Experimental Evaluation of the Chill Casting Method for the Fabrication of LM-25 Aluminum Alloy-Borosilicate Glass (p) Composites

Anupama Hiremath; Joel Hemanth

doi:10.4028/www.scientific.net/KEM.748.69

Paper Titles

Ply Orientation-Driven Path Planning with Multi Reference Paths for Robotic Fiber Placement on Mesh Surface
p.45

Flame Retardant Effect of a Modified Intumescent Flame Retardant on a Rigid Polyurethane Foam
p.51

A Comparison of the Polymer Matrix Behavior and Mechanical Properties of the Glass Reinforced Plastics and Glass Reinforced Epoxy Pipes under Different Oil Field Chemicals
p.55

Flexural Properties and Vibration Behavior of Jute/Glass/Carbon Fiber Reinforced Unsaturated Polyester Hybrid Composites for Wind Turbine Blade
p.62

Experimental Evaluation of the Chill Casting Method for the Fabrication of LM-25 Aluminum Alloy-Borosilicate Glass (p) Composites
p.69

Effect of Graphene Oxide on Non-Isothermal Melt Crystallization Kinetics of Poly(Trimethylene Terephthalate)
p.74

Influence of Zinc Oxide Nanograins on Properties of Epoxidized Natural Rubber Vulcanizates
p.79

An Alternative Crosslinking of Epoxidized Natural Rubber with Maleic Anhydride
p.84

Emission Spectra Analysis of Atmospheric Pressure DBD Plasma Being Processed by Polypropylene Non Woven Fabric
p.91

HomeKey Engineering MaterialsKey Engineering Materials Vol. 748Experimental Evaluation of the Chill Casting...

Experimental Evaluation of the Chill Casting Method for the Fabrication of LM-25 Aluminum Alloy-Borosilicate Glass (p) Composites

Abstract:

The paper investigates the novelty of application of end chills in fabricating Aluminum alloy metal matrix composites. An effort has also been made to evaluate the effect of chill material on the soundness of the castings obtained. The required composites were prepared using LM-25 Aluminum alloy as matrix material in which different weight percent of Borosilicate glass particles were added ranging from 3 wt.% to 12 wt.%. The variation in weight percent was brought about in steps of 3%. The fabrication of the composites was carried out in sand molds by incorporating two metallic (copper and Steel) and two non-metallic (Graphite and Silicon carbide) end chills. The specimens for strength and hardness tests were prepared as per ASTM standards and the specimens were drawn from near chill-end as well as from farther away from chill end. The microstructure of the specimens reveal a refined grain structure proving the sound quality of the castings. The result analysis also leads to the conclusion that metallic chills are more beneficial as compared to non-metallic chills for obtaining a good quality composites. Copper chill with a high volumetric heat capacity proved to be the best chill material amongst the others.

You might also be interested in these eBooks

Advanced Materials and Engineering Materials VI

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 748)

Pages:

69-73

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.748.69

Citation:

Cite this paper

Online since:

August 2017

Authors:

Anupama Hiremath*, Joel Hemanth

Keywords:

Directional Solidification, End Chills, LM-25 Metal Matrix Composites, Stir Casting

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Koli DK, Agnihotri G, Purohit R., Advanced aluminum matrix composites: The critical need of automotive and aerospace engineering fields, Materials Today: Proceedings. 2(4-5) (2015) 3032-41.

DOI: 10.1016/j.matpr.2015.07.290

Google Scholar

[2] Salih OS, Ou H, Sun W, McCartney DG, A review of friction stir welding of aluminium matrix composites, Materials & Design. 86, (2015) 61-71.

DOI: 10.1016/j.matdes.2015.07.071

Google Scholar

[3] Bodunrin MO, Alaneme KK, Chown LH., Aluminium matrix hybrid composites: a review of reinforcement philosophies; mechanical, corrosion and tribological characteristics, Journal of Materials Research and Technology. 4(4) (2015) 434-45.

DOI: 10.1016/j.jmrt.2015.05.003

Google Scholar

[4] Boostani AF, Tahamtan S, Jiang ZY, Wei D, Yazdani S, Khosroshahi RA, Mousavian RT, Xu J, Zhang X, Gong D., Enhanced tensile properties of aluminum matrix composites reinforced with graphene encapsulated SiC nanoparticles, Composites Part A: Applied Science and Manufacturing. 68 (2015).

DOI: 10.1016/j.compositesa.2014.10.010

Google Scholar

[5] Schultz BF, Ferguson JB, Rohatgi PK., Microstructure and hardness of Al2O3 nanoparticle reinforced Al–Mg composites fabricated by reactive wetting and stir mixing, Materials Science and Engineering: A. 530 (2011) 87-97.

DOI: 10.1016/j.msea.2011.09.042

Google Scholar

[6] Shaha SK, Czerwinski F, Kasprzak W, Friedman J, Chen DL., Microstructure and mechanical properties of Al–Si cast alloy with additions of Zr–V–Ti, Materials & Design. 83 (2015) 801-12.

DOI: 10.1016/j.matdes.2015.05.057

Google Scholar

[7] Seah KH, Hemanth J, Sharma SC., Effect of high-rate heat transfer during casting on the strength, hardness and wear behaviour of aluminium—quartz particulate metal matrix composites, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture. 217(5) (2003).

DOI: 10.1243/095440503322011371

Google Scholar

[8] Hiremath A, Hemanth J., Fabrication and Impact of chills on the Strength of Chilled Aluminium alloy-Borosilicate glass Particulate Composite, International Journal of Applied Engineering Research. 10(20) (2015) 41685-8.

Google Scholar

[9] Devoor NS, Ramesh D, Awarasang S., Study the Tensile and Compression Behaviour of LM 25 Aluminium Alloy Reinforced with Steel Wire, International Journal of Innovative Research and Development. 5(11) ISSN 2278–0211 (2016).

Google Scholar

[10] Y.C. Madhu Kumar, U. Shankar, Evaluation of mechanical properties of aluminium alloy 6061-glass particulates reinforced metal matrix composites, International Journal of Modern Engineering Research, 2 (5) (2012) 3207-9.

Google Scholar