A Comparative Study of a Machine Learning Approach and Response Surface Methodology for Optimizing the HPT Processing Parameters of AA6061/SiCp Composites

A Comparative Study of a Machine Learning Approach and Response Surface Methodology for Optimizing the HPT Processing Parameters of AA6061/SiCp Composites

This work investigates the efficacy of high-pressure torsion (HPT), as a severe plastic deformation mechanism for processing plain and silicon-carbide-reinforced AA6061, with the broader objective of using the technique for improving the properties of lightweight materials for a range of objectives....

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Bibliographic Details
Published in:Journal of Manufacturing and Materials Processing Vol. 7; no. 4; p. 148
Main Authors: El-Garaihy, Waleed H., Alateyah, Abdulrahman I., Shaban, Mahmoud, Alsharekh, Mohammed F., Alsunaydih, Fahad Nasser, El-Sanabary, Samar, Kouta, Hanan, El-Taybany, Yasmine, Salem, Hanadi G.
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-08-2023
Subjects:
AA6061
Algorithms
Alloys
Aluminum alloys
Aluminum base alloys
Comparative analysis
Comparative studies
Compressive strength
Datasets
Deformation mechanisms
Design of experiments
Equivalence
genetic algorithm
Genetic algorithms
Grain refinement
Hardness
high-pressure torsion
Homogeneity
Investigations
Machine learning
machine learning approach
Mathematical models
Mechanical properties
Methods
Optimization
Plastic deformation
Powder metallurgy
Powders
Process parameters
Response surface methodology
severe plastic deformation
Shear strain
Silicon carbide
Specific gravity
Egypt
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Summary:This work investigates the efficacy of high-pressure torsion (HPT), as a severe plastic deformation mechanism for processing plain and silicon-carbide-reinforced AA6061, with the broader objective of using the technique for improving the properties of lightweight materials for a range of objectives. The interactions between input variables, such as the pressure and equivalent strain (εeq) applied during HPT processing, and the presence of SiCp and response variables, like the relative density, grain refinement, homogeneity of the structure, and the mechanical properties of the AA6061 aluminum matrix, were investigated. Hot compaction (HC) of the mixed powders followed by HPT were employed to produce AA6061 discs with and without 15% SiCp. The experimental findings were then analyzed statistically using the response surface methodology (RSM) and a machine learning (ML) approach to predict the output variables and to optimize the input parameters. The optimum combination of HPT process parameters was confirmed by the genetic algorithm (GA) and ML approaches. Furthermore, the constructed ML and RSM models were validated experimentally by HPT processing the same material under new conditions not fed into the models and comparing the experimental results to those predicted by the model. From the ML and RSM models, it was found that processing the AA6061/SiCp composite HPT via four revolutions at 3 GPa produced the highest mechanical properties coupled with significant grain refinement compared to the HC condition. ML analysis revealed that the equivalent strain induced by the number of revolutions was the most effective parameter for grain refinement, whereas the presence of SiCp played the highest role in improving both the hardness values and the compressive strength of the AA6061 matrices.
ISSN:2504-4494
2504-4494
DOI:10.3390/jmmp7040148