Synthesis of Bulk Metal Matrix Nanocomposites by Full Cavitation Solidification Method

Payodhar Padhi; Biranchi Narayan Dash; Pragyan Mohanty; B.K. Satapathy; Sachikanta Kar

doi:10.4028/www.scientific.net/KEM.545.193

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Powder Injection Moulding of Alumina Using PEG/PVB Binder Systems
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Study of Particle Distribution in Al-SiC Particulate Composite by Random Motion of Mould
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Synthesis of Bulk Metal Matrix Nanocomposites by Full Cavitation Solidification Method
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 545Synthesis of Bulk Metal Matrix Nanocomposites by...

Synthesis of Bulk Metal Matrix Nanocomposites by Full Cavitation Solidification Method

Abstract:

There are several methods for the production of metal matrix nano composites including mechanical alloying, vertex process and spray deposition. However, the above processes are expensive. Solidification processing is a relatively cheaper route. However, during solidification processing nano particulates tend to agglomerate as a result of van der Waals forces and thus proper dispersion of the nano-particulate in metal matrix is a challenge. Many researchers dispersed nanoparticles in metal matrix by ultrasonic casting. However their technique has several drawbacks such as the oscillating probe, which is in direct contact with liquid metal, may dissolve in the liquid metal and contaminate it. Moreover, the extent of dispersion is not uniform. It is maximum near the probe and gradually decreases as one move away from the probe. Lastly in the method developed by them, the oscillating probe is removed from the liquid metal before cooling and solidification begin. It may lead to partial reagglomeration of nanoparticles. To overcome these difficulties a non-contact method, where the ultrasonic probe is not in direct contact with the liquid metal, was attempted to disperse Nano-sized Al2O3 particulates in aluminium matrix. In this method the mold was subjected to ultrasonic vibration. The crystallite size of Al2O3 was mostly below 10 nm. Nano composite having 1-1.5 wt. % of Al2O3 was cast. From HRTEM studies it is observed that the Al2O3 particles are distributed uniformly except the grain boundaries. In micro scale the hardness is uniform throughout the samples. This is due to cavitation process as well as pushing of the nano-particles during the growth of the grains. In the present study it accounts all first-order effects i.e., phase change, bubble dynamics, turbulent pressure fluctuations, and noncondensable gases for deaglomeration and distribution of particles throughout the domain to get uniform distributions.

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Periodical:

Key Engineering Materials (Volume 545)

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193-196

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.545.193

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Online since:

March 2013

Authors:

Payodhar Padhi, Biranchi Narayan Dash, Pragyan Mohanty, B.K. Satapathy, Sachikanta Kar

Keywords:

Full Cavitation, Nanocomposite, Solidification, Ultrasonic

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