Generating Permanent and Temporary Material Compounds in FLM Processes

Christoph Doerffel; Raik Schmidt; Mirko Spieler; Wolfgang Nendel; Lothar Kroll; Jens Petzold; David Schreiter; Mathias Hunold

doi:10.4028/www.scientific.net/KEM.809.353

Paper Titles

Ultrasonic Assisted Thermal Direct Joining of Thermoplastic Composites and Aluminum for Multi Material Design
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Influence of Composition on Mechanical Properties of Additively Manufactured Composites Reinforced with Endless Carbon Fibers
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Surface Topography Influences on the Fatigue Behavior of Composite Joints
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Deflection Sheaves for Elevator Application in Lightweight Design
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Generating Permanent and Temporary Material Compounds in FLM Processes
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Analysis of a Process Approach for Production of Triaxial Braids with Locally Customized Filler Yarn Count
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Comparison of Electroplated Ni and PVD Ni Coating Layers after Soft Soldering Process
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Manufacturing CFRP-Parts Using a Modified Co-Curing Method – Fundamental Experimental Analysis
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Temperature- and Time-Dependent Penetration of Surface Structures in Thermal Joining of Plastics to Metals
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 809Generating Permanent and Temporary Material...

Generating Permanent and Temporary Material Compounds in FLM Processes

Abstract:

Like all additive manufactured parts, FLM (fused-layer-modeling) components are characterized by a large number of joints between the similar and different materials. These joints can be divided into five categories:- Permanent cohesive bonds between single layers of the same thermoplastic material,- Permanent adhesive bonds between single layers of different thermoplastic materials- Temporary adhesive bonds between single layers of different thermoplastic materials,- Permanent adhesive bonds between a single layer of thermoplastic material and a non-thermoplastic base material,- Temporary adhesive bonds between a single layer of thermoplastic material and a non-thermoplastic base material.The first three types of bonds describe the binding process when parts are manufactured of base material, a second permanently bonded component or a support material that has good release properties. The last two types of connection describe the permanent connection between the printing part and a non-FLM-component or the temporary joint between the printed part and the build platform during the printing process. The resulting compounds can be characterized as material compounds.Since the FLM process is mainly used for design and hobby applications, the fundamentals of the bonding processes and their influence on the internal structure of the material are hardly described. Some information can be taken from the literature for welding plastics and the production of hybrid parts by injection molding. Due to the different pressure and temperature conditions as well as the very large surface-volume-ratio of the discharged strand occur significant differences in the following factors: melt flow, solidification time, formation of surface layers and wetting of the surfaces.The investigation and characterization of these effects as a function of external process parameters is an important constituent for the further development of the FLM process into an industrially suitable manufacturing process for thermoplastic components with very high lightweight and complex geometry in small series etc.

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Periodical:

Key Engineering Materials (Volume 809)

Pages:

353-359

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.809.353

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Online since:

June 2019

Authors:

Christoph Doerffel*, Raik Schmidt, Mirko Spieler, Wolfgang Nendel, Lothar Kroll, Jens Petzold, David Schreiter, Mathias Hunold

Keywords:

3D-Printing, Fused-Layer-Modeling, Hybrid Composite, Plastic Welding

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References

[1] C. Doerffel, R. Schmidt, M. Spieler, W. Nendel, L. Kroll, J. Petzold, D. Schreiter, Innovative Technologien für den granulatbasierten FLM-Druck, Tagungsband 16. Chemnitzer Textiltechniktagung pp.190-198, Chemnitz 2018 ISBN: 978-3-98-19946-0-5.

DOI: 10.4028/www.scientific.net/kem.809.353

Google Scholar

[2] Information on https://www.3d-druck-community.de/thread-349.html (28.01.2019).

Google Scholar

[3] Information on https://3dprintingblog.wordpress.com/2014/11/09/3d-druck-praxistipp-optimale-haftung-fur-die-ersten-schichten/ (28.01.2019).

Google Scholar

[4] C. Doerffel, A. Schwarzmeier, M. Spieler, W. Nendel, L. Kroll, Kostengünstige Ultraleichtgreifer in Hybridbauweise, Rapid.Tech - International Trade Show & Conference for Additive Manufacturing, 2016., pp.301-310, Carl Hanser Verlag München, 2016, Print-ISBN 978-3-446-45017-2.

DOI: 10.3139/9783446450608.026

Google Scholar

[5] J. Blase, M. Holzinger, M. Kausch, C. John Neuartige Hybridbauweisen durch Kombination von Textilhalbzeugen und additiv gefertigten Strukturen, Tagungsband 16. Chemnitzer Textiltechniktagung pp.112-118, Chemnitz 2018 ISBN: 978-3-98-19946-0-5.

Google Scholar

[6] S. Grießbach, Individualisierte Massenproduktion-Hybride Kunststoffbauteile mittels Lasersintern und Spritzguss, Tagungsband Technomer 2015, page 24, Chemnitz 2015 ISBN 978-3-939382-12-6.

Google Scholar

[7] Merlin Eberle, Untersuchung der Möglichkeiten der direkten Herstellung von Hybridbauteilen im FLM-Verfahren, not published student research paper, Chemnitz (2018).

Google Scholar

[8] H. Maus, P. Dohle, B.Clauß, K. Hofmann, Entwicklung eines 3D-Druckkopfes zur Fertigung großformatiger Kunststoff-Bauteile, Tagungsband Technomer 2017, page 141, Chemnitz 2017 ISBN 978-3-939382-13-3.

Google Scholar