PLA 3D打印废弃物机械回收技术评价

F. Beltrán, M. Arrieta, E. Moreno, G. Gaspar, L. M. Muneta, Ruth Carrasco-Gallego, Susana Yáñez, David Hidalgo-Carvajal, M. U. Orden, J. Urreaga
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引用次数: 15

摘要

3D打印PLA废料是从一个众所周知的参考等级和从不同的来源回收。回收后的废弃物经过能量洗涤步骤,然后通过熔融挤压再加工成薄膜,然后进行压缩成型以模拟工业加工条件。对所得材料进行了表征,并报道了材料的光学、结构、热学和结晶行为。机械回收过程导致配方的结晶度增加和特性粘度降低,特别是在基于不同3D-PLA废物共混的样品中。此外,获得的薄膜在堆肥条件下不到一个月就分解了,并且观察到回收材料的降解速度比开始的3D-PLA长丝要快,因为存在更短的聚合物链。最后,为了增加回收材料的分子量,将3D-PLA废料在110、120和130℃下进行固态聚合,观察到基于已知参考品位的3D-PLA废料的特性粘度得到改善,而来自不同来源的3D-PLA废料的特性粘度没有明显变化。综上所述,3D打印PLA产品为分布式回收方案的实施提供了理想的环境,来自知名PLA等级的废弃物可以成功地加工成综合性能良好的薄膜。
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Technical Evaluation of Mechanical Recycling of PLA 3D Printing Wastes
3D printing PLA wastes were recovered from a well-known reference grade and from different sources. The recovered wastes were subjected to an energic washing step and then reprocessed into films by melt-extrusion, followed by compression molding to simulate the industrial processing conditions. The obtained materials were characterized and the optical, structural, thermal and crystallization behavior are reported. The mechanical recycling process leads to an increase of the crystallinity and a decrease of the intrinsic viscosity of the formulations, particularly in the sample based on blends of different 3D-PLA wastes. Moreover, the obtained films were disintegrated under composting conditions in less than one month and it was observed that recycled materials degrade somewhat faster than the starting 3D-PLA filament, as a consequence of the presence of shorter polymer chains. Finally, to increase the molecular weight of the recycled materials, the 3D-PLA wastes were submitted to a solid-state polymerization process at 110, 120, and 130 °C, observing that the recycled 3D-wastes materials based on a well-known reference grade experiences an improvement of the intrinsic viscosity, while that coming from different sources showed no significant changes. Thus, the results show that 3D printing PLA products provides an ideal environment for the implementation of distributed recycling program, in which wastes coming from well-known PLA grades can successfully be processed in films with good overall performance.
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