Processing of Primary Silicon and Mg2Si Reinforced Hybrid Functionally Graded Aluminum Composites by Centrifugal Casting

S. Raghunandan; Jasim Akber Hyder; T.P.D. Rajan; K. Narayan Prabhu; B.C. Pai

doi:10.4028/www.scientific.net/MSF.710.395

Paper Titles

Synthesis of Porous SiC Preform and Squeeze Infiltration Processing of Aluminium-SiC Metal Ceramic Composites
p.371

Synthesis and Characterization of In Situ AlN Reinforced Magnesium Matrix Composites
p.377

Role of SiC_P on Processing and Physical Characteristics of Al-Si-Mg/SiC_P Composite Foams
p.383

Processing and Microstructure of Magnesium In Situ Composite with Titanium and Boron Based Reinforcement
p.389

Processing of Primary Silicon and Mg₂Si Reinforced Hybrid Functionally Graded Aluminum Composites by Centrifugal Casting
p.395

Tribological Behavior of Mg-Mg₂Si In Situ Composite
p.401

Wear Characteristic of Al-Based Metal Matrix Composites Used for Heavy Duty Brake Pad Applications
p.407

Challenges in Characterization and Acceptance of Metal Matrix Composite “Carrier Plate” Material for Space Applications
p.412

Mechanical Characterization of Multi Phase Steel at Different Rates of Loading
p.421

HomeMaterials Science ForumMaterials Science Forum Vol. 710Processing of Primary Silicon and Mg2Si Reinforced...

Processing of Primary Silicon and Mg₂Si Reinforced Hybrid Functionally Graded Aluminum Composites by Centrifugal Casting

Abstract:

In the present investigation, FGMs of mono-dispersed in-situ primary Si and their hybrids with Mg₂Si reinforcements have been fabricated by the centrifugal casting process using 390 commercial Al alloy. Hard primary silicon particles are formed during the solidification of the 390 alloy and Mg₂Si reinforcements are formed by the addition of varying amount of magnesium into the A390 aluminium alloy. Owing to the difference in density both primary silicon and Mg₂Si gets segregated towards the inner periphery during centrifugal casting. The size of the Mg₂Si in-situ reinforcement phase is relatively smaller and is distributed in the edges of primary silicon particles and also individually in the matrix. The in-situ Mg₂Si and primary silicon can significantly increase the hardness and strength of the inner periphery of the casting. Higher Mg contents have been observed to introduce significant porosity leading to poor castings. Addition of phosphorous to the melt has led to the modification and refinement of primary Si morphology and also helped in the reduction of shrinkage porosity. Maximum hardness of 167 BHN is observed towards the inner periphery of the 390Al-2.5%Mg added in-situ composite.

You might also be interested in these eBooks

Advances in Metallic Materials and Manufacturing Processes for Strategic Sectors

View Preview

Info:

Periodical:

Materials Science Forum (Volume 710)

Pages:

395-400

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.710.395

Citation:

Cite this paper

Online since:

January 2012

Authors:

S. Raghunandan, Jasim Akber Hyder, T.P.D. Rajan, K. Narayan Prabhu, B.C. Pai

Keywords:

Aluminum (Al), Centrifugal Casting, Functionally Graded Material (FGM), Primary Silicon

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] B.P. Krishnan and P.K. Rohatgi, Metal. Tech, 11 (1984) p.41

Google Scholar

[2] A. Baneerji, P.K. Rohatgi and W. Reif, in proc. Europ. MRS. Conf. Advanced Materials Research and development of Transportation of Composites, Strassburg, France, 1985, p.356.

Google Scholar

[3] T.P.D. Rajan, R.M. Pillai and B.C. Pai, Mater. Character. 61 (2010) p.923.

Google Scholar

[4] Mondolfo L.F., 'Aluminum Alloys: Structure and Properties', Butterworths, London, (1976) p.338.

Google Scholar

[5] Yoshimi Watanabe and Shin Oike, Acta Materilia, 53 (2005) p.1631.

Google Scholar

[6] Yoshimi Watanabe and Tatsuru Nakamura, Intermetallics, 9(1) (2001) p.33.

Google Scholar

[7] Z. Humberto Melgarejo, O. Marcelo Sua´rez, and Kumar Sridharan, Scripta Materialia 55, (2006), p.95.

Google Scholar

[8] T.P.D. Rajan, R.M. Pillai and B.C. Pai, J. of Alloys and Compds., 453 (2008) p L4.

Google Scholar