Manufacture of Continuous Metal Matrix Composite Strip Reinforced by Particulate Materials from the Semisolid Processing

Antonio de Pádua Lima Filho; Bruno Katsuyoshi Silama Ueda; Tales Paschoalino de Castro; Rodrigo Alessandro Nunes de Oliveira

doi:10.4028/www.scientific.net/SSP.285.189

Paper Titles

Characterization of Microstructure and Shrinkage Porosity of a Semi-Solid Metal Slurry in Gravity Die Casting
p.161

Preparation of Semi-Solid A390 Aluminum Alloy Slurry through a Serpentine Pouring Channel
p.169

SIMA Processing of Cu34wt.%Zn2wt.%Pb Brass Alloy
p.176

Metallurgical Structure of A356 Alloy Solidified by Mechanical Stirring
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Manufacture of Continuous Metal Matrix Composite Strip Reinforced by Particulate Materials from the Semisolid Processing
p.189

Experimental Study on C_F/Al Composite Plate with Complex Curved Surface Fabricated by Liquid-Solid Infiltration Extrusion
p.197

Thixoforming of Wrought Aluminum Alloy 1973
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Thixoforming of Semisolid Slurry with High Fraction Solid Fabricated by Partial Melting of Commerical Wrought Aluminum Alloys
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Effects of Annular Electromagnetic Stirring Melt Treatment on Microstructure and Mechanical Properties of 7050 Rheo-Casting
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HomeSolid State PhenomenaSolid State Phenomena Vol. 285Manufacture of Continuous Metal Matrix Composite...

Manufacture of Continuous Metal Matrix Composite Strip Reinforced by Particulate Materials from the Semisolid Processing

Abstract:

Strip casting is a new method of producing metal matrix composites. Two-roll melt dragged processing (TRMD-ing) and single-roll melt dragged processing (SRMD-ing) methods were used to study the manufacture of 2-mm-thick composite strips by using PbSn (≈ 11.3 g/cm³) eutectic alloy matrix reinforced with iron (≈ 7.86 g/cm³) powder (≈ 70 μm) at a rate of 0.3 m/s. The metallic powder stored in the feed hopper (≈ 90 g) was pushed during the pouring operation of the cast alloy (≈ 4 kg) at 260 oC on the cooling slope to produce a mixture of metallic slurry and particles to feed the nozzle to be dragged by the lower roll. Various surface defects occurred during processing, such as the failure of the powder particle to be embedded in the matrix by SRMD-ing with and without stirrer into the nozzle, and the rolling up of the strip into the nozzle by TRMD-ing. Graphite nanoparticles formed inside the α-Pb grain revealed a complicate eutectic structure in both the processing methods. The colloidal graphite used to coat the crucible, cooling slope, and nozzle could act as a nucleation agent for preferential centre segregation in the α-Pb grain. This suggests that the graphite nanoparticles functioned as nucleation points in the lead-rich α phase. Thus, another type of composite was formed in the presence of graphite nanoparticles within the lead-rich α-phase surrounded by β-Sn. An electron probe microanalysis and scanning electronic microscopy were used to investigate the composition and distribution and identify the different phases. Several types of particulate reinforcements may be added to the matrix to obtain composites for mechanical, electronic, and magnetic applications using these technologies.

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Periodical:

Solid State Phenomena (Volume 285)

Pages:

189-196

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.285.189

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Online since:

January 2019

Authors:

Antonio de Pádua Lima Filho*, Bruno Katsuyoshi Silama Ueda, Tales Paschoalino de Castro, Rodrigo Alessandro Nunes de Oliveira

Keywords:

Metal Matrix Composites, Sn-Pb Eutectic Alloy Composites, Strip Casting

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References

[1] T. Haga, K. Takahashi, H. Inui, H. Sakagushi, S. Watari, S. Kumai, Roll casting of wire inserted aluminum alloy strip, J. Mater. Process. Technol. 187-188 (2007) 508-511.