Surface Roughness in the Ball Burnishing Process Using Response Surface Methodology and Desirability Function. Advances in Engineering Software journal. 42(11): 992–998.
[8] Hamadache, H., Zemouri, Z., Laouar, L. and Dominiak, S. 2014. Improvement of Surface Conditions of 36 Cr Ni Mo 6 Steel by Ball Burnishing Process. Journal of Mechanical Science and Technology. 28(4): 1491–1498.
[9] Revankar, G.D., Shetty, R., Rao, S.S. and Gaitonde, V.N. 2014. Analysis of Surface Roughness and Hardness in Ball Burnishing of Titanium Alloy. Measurement Journal. 58: 256–268.
[10] Nikalje, A. M., Kumar, A. and Sai Srinadh, K. V. 2013. Influence of Parameters and Optimization of EDM Performance Measures on MDN 300 Steel Using Taguchi Method. International Journal Advanced Manufactoring Technology. 69(1-4): 41–49.
[11] MINITAB14 software/2005/help
[12] El-Tayeb, N.S.M., Low, K.O. and Brevern, P.V. 2006. Influence of Roller Burnishing Contact Width and Burnishing Orientation on Surface Quality and Tribological Behavior of Aluminium 6061. Journal of Materials Processing Technology. 186(1-3): 272–278.