Experimental and finite element analysis of mechanical and fracture behaviour of Al₂O₃ particulate-filled A356 alloy composites: Part II

Abstract: In the present work, alumina (Al 2 O 3 )-filled cast aluminium alloy (A356) composites were fabricated using stir casting technique by varying Al 2 O 3 contents (0, 5, 10, 15, 20 and 25 wt.%). The fabricated composites were studied for their physical, mechanical and fracture toughness behaviour experimentally, theoretically and compared with finite element analysis method to validate the experimental and theoretical results. The physical and mechanical results showed that the addition of alumina to A356 alloy … Show more

“…The reason for adding 2.5% reinforcement was to avoid porosity and distribute it uniformly in the matrix. Kukshal et al 28 reported that composite porosity increases in tandem with the volume fraction of the reinforcement. Even with this low percentage of reinforcement, strength was enhanced.…”

Development of alumina reinforced aluminum metal matrix composite with enhanced compressive strength through squeeze casting process

“…The reason for adding 2.5% reinforcement was to avoid porosity and distribute it uniformly in the matrix. Kukshal et al 28 reported that composite porosity increases in tandem with the volume fraction of the reinforcement. Even with this low percentage of reinforcement, strength was enhanced.…”

Development of alumina reinforced aluminum metal matrix composite with enhanced compressive strength through squeeze casting process

Finite Element Modeling and Analysis of Natural Fiber-Reinforced Composite

Thermo-Mechanical and Fracture Characterization of Uncoated, Single and Multilayer (SiN/CrN) Coating on Granite Powder Filled Metal Alloy Composites