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Deformation by design: data-driven approach to predict and modify deformation in thin Ti-6Al-4V sheets using laser peen forming
Citation Link: https://doi.org/10.15480/882.8939
Publikationstyp
Journal Article
Publikationsdatum
2023
Sprache
English
Author
Sala, Siva Teja
Pöltl, Dominik
Enthalten in
Citation
Journal of Intelligent Manufacturing (in Press): (2023)
Publisher DOI
Scopus ID
Abstract: The precise bending of sheet metal structures is crucial in various industrial and scientific applications, whether to modify deformation in an existing component or to achieve specific shapes. Laser peen forming (LPF) is proven as an innovative forming process for sheet metal applications. LPF involves inducing mechanical shock waves into a specimen that deforms the affected region to a certain desired curvature. The degree of deformation induced after LPF depends on numerous experimental factors such as laser energy, the number of peening sequences, and the thickness of the specimen. Consequently, comprehending the complex dependencies and selecting the appropriate set of LPF process parameters for application as a forming or correction process is crucial. The main objective of the present work is the development of a data-driven approach to predict the deformation obtained from LPF for various process parameters. Artificial neural network (ANN) was trained, validated, and tested based on experimental data. The deformation obtained from LPF is successfully predicted by the trained ANN. A novel process planning approach is developed to demonstrate the usability of ANN predictions to obtain the desired deformation in a treated region. The successful application of this approach is demonstrated on three benchmark cases for thin Ti-6Al-4V sheets, such as deformation in one direction, bi-directional deformation, and modification of an existing deformation in pre-bent specimens via LPF. Graphical abstract: [Figure not available: see fulltext.].
Schlagworte
Artificial neural networks
Dimensional analysis
Laser peen forming (LPF)
Machine learning
Process planning
MLE@TUHH
DDC Class
620: Engineering
Publication version
publishedVersion
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Name
s10845-023-02240-y.pdf
Type
main article
Size
3.02 MB
Format
Adobe PDF