Investigation on the Crack and Thinning Behavior of Aluminum Alloy 5052 Sheet in Stretch Flanging Process

Stretch flanging is the important sheet metal-forming process which is widely used in automobile and aerospace sectors. The formability of sheet metal depends on various parameters such as material properties, geometry of the tool setup and process parameters. In the present work, effects of differe...

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Bibliographic Details
Published in:Journal of failure analysis and prevention 2020-08, Vol.20 (4), p.1212-1228
Main Authors: Kumar, Surendra, Ahmed, M., Panthi, S. K.
Format: Article
Language:English
Subjects:
Aerospace industry
Aluminum base alloys
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Computer simulation
Corrosion and Coatings
Crack propagation
Deformation effects
Dies
Dimpling
Edge cracks
Flanging
Material properties
Materials Science
Metal sheets
Process parameters
Quality Control
Reliability
Safety and Risk
Simulation
Solid Mechanics
Strain distribution
Stress concentration
Technical Article > -Peer-Reviewed
Tribology
Weight reduction
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Summary:Stretch flanging is the important sheet metal-forming process which is widely used in automobile and aerospace sectors. The formability of sheet metal depends on various parameters such as material properties, geometry of the tool setup and process parameters. In the present work, effects of different die radius and sheet width on deformation behavior of sheet are studied by FEM simulation and experiments. The predicted FEM results are presented in the form of edge crack location and its propagation, crack length, forming load and strain distribution in sheet along the die profile radius. This study indicates that crack length increases with increase in the sheet width, while the crack length decreases with increase in the die radius. It is found that the crack propagation in stretch flanging process is affected by the strain distribution in sheet and this distribution of strain depends on many parameters. The crack initiates during deformation of the sheet at the die corner edge and propagates toward the center of the sheet along the die profile radius. Simulation results are compared with the experimental one in terms of crack length and variation in sheet thickness. FE simulation results are found in very good agreement with experimental results. Fractography study is also presented in terms of size, shape of the dimples along with their distribution on the fractured surface.
ISSN:1547-7029
1728-5674
1864-1245
DOI:10.1007/s11668-020-00922-w