Evaluation of tensile strength of Al7075-SiC nanocomposite compacted by gas gun using spherical indentation test and neural networks

Evaluation of tensile strength of Al7075-SiC nanocomposite compacted by gas gun using spherical indentation test and neural networks

[Display omitted] •Al7075/SiC nanocomposite was fabricated using dynamic powder compaction.•Tensile strength of the samples was determined using instrumented indentation test.•Reinforcing Al7075 matrix using SiCnp improved the tensile strength around 300%. In this paper, fabrication of Al7075-SiC na...

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Bibliographic Details
Published in:Advanced powder technology : the international journal of the Society of Powder Technology, Japan Vol. 27; no. 4; pp. 1821 - 1827
Main Authors: Atrian, A., Majzoobi, G.H., Nourbakhsh, S.H., Galehdari, S.A., Masoudi Nejad, R.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-07-2016
Subjects:
Al7075
Indentation
Nanocomposite
Neural networks
Powder compaction
Powder compaction
Nanocomposite
Al7075
Neural networks
Indentation
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Summary:[Display omitted] •Al7075/SiC nanocomposite was fabricated using dynamic powder compaction.•Tensile strength of the samples was determined using instrumented indentation test.•Reinforcing Al7075 matrix using SiCnp improved the tensile strength around 300%. In this paper, fabrication of Al7075-SiC nanocomposite using dynamic compaction is investigated. Evaluation of material tensile characteristics are often destructive and costly and impossible for small samples. Therefore, instrumented indentation tests can be employed to obtain the tensile stress-strain curve of the material. In this investigation, the tensile stress-strain curve of Al7075-SiC nanocomposite is obtained using combination of spherical indentation test, finite element (FE) simulation, and neural networks. To fabricate the Al7075/SiC nanocomposite samples, Al7075 micron-sized powder and SiC nano particles were mixed to obtain Al7075-5vol% SiC, and Al7075-10vol% SiC and the mixtures were mechanically milled. The mixtures were then consolidated under impact loading by a single-stage gas gun. The compaction was performed at 573K temperature and a maximum relative density of 97.5% was obtained. The load-penetration curve for each nanocomposite sample was obtained using spherical indentation test on the compacted samples. The corresponding numerical curve for each sample was also obtained by finite element simulation of the indentation process. Finally, using the experimental and the FE results, the constants of Hollomon’s material model were determined using artificial neural networks (ANN). The results indicated that SiC nano-particles reinforcement of Al7075 increased the tensile strength of the nanocomposite by around 300%.
ISSN:0921-8831
1568-5527
DOI:10.1016/j.apt.2016.06.015