Iranian Journal of Manufacturing Engineering

Iranian Journal of Manufacturing Engineering

Fabrication and characterization of the mechanical properties of Al1050-CNT composites using accumulative channel-die compression bonding process

Document Type : Original Article

Authors
Hossein Jafarzadeh 1
Ehsan Shalchi 2
Moharram Shameli 3
1 Assistant Professor, Department of Mechanical Engineering, Islamic Azad University, Tabriz branch, Tabriz, Iran
2 MSc, Space Thruster Research Institute, Iran Space Institute, Tabriz, Iran
3 Assistant Professor, Space Thruster Research Institute, Iran Space Institute, Tabriz, Iran
10.22034/ijme.2024.437634.1922
Abstract
In the present investigation a new severe plastic deformation method called accumulative channel-die compression bonding (ACCB) was adapted for fabrication of Al1050-carbon nanotube (CNT) composites. Microstructure and mechanical properties of Al1050 matrix material and synthesized composites were analyzed using SEM and tensile testing. The obtained results showed that the average grain size of matrix is reduced to 7 and 4 μm after one and two passes of ACCB respectively. Processed composites and Al1050 showed a limited homogeneous plastic deformation indicating the limited work hardening capacity due to the high dislocation densities developed during ACCB process. Also, the tensile strength of Al1050-CNT composites was increased with increase in deformation passes. It was demonstrated that different mechanisms are responsible for improved mechanical properties including the increase in dislocation density and reinforcement fraction and grain refinement by plastic deformation. Fractured surface were showed a combination of ductile and brittle failure during tensile deformation.
Keywords
Nanocomposite
Al1050-CNT Composite
ACCB
Mechanical Properties
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