EFFECT OF SIC AND TIB2 PARTICLES ON MICROSTRUCTURE AND MECHANICAL PROPERTIES OF COPPER SURFACE COMPOSITES FABRICATED BY FRICTION STIR PROCESSING

Authors:

L. Suvarna Raju,, N. Ramakrishna, G. Mallaiah,

DOI NO:

https://doi.org/10.26782/jmcms.2020.07.00044

Keywords:

Volume percentage (vol.%),SiCp (Silicon Carbide particles),TiB2p (Titanium diboride particles), Cu/SiC (Copper surface composite),

Abstract

Pure copper is reinforced with 20µm ceramic particles like SiCp and TiB2 using FSP to fabiricate surface composites at constant rotational speed of 1120 revaluations per minutes and speed of the weld at 40mm/min. Cylindrical tapper threaded profile pin made of high carbon high chromium was used to prepare the copper surface composites. Experiments were conducted on a vertical milling machine to prepare Surface composites by varying volume percentage of reinforcements (vol.%2, vol.%4,vol.%6). six combinations of surface composites Cu/2vol.%SiC, Cu/4vol.%Sic, Cu/6vol.%Sic; Cu/2vol.%TiB2, Cu/4vol.%TiB2 and Cu/6vol.%TiB2 were fabricated. The processed composites were examined by using and optical microscope to reveal the microstructure. At 4 vol. % sic particles and 4vol.% of TiB2 particles the microstructure reveals fine grains (equiaxed) at the processed region as compared with 2&6 vol.% of reinforcements. Mechanical tests were conducted to determine ultimate tensile strength, yield strength. Hardness survey was made on the processed sample and base metal. From the results, it is found that at 4 vol. % of SiC and 4 vol.% of TiB2  superior properties were obtained as that of vol.% 2 and vol.% 6 of reinforcements. This is attributed to the fine grains formed in the copper surface composites. Cu surface composite reinforced with 6 vol. % of TiB2 resulted in higher hardness. As the vol. % of SiC and TiB2 increased the resistance to wear is also increased.

Refference:

I A. N. Attia, “Surface metal matrix composites,” Materials and Design, vol. 22, no. 6, pp. 451–457, 2001.
II Chang CI, Du XH, Huang JC. Achieving ultrafine grain size in Mge Ale Zn alloy by friction stir processing. Scr Mater 2007; 57: 209e12.
III Devaraju A, Kumar A, Kotiveerachari B. Influence of rotational speed and reinforcement on wear and mechanical properties of aluminum hybrid composites via friction stir processing. Mater Des2013; 45: 576e85.
IV L. Suvarna Raju, A. Kumar. “Influence of Al2O3 particles on the microstructure and mechanical
V M. Barmouz, P. Asadi, M. K. B. Givi, and M. Taherishargh, “Investigation of mechanical properties of Cu/SiC composite fabricated by FSP: effect of SiC particles’ size and volume fraction,” Materials Science and Engineering A, vol. 528, no. 3, pp. 1740–1749, 2011.
VI P. Asadi, M. K. B. Givi, K. Abrinia, M. Taherishargh, and R. Salekrostam, “Effects of SiC particle size and process parameters on the microstructure and hardness of AZ91/SiC composite layer fabricated by FSP,” Journal of Materials Engineering and Performance, vol. 20, no. 9, pp. 1554–1562, 2011.
VII properties of copper surface composites fabricated by friction stir processing”, Defence Technology, 2014
VIII R. S. Mishra and Z. Y. Ma, “Friction stir welding and processing,” Materials Science and Engineering R: Reports, vol. 50, no. 1-2, pp. 1–78, 2005.
IX R. Sathiskumar, N. Murugan, I. Dinaharan, S.J. Vijay. “Prediction Of Mechanical And Wear Properties of Copper Surface Composites Fabricated Using Friction Stir Processing”, Materials & Design, 2014.
X S. Cartigueyen and K. Mahadevan, “Role of friction stir processing on copper and copper-based particle reinforced composites—a review,” Journal of Materials Science & Surface Engineering, vol. 2, no. 2, pp. 133–145, 2015.

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