An experimental study on the abrasive flow machining of aluminum alloy (AA 2024)

An experimental study on the abrasive flow machining of aluminum alloy (AA 2024)

The drilling and boring of the aluminum alloys tubes have a significant challenge in surface defects and burr phenomena. There is an ever-increasing demand for the surface modification and deburring of these components in the manufacturing industries. Most of the advanced machining processes have te...

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Bibliographic Details
Published in:SN applied sciences Vol. 5; no. 5; pp. 151 - 12
Main Authors: Choopani, Yahya, Khajehzadeh, Mohsen, Razfar, Mohammad Reza
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-05-2023
Springer Nature B.V
Springer
Subjects:
Abrasive flow machining
Abrasive machining
Abrasive media
Alloys
Aluminum
Aluminum alloy (AA2024)
Aluminum alloys
Aluminum base alloys
Applied and Technical Physics
Boring
Chemistry/Food Science
Deburring
Drilling
Earth Sciences
Empirical analysis
Engineering
Environment
Integrity
Investigations
Manufacturing industry
Material removal
Materials Science
Metal fatigue
Morphology
Research Article
Residual stress
Surface defects
Surface finish
Surface roughness
Tubes
Viscosity
Surface roughness
Material removal
Aluminum alloy (AA2024)
Abrasive flow machining
Abrasive media
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Summary:The drilling and boring of the aluminum alloys tubes have a significant challenge in surface defects and burr phenomena. There is an ever-increasing demand for the surface modification and deburring of these components in the manufacturing industries. Most of the advanced machining processes have technological restrictions to overcome these challenges. This paper proposes abrasive flow machining (AFM) to meet these requirements. To explore the machining performance, experiments were conducted on the internal surface of tubes made of aluminum alloys (AA2024) in the various number of AFM cycles for studying and observing its behavior on the surface roughness (Ra) and material removal (MR) characteristics with an empirical approach. The empirical findings prove that the AFM process is effective and efficient for machining the internal surface of tubes AA2024 because the Ra value has been remarkably reduced from 1.785 to 0.474 µm and the maximum value of MR has been obtained up to the range of 42 mg. Moreover, surface morphology analysis shows that the boring operation has generated a rough surface full of surface defects. In contrast, the AFM process has produced a smooth surface without surface defects, improving the surface integrity of tubes AA2024. Article Highlights The abrasive flow machining (AFM) process is proposed for the surface modification of aluminum alloys (AA2024). The various AFM cycles have been studied for the AFM of AA2024 to evaluate its effect on Ra, MR, and surface morphology. The surface finish of AA2024 was improved by 73.44% with better surface integrity using the AFM process.
ISSN:2523-3963
2523-3971
DOI:10.1007/s42452-023-05370-3