Rapid tooling for rubber extrusion molding by digital light processing 3D printing with dual curable vitrimers

Rita Höller, Katja Hrbinič, David Reisinger, Walter Alabiso, Stephan Schuschnigg, Mathias Fleisch, Christoph Waly, Elisabeth Rossegger, Sandra Schlögl
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引用次数: 0

Abstract

For the manufacture of extrusion dies, three-dimensional (3D) printing with photopolymers offers numerous advantages including flexibility, high surface quality, decent build speed, low costs and a reduced amount of waste. However, the majority of photocurable resins used in vat photopolymerization 3D printing rely on acrylates, which entail 3D-printed objects with poor mechanical properties. In particular, the high brittleness limits their application in rapid tooling, for which tough materials with high glass transition temperatures (Tg) are required. In the present study, we highlight the use of dual curable acrylate-epoxy resins with dynamic covalent bonds for the direct fabrication of extrusion dies. During digital light processing (DLP) 3D printing the acrylate network is formed, whose toughness and thermal stability are significantly enhanced by the thermoactivated formation of a second network. By following a postbaking procedure, aminoglycidiyl monomers are cured with an anhydride hardener bearing bulky norbornene groups yielding interpenetrating polymer networks with a Tg > 100°C. The tertiary amine groups present in the structure of the aminoglycidyl derivatives do not only accelerate the ring-opening reaction but also act as internal catalysts and activate bond exchange reactions between free –OH groups and ester moieties available in the photopolymer. This is confirmed by rheometer studies showing a distinctive stress relaxation at elevated temperature and giving rise to a possible reprocessability of the 3D-printed dies. With a selected resin formulation, a set of dies is printed by DLP 3D printing, with which a highly filled rubber compound is successfully extruded. The results clearly show that dual curable resins with dynamic covalent bonds are a promising class of material for rapid tooling and pave the way towards a customized and convenient fabrication of extrusion dies for rubber processing.

Abstract Image

利用数字光处理 3D 打印技术和双固化玻璃缸实现橡胶挤压成型的快速模具制造
对于挤压模具的制造,使用光聚合物进行三维打印具有许多优势,包括灵活性、高表面质量、适当的构建速度、低成本和减少废料量。然而,大桶光聚合三维打印中使用的大多数光固化树脂都依赖于丙烯酸酯,这导致三维打印物体的机械性能较差。特别是,高脆性限制了它们在快速模具中的应用,而快速模具需要具有高玻璃化转变温度(Tg)的坚韧材料。在本研究中,我们重点介绍了使用具有动态共价键的双固化丙烯酸酯-环氧树脂直接制造挤压模具的方法。在数字光处理 3D 打印过程中,丙烯酸酯网络形成,通过热激活形成第二个网络,其韧性和热稳定性显著增强。通过后烘烤程序,氨基缩水甘油酯单体与带有大块降冰片烯基团的酸酐固化剂一起固化,形成互穿聚合物网络,Tg > 100°C。氨缩水甘油酯衍生物结构中的叔胺基团不仅能加速开环反应,还能充当内部催化剂,激活光聚合物中的游离 -OH 基团和酯分子之间的键交换反应。流变仪研究证实了这一点,该研究显示在温度升高时会出现明显的应力松弛,从而使 3D 打印模具具有可再加工性。利用选定的树脂配方,通过数字光处理三维打印技术打印出一套模具,并成功挤出了高填充度的橡胶复合物。研究结果清楚地表明,具有动态共价键的双固化树脂是一类很有前途的快速模具材料,并为定制和方便地制造橡胶加工挤出模具铺平了道路。本文受版权保护,保留所有权利。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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