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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1140Intrinsic Hybrid Composites for Lightweight...

Intrinsic Hybrid Composites for Lightweight Structures: Tooling Technologies

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Abstract:

The increasing use of hybrid materials requires efficient manufacturing processes. With the concept of the intrinsic hybrids the shaping or forming of the part is combined with the hybridization in the same process step and thereby the same tool. Hence new tooling concepts, which realise the process requirements, are necessary. This paper describes tooling concepts and design methods for the manufacturing of intrinsic hybrid parts. Different solutions for rotational and planar parts with thermosetting or thermoplastic matrix material are presented. Additionally the integration of inserts in such tools is discussed. Finally the main challenges for the design of tools for intrinsic hybrids will be presented.

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Periodical:

Advanced Materials Research (Volume 1140)

Pages:

247-254

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1140.247

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Cite this paper

Online since:

August 2016

Authors:

Zheng Wang*, Matthias Riemer, Simon Frederik Koch, Daniel Barfuss, Raik Grützner, Florian Augenthaler, Jan Schwennen

Keywords:

Fiber Reinforced Plastic, Intrinsic Hybrid, Tool Design

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* - Corresponding Author

[1] W. X. Wang, T. Matsubara, Y. Takao, K. Yasuda, R. Hayashi, Effects of curing conditions on the short time co-cure of CFRP–steel hybrid laminates, Journal of Reinforced Plastics and Composites. 34 (2015) 819–829.

DOI: 10.1177/0731684415582281

[2] C. Lauter, M. Sarrazin, T. Thomas, Multimaterialsysteme höchstfest verbunden, adhesion KLEBEN & DICHTEN. 55 (2011) 39-43.

DOI: 10.1365/s35145-011-0015-0

[3] H. Funken, Systematische Entwicklung von Ultra-Leichtbaukonstruktionen in Faserverbund-Wabensandwichbauweise am Beispiel eines Kleinflugzeuges, Paderborn: Laboratorium für Konstruktionslehre, (2001).

[4] F. Klocke, W. König, Fertigungsverfahren 4., Springer-Verlag, Berlin, (2006).

[5] M. Neitzel, P. Mitschang, U. Breuer, Handbuch Verbundwerkstoffe, Werkstoffe, Verarbeitung, Anwendung, Carl Hanser Verlag, München, (2014).

DOI: 10.3139/9783446436978.fm

[6] A. Albert, W.G. Drossel, W. Zorn, Active media based forming fort he in-situ manufacturing of metal plastic composite, Euro Hybrid Materials and Structures 2014 Proceedings, 2014, 152-159.

[7] Corus Technology, Method and device for producing a composite product produced therewith, U.S. Patent US20050127564 A1 (2003).

[8] E. Bürkle, H. Wobbe, Kombinationstechnologien auf Basis des Spritzgießverfahrens, Carls Hanser Verlag, München, (2016).

DOI: 10.3139/9783446446083.fm

[9] H.C. Schmidt, U. Damerow, C. Lauter, B. Gorny, F. Hankeln, W. Homberg, T. Troester, H.J. Maier, R. Mahnken, Manufacturing porcesses for combined forming of multi-material structures consisting of sheet metal and local CFRP reinforcements, Key Engineering Materials. 504-506 (2012).

DOI: 10.4028/www.scientific.net/kem.504-506.295

[10] W. Hufenbach, L. Kroll, M. Gude, O. Helms, T. Seung, Beanspruchungsgerechte Krafteinleitungen für Luftfahrt-Hydraulikaktuatoren in Faserverbund-Leichtbauweise, Konstruktion. 58 (2006) 71-74.

[11] O. Helms, Konstruktion und technologische Umsetzung von hochbeanspruchten Lasteinleitungselementen für neuartige Leichtbaustrukturen in Faserverbundbauweise. TU Dresden, Dissertation, (2006).

[12] J. Fleischer, S. -F. Koch, S. Coutandin, Manufacturing of polygon fiber reinforced plastic profiles by rotational moulding and intrinsic hybridization, Prod. Eng. Res. Devel. 9 (2015) 317-328.

DOI: 10.1007/s11740-015-0620-0

[13] S. -F. Koch, M. Dackweiler, F. Pottmeyer, J. Fleischer, Intrinsische Hybridisierung im Schleuderverfahren, Lightweight Design. 4 (2015) 12-18.

DOI: 10.1007/s35725-015-0026-0

[14] ISO 8667, Commercial vehicles and buses; Cross-tooth gearbox flanges, type T, (1992).

DOI: 10.3403/00164816u

[15] D. Barfuss, R. Grützner, C. Garthaus, M. Gude, R. Müller, D. Langrebe; Intrinsic manufacture of hollow thermoplastic composite/metal structures, Proceedings 19th ESAFORM, 27th - 29th April AIP Publishing, (2016).

DOI: 10.1063/1.4963580

[16] Z. Wang, C. Lauter, B. Sanitther, M. Frantz, T. Tröster, Intrinsic Manufacturing of Metal-FRP-Hybrid Structural Automotive Components by Resin Transfer Moulding, 18th ICCS, Lisbon, (2015).

[17] R. Haase, R. Müller, D. Landgrebe, P. Scholz, M. Riemer, Process Design for Hybrid Sheet Metal Components, Acta Metall. Sin. (Engl. Lett). 28 (2015) 1518-1524.

DOI: 10.1007/s40195-015-0352-3

[18] C. Zinn, Intrinsische Herstellung hybrider Strukturkomponenten in einem modizifierten RTM-Prozess, DGM-Fachausschuss Hybride Werkstoffe und Strukturen, Paderborn, (2015).