Investigations on Mechanical Properties of Al-4.5% Cu-SiC and Al-4.5%Cu-Graphite Composites
Abstract Views
323
Downloads
318
Citations
Share
##plugins.themes.bootstrap3.article.sidebar##
Published Jul 27, 2018
Abstract viewed = 323 times
##plugins.themes.bootstrap3.article.main##
This paper deals with the investigation of mechanical properties by introducing micro size SiC particulates and Graphite particulates into Al-4.5%Cu alloy matrix. SiC and Graphite particle reinforced Al alloy metal matrix composites were prepared by stir casting method. Al-Cu alloy was taken as the base matrix to which SiC and Graphite particulates were used as reinforcements. 6 wt. % of SiC and Graphite particulates were added to the base matrix to fabricate Al-4.5Cu – 6 wt. % SiC and Al-4.5%Cu – 6 wt. % Graphite composites. For each composite, the reinforcement particles were pre-heated to a temperature of 600oC and then dispersed in steps of two into the vortex of molten Al-Cu alloy to improve wettability and distribution. The Micostructural study was done by using optical microscope, which revealed the uniform distribution of SiC and Graphite particles in matrix alloy. Mechanical properties like hardness, tensile and impact strength were evaluated as per ASTM standards. Hardness and tensile strength increased with addition of 6 wt. % of SiC particulates in the base matrix Al-Cu alloy compared to Al-Cu-6wt. % Graphite composites.
Downloads
References
-
Zeeshan Ahmad and Dr. Sabah Khan, “A review paper on tribological and mechanical properties of Aluminium metal matrix composites manufactured by different route,” IJCESR, 1, 4, 2014.
Google Scholar
1
-
Wei-chen Zhai, Zhao-hui Zhang, Fu-chi Wang, Xiang-bo Shen, Shu-kui Lee, and Lu Wang, “Effect of SI content on microstructure and properties of Si/Al composites”, Trans. Nonferrous Met. Soc. China, 24, pp. 982-988, 2014.
Google Scholar
2
-
H. Ribes, M. Suery, G. L.Esperance, and J.G. Legoux, “Microscopic examination of the interface region in 6061-Al/SiC composites reinforced with asreceived and oxidized SiC particles,” Metallurgical and Materials Transactions A, vol. 21, pp. 2489–2496, 1999.
Google Scholar
3
-
B. VijayaRamnath, C. Elanchezhian, M. Jaivignesh, S. Rajesh, C. Parswajinan, and Siddique Ahmed Ghias, “Evaluation of mechanical properties of aluminium alloy–alumina–Boron carbide metal matrix composites”, Materials and Design, 58, pp. 332–338, 2014.
Google Scholar
4
-
Sankaranarayanan, S., Sabat, R.K., Jayalakshmi, S. and Gupta, M.: Microstructural evolution and mechanical properties of Mg composites containing nano B4C hybridized micro Ti particulates, Materials Chemistry and Physics, Vol. 143, pp. 1178-1190, 2014.
Google Scholar
5
-
Pattanashetty Basavaraja, Madeva Nagaral, S., Vidyashankar, and V. Auradi, “Evaluation of Mechanical properties of Al2219-SiC-Graphite reinforced hybrid Composites”, International Journal of Applied Engineering Research, 10, 9, 2015.
Google Scholar
6
-
Madeva Nagaral, V. Auradi, and S. A. Kori, “Microstructure and Mechanical Properties of Al6061-graphite Composites Fabricated by Stir-Casting Process”, Applied Mechanics and Materials, 766-767, pp. 308-314, 2015.
Google Scholar
7
-
V. Auradi, G. L. Rajesh, and S. A. Kori, “Processing of B4C particulate reinforced 6061aluminium matrix composites by melt stirring involving two-step addition”, Procedia Materials Science, 6, 1068 – 1076, 2014.
Google Scholar
8
-
X.P. Li, C.Y. Liu, M.Z. Ma, and R.P. Liu, “Microstructures and mechanical properties of AA6061–SiC composites prepared through spark plasma sintering and hot rolling”, Elsevier Materials Science & Engineering A 650, pp.139–144, 2014.
Google Scholar
9
-
S Gopala kannan and T Senthilvelan, “Synthesis and Characterization of Al7075 reinforced with SiC and B4C nano particles fabricated by ultrasonic cavitation method”, Journal of Scientific & Industrial Research Vol 74, pp.281-285, 2015.
Google Scholar
10
