TY - GEN
T1 - Experimental evaluation of the chill casting method for the fabrication of LM-25 aluminum alloy-borosilicate glass (p) composites
AU - Hiremath, Anupama
AU - Hemanth, Joel
PY - 2017/1/1
Y1 - 2017/1/1
N2 - 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 nonmetallic 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.
AB - 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 nonmetallic 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.
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U2 - 10.4028/www.scientific.net/KEM.748.69
DO - 10.4028/www.scientific.net/KEM.748.69
M3 - Conference contribution
AN - SCOPUS:85028772481
SN - 9783035711837
T3 - Key Engineering Materials
SP - 69
EP - 73
BT - Advanced Materials and Engineering Materials VI - 6th ICAMEM
PB - Trans Tech Publications Ltd
T2 - 6th International Conference of Advanced Materials and Engineering Materials, ICAMEM 2017
Y2 - 11 March 2017 through 12 March 2017
ER -