Photo-chemically induced polycondensation of a pure phenolic resin for additive manufacturing

Bakelite © or phenoplasts are considered the first synthetic polymers in the world. These resins, produced by polycondensation, have always been known for their chemical resistance, excellent flame resistance and thermal stability. Originally, pressure and temperature are required for processing and...

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Veröffentlicht in:	Polymer chemistry 2022-02, Vol.13 (6), p.768-777
Hauptverfasser:	Wolff, Raffael, Ehrmann, Katharina, Knaack, Patrick, Seidler, Konstanze, Gorsche, Christian, Koch, Thomas, Stampfl, Jürgen, Liska, Robert
Format:	Artikel
Sprache:	eng
Schlagworte:	3-D printers Additive manufacturing Bakelite Fire resistance High temperature Injection molding Lithography Manufacturing Phenolic resins Photoresists Polymer chemistry Polymers Pressure molding Resins Thermal analysis Thermal resistance Thermal stability Three dimensional printing Vinyl resins
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creator	Wolff, Raffael Ehrmann, Katharina Knaack, Patrick Seidler, Konstanze Gorsche, Christian Koch, Thomas Stampfl, Jürgen Liska, Robert
description	Bakelite © or phenoplasts are considered the first synthetic polymers in the world. These resins, produced by polycondensation, have always been known for their chemical resistance, excellent flame resistance and thermal stability. Originally, pressure and temperature are required for processing and limited the production of phenoplasts to compression and injection molding. However, with the invention of lithography and 3D printing, new desirable processing possibilities have emerged. Previous work in the area of additive manufacturing of phenoplasts has focused on thin-layer photoresists or parts that can only be printed using other polymers as a matrix. Here we report direct 3D printing of phenoplasts, without binders or matrix polymers, using Hot Lithography, a stereolithography-based 3D printing technology at elevated temperatures. In simultaneous thermal analysis and photo-DSC experiments we investigated suitable conditions for the UV-induced polycondensation of the phenolic resins. Based on these experiments, formulations are presented, which are stable under the selected printing conditions and yet reactive enough for the printing process. Direct 3D printing with Hot Lithography and post-curing gave bubble-free specimens, thus a simple production of complicated structures could be achieved without the conventional complex injection molding and more importantly the first bulk polycondensation process using this technique. Additive manufacturing of phenolic resins as a proof-of-concept for the first photo-chemical induced polycondensation by Hot Lithography. Through the dual use of a photoacidgenerator, the first pure 3D printing of Bakelite © is investigated.
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Based on these experiments, formulations are presented, which are stable under the selected printing conditions and yet reactive enough for the printing process. Direct 3D printing with Hot Lithography and post-curing gave bubble-free specimens, thus a simple production of complicated structures could be achieved without the conventional complex injection molding and more importantly the first bulk polycondensation process using this technique. Additive manufacturing of phenolic resins as a proof-of-concept for the first photo-chemical induced polycondensation by Hot Lithography. 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subjects	3-D printers Additive manufacturing Bakelite Fire resistance High temperature Injection molding Lithography Manufacturing Phenolic resins Photoresists Polymer chemistry Polymers Pressure molding Resins Thermal analysis Thermal resistance Thermal stability Three dimensional printing Vinyl resins
title	Photo-chemically induced polycondensation of a pure phenolic resin for additive manufacturing
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