Investigation on Various Ceramic Nanoparticles Reinforced Aluminum Matrix Composites via Accumulative Roll Bonding and Cryorolling

Accumulative roll bonding (ARB) and cryorolling (CR) processes are used to fabricate three kinds of composites of AA1050 reinforced with SiCp and TiCp, to become the Al-SiCp, Al-TiCp, and Al-SiCp-TiCp composites. The effects of reinforced particles and different passes of ARB and CR on mechanical properties, microstructure, and particle distribution are studied. The microstructure shows the uniform distribution of particulates, decreased porosity, and excellent bonding between particle and matrix as the rolling cycles increased. Mechanical properties of the ARBed and cryorolled sheets are examined, and samples are compared with matrix alloy and composites. The findings demonstrate that the Al-SiCp, Al-TiCp, and Al-SiCp-TiCp composites improve the elastic modulus, yield strength, and hardness. After comparing the results of composites, the best combination of hardness, yield strength, ultimate tensile strength, toughness, and young modulus base composite has been chosen. Al-TiCp and Al-SiCp composites demonstrate ductile fracture behavior, as observed through SEM testing, while Al-SiCp-TiCp composite sample exhibits a bimodal fracture. This composite should aid in the creation of lightweight composites for use in aeronautical applications. The study uses accumulative roll bonding (ARB) and cryorolling (CR) processes to create AA1050 composites reinforced with SiCp and TiCp, forming Al-SiCp, Al-TiCp, and Al-SiCp-TiCp composites. Effects of particles and ARB/CR passes on properties are examined. Increased cycles improve microstructure, particle distribution, bonding, and mechanical properties. The composites enhance modulus, strength, and hardness. Optimal composite is selected after comparing results.image (c) 2023 WILEY-VCH GmbH

Automated summary

This study uses accumulative roll bonding (ARB) and cryorolling (CR) processes to create AA1050 composites reinforced with SiCp and TiCp, forming Al-SiCp, Al-TiCp, and Al-SiCp-TiCp composites. Effects of particles and ARB/CR passes on properties are examined. Increased cycles improve microstructure, particle distribution, bonding, and mechanical properties. The composites enhance modulus, strength, and hardness. Optimal composite is selected after comparing results.