Application of Polymer Plaster Composites in Additive Manufacturing of High-Strength Components

Stefan Junk; Rebecca Matt

doi:10.4028/www.scientific.net/MSF.825-826.763

Paper Titles

Experimental and Numerical Analyses of the Lightweight Potential for Hybrid Thin-Walled Members
p.732

Energy and Time Efficient Microwave Curing for CFRP Parts Manufactured by Filament Winding
p.741

Braiding of Branches for the Fibre Composite Technology
p.749

Applications of Variable-Axial Fibre Designs in Lightweight Fibre Reinforced Polymers
p.757

Application of Polymer Plaster Composites in Additive Manufacturing of High-Strength Components
p.763

Application of a Composite Hot Shearing Tool Manufactured by Co-Spray Forming
p.771

Reinforcement Elements Aligned with the Direction of Forces for Load Transfer Areas of Long-Fiber-Reinforced Thermoplastic Components
p.779

Online Poling of Thermoplastic-Compatible Piezoceramic Modules during the Manufacturing Process of Active Fiber-Reinforced Composites
p.787

New Sandwich Structures Consisting of Aluminium Foam and Thermoplastic Hybrid Laminate Top Layers
p.797

HomeMaterials Science ForumMaterials Science Forum Vols. 825-826Application of Polymer Plaster Composites in...

Application of Polymer Plaster Composites in Additive Manufacturing of High-Strength Components

Abstract:

Today, 3D-printing with polymer plaster composites is a common method in Additive Manufacturing. This technique has proven to be especially suitable for the production of presentation models, due to the low cost of materials and the possibility to produce color-models. But nowadays it requires refinishing through the manual application of a layer of resin. However, the strength of these printed components is very limited, as the applied resin only penetrates a thin edge layer on the surface. This paper develops a new infiltration technique that allows for a significant increase in the strength of the 3D-printed component. For this process, the components are first dehydrated in a controlled two-tier procedure, before they are then penetrated with high-strength resin. The infiltrate used in this process differs significantly from materials traditionally used for infiltration. The result is an almost complete penetration of the components with high-strength infiltrate. As the whole process is computer-integrated, the results are also easier to reproduce, compared to manual infiltration. On the basis of extensive material testing with different testing specimen and testing methods, it can be demonstrated that a significant increase in strength and hardness can be achieved. Finally, this paper also considers the cost and energy consumption of this new infiltration method. As a result of this new technology, the scope of applicability of 3D-printing can be extended to cases that require significantly more strength, like the production of tools for the shaping of metals or used for the molding of plastics. Furthermore, both the process itself and the parameters used are monitored and can be optimized to individual requirements and different fields of application.

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Periodical:

Materials Science Forum (Volumes 825-826)

Pages:

763-770

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.825-826.763

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Online since:

July 2015

Authors:

Stefan Junk*, Rebecca Matt

Keywords:

Additive Manufacturing, Binder Jetting, Infiltration, Polymer Plaster Composites, Resin

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