Production of 3D Parts from Wood Chips in a Closed Mold Process

Robert Hartmann; Michael Koch

doi:10.4028/www.scientific.net/MSF.825-826.1027

Paper Titles

3D-FIB Characterization of Wear in WC-Co Coated Composites
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Bimodal Particle Reinforcement for Wear Resistant Powder Metallurgy Steels
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Control of the Cobalt Surface Layer Formation on Cemented Carbides
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Gigacycle Fatigue Behaviour of Sintered WC-Co Hardmetals Investigated by Ultrasonic Resonance Testing
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Production of 3D Parts from Wood Chips in a Closed Mold Process
p.1027

Bio-Pultrusion of Façade-Profiles from Sustainable Materials
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Processing and Characterization of Wood Plastic Composites from Bio-Based Polyamide 11 and Chemically Modified Beech Fibers
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Impact Resistance Bio Compound
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New Biocomposites for Lightweight Structures and their Processes
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HomeMaterials Science ForumMaterials Science Forum Vols. 825-826Production of 3D Parts from Wood Chips in a Closed...

Production of 3D Parts from Wood Chips in a Closed Mold Process

Abstract:

The application-oriented distribution of wood chips is a major obstacle in the production of 3D molded composite parts made of plastics and wood. Similar to fibers in conventional fiber-reinforced plastic components long chips can be used for force transmission. Short chips and wood powder can be distributed homogeneously between longer chips to increase the wood volume percentage and to allow post-processing-free edge areas. The applied process parameters during the incorporation of the matrix material determine the filling of the cavity and the impregnation of the chips. Different formaldehyde-free resin and adhesive systems, as well as thermoplastic powders are used as matrix material. By controlling the subsequent pressing process of the oriented and impregnated chips the density and wall thickness of the molded part can be influenced. In this work different production process variants and a concept for a modular 3D experimental mold are investigated. The flowability and bulk density of the wood chip fractions are characterized and the compression pressure required in the production process is determined. Initial tests with a panel mold are carried out and the bending strength of the manufactured specimen is examined.

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Periodical:

Materials Science Forum (Volumes 825-826)

Pages:

1027-1032

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.825-826.1027

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Online since:

July 2015

Authors:

Robert Hartmann*, Michael Koch

Keywords:

3D Mold, Flow Front Advancement, Formaldehyde Emission, Resin Transfer Molding, Wood Chips

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