Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates

Christian T. Poppe; Moritz Kruse; Luise Kärger

doi:10.21741/9781644902479-24

Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates

Christian T. Poppe^*
, Moritz Kruse
, Luise Kärger

^*Korrespondierende/r Autor/-in für diese Arbeit

Professur für Fertigungstechnik - Innovative Fertigungstechnologien

Publikation: Beiträge in Sammelwerken › Aufsätze in Konferenzbänden › Forschung › Begutachtung

1 Zitat (Scopus)

92 Downloads (Pure)

Abstract

Fiber-metal-laminates (FML) provide excellent fatigue behavior, damage-tolerant properties, and inherent corrosion resistance. A 2017-developed single-step process that combines deep-drawing with simultaneous infiltration (in-situ-hybridization) yields promising results. However, Fluid-Structure-Interaction (FSI) between the hybrid stack and the fluid pressure complicated the defect-free processing of double-curved parts. In this work, a Finite Element (FE) simulation approach for modeling the in-situ hybridization of FMLs is expanded to incorporate a both-sided (strong) FSI, aiming to facilitate apriori virtual support for process- and part development. Using Terzaghi’s effective stress formulation, the proposed framework can predict metal sheet buckling and resin accumulation resulting from local fluid pressure during infiltration of the textile interlayers on part level. Different conditions are simulated, outlining the high relevance of considering strong FSI during process simulation. The part-level results are compared with experimental findings. Modeling challenges are discussed, along with suggested future enhancements of the simulation approach.

Originalsprache	Englisch
Titel	Material Forming - The 26th International ESAFORM Conference on Material Forming – ESAFORM 2023 : The 26th International ESAFORM Conference on Material Forming - ESAFORM 2023
Redakteure/-innen	Lukasz Madej, Mateusz Sitko, Konrad Perzynski
Seitenumfang	12
Erscheinungsort	Krakow
Herausgeber (Verlag)	MaterialsResearchForum LLC
Erscheinungsdatum	19.04.2023
Seiten	219-230
ISBN (elektronisch)	978-1-64490-247-9
DOIs	https://doi.org/10.21741/9781644902479-24
Publikationsstatus	Erschienen - 19.04.2023
Veranstaltung	26th International ESAFORM Conference on Material Forming 2023 - AGH University of Science and Technology, Kraków, Polen Dauer: 19.04.2023 → 21.04.2023 Konferenznummer: 26 https://esaform2023.agh.edu.pl/

Bibliographische Notiz

Funding Information:
The authors would like to thank the German Research Foundation (DFG) for funding the projects BE 5196/4-1 and BE 5196/4-2. Moreover, the authors would like to thank the German Federal Ministry of Education and Research (BMBF) for the funding of the project" HyWet" (03INT614AC) as part of the Transatlantic Cluster for Lightweighting (TraCLight), for which some presented numerical methods were developed. This work is also part of the Young Investigator Group (YIG)" Tailored Composite Materials for Lightweight Vehicles", gratefully funded by the Vector Stiftung.

Publisher Copyright:
© 2023, Association of American Publishers. All rights reserved.

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10.21741/9781644902479-24Lizenz: CC BY

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Gezielte Einstellung gradierter Eigenschaften unter Nutzung der in-situ Hybridisierung zur Herstellung eigenschaftsoptimierter, thermoplastbasierter Faser-Metall Laminate
Ben Khalifa, N. (Wissenschaftliche Projektleiter*in), Chen, H. (Projektmitarbeiter*in) & Kruse, M. (Projektmitarbeiter*in)
Deutsche Forschungsgemeinschaft
01.08.20 → 30.06.22
Projekt: Forschung
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Ben Khalifa, N. (Wissenschaftliche Projektleiter*in), Henning, F. (Wissenschaftliche Projektleiter*in) & Weidenmann, K. A. (Wissenschaftliche Projektleiter*in)
Deutsche Forschungsgemeinschaft
01.07.18 → 31.12.18
Projekt: Forschung

Dieses zitieren

Poppe, C. T., Kruse, M., & Kärger, L. (2023). Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates. in L. Madej, M. Sitko, & K. Perzynski (Hrsg.), Material Forming - The 26th International ESAFORM Conference on Material Forming – ESAFORM 2023: The 26th International ESAFORM Conference on Material Forming - ESAFORM 2023 (S. 219-230). (Materials Research Proceedings; Band 28). MaterialsResearchForum LLC. https://doi.org/10.21741/9781644902479-24

Poppe, Christian T. ; Kruse, Moritz ; Kärger, Luise. / Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates. Material Forming - The 26th International ESAFORM Conference on Material Forming – ESAFORM 2023: The 26th International ESAFORM Conference on Material Forming - ESAFORM 2023. Hrsg. / Lukasz Madej ; Mateusz Sitko ; Konrad Perzynski. Krakow : MaterialsResearchForum LLC, 2023. S. 219-230 (Materials Research Proceedings).

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abstract = "Fiber-metal-laminates (FML) provide excellent fatigue behavior, damage-tolerant properties, and inherent corrosion resistance. A 2017-developed single-step process that combines deep-drawing with simultaneous infiltration (in-situ-hybridization) yields promising results. However, Fluid-Structure-Interaction (FSI) between the hybrid stack and the fluid pressure complicated the defect-free processing of double-curved parts. In this work, a Finite Element (FE) simulation approach for modeling the in-situ hybridization of FMLs is expanded to incorporate a both-sided (strong) FSI, aiming to facilitate apriori virtual support for process- and part development. Using Terzaghi{\textquoteright}s effective stress formulation, the proposed framework can predict metal sheet buckling and resin accumulation resulting from local fluid pressure during infiltration of the textile interlayers on part level. Different conditions are simulated, outlining the high relevance of considering strong FSI during process simulation. The part-level results are compared with experimental findings. Modeling challenges are discussed, along with suggested future enhancements of the simulation approach.",

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note = "Publisher Copyright: {\textcopyright} 2023, Association of American Publishers. All rights reserved.; 26th International ESAFORM Conference on Material Forming 2023, ESAFORM 2023 ; Conference date: 19-04-2023 Through 21-04-2023",

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Poppe, CT, Kruse, M & Kärger, L 2023, Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates. in L Madej, M Sitko & K Perzynski (Hrsg.), Material Forming - The 26th International ESAFORM Conference on Material Forming – ESAFORM 2023: The 26th International ESAFORM Conference on Material Forming - ESAFORM 2023. Materials Research Proceedings, Bd. 28, MaterialsResearchForum LLC, Krakow, S. 219-230, 26th International ESAFORM Conference on Material Forming 2023, Kraków, Polen, 19.04.23. https://doi.org/10.21741/9781644902479-24

Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates. / Poppe, Christian T.; Kruse, Moritz; Kärger, Luise.
Material Forming - The 26th International ESAFORM Conference on Material Forming – ESAFORM 2023: The 26th International ESAFORM Conference on Material Forming - ESAFORM 2023. Hrsg. / Lukasz Madej; Mateusz Sitko; Konrad Perzynski. Krakow: MaterialsResearchForum LLC, 2023. S. 219-230 (Materials Research Proceedings; Band 28).

Publikation: Beiträge in Sammelwerken › Aufsätze in Konferenzbänden › Forschung › Begutachtung

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AU - Kruse, Moritz

AU - Kärger, Luise

N1 - Conference code: 26

PY - 2023/4/19

Y1 - 2023/4/19

N2 - Fiber-metal-laminates (FML) provide excellent fatigue behavior, damage-tolerant properties, and inherent corrosion resistance. A 2017-developed single-step process that combines deep-drawing with simultaneous infiltration (in-situ-hybridization) yields promising results. However, Fluid-Structure-Interaction (FSI) between the hybrid stack and the fluid pressure complicated the defect-free processing of double-curved parts. In this work, a Finite Element (FE) simulation approach for modeling the in-situ hybridization of FMLs is expanded to incorporate a both-sided (strong) FSI, aiming to facilitate apriori virtual support for process- and part development. Using Terzaghi’s effective stress formulation, the proposed framework can predict metal sheet buckling and resin accumulation resulting from local fluid pressure during infiltration of the textile interlayers on part level. Different conditions are simulated, outlining the high relevance of considering strong FSI during process simulation. The part-level results are compared with experimental findings. Modeling challenges are discussed, along with suggested future enhancements of the simulation approach.

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KW - fea

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Poppe CT, Kruse M, Kärger L. Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates. in Madej L, Sitko M, Perzynski K, Hrsg., Material Forming - The 26th International ESAFORM Conference on Material Forming – ESAFORM 2023: The 26th International ESAFORM Conference on Material Forming - ESAFORM 2023. Krakow: MaterialsResearchForum LLC. 2023. S. 219-230. (Materials Research Proceedings). doi: 10.21741/9781644902479-24

Modeling of 3D fluid-structure-interaction during in-situ hybridization of double-curved fiber-metal-laminates

Abstract

Bibliographische Notiz

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Gezielte Einstellung gradierter Eigenschaften unter Nutzung der in-situ Hybridisierung zur Herstellung eigenschaftsoptimierter, thermoplastbasierter Faser-Metall Laminate

In situ Hybridisierung beim Tiefziehen - Thermoplastische Faser-Metall-Laminatbauteile (FML) basierend auf reaktiv verarbeitetem Gusspolyamid 6

Dieses zitieren