在增材制造中提高回收细粉玻璃 (RFPG) 的价值:聚对苯二甲酸乙二酯(PETG)中 RFPG 含量的优化与多反应分析

Markos Petousis , Nikolaos Michailidis , Václav Kulas , Vassilis Papadakis , Mariza Spiridaki , Nikolaos Mountakis , Apostolos Argyros , John Valsamos , Emmanouel Stratakis , Nectarios Vidakis
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摘要

循环经济和以可持续发展为导向的生产是该行业的关键方面。回收原料正逐步取代原生材料来生产零部件,并作为可持续添加剂来开发生态友好型复合材料。本文研究了回收细粉玻璃(FPG)对对苯二甲酸乙二醇酯(PETG)的增强潜力。将六种不同化合物(FPG 含量分别为 2.0、4.0、6.0、8.0、10.0 和 12.0 wt%)的长丝和三维(3D)试样形式(采用材料挤压 - MEX 方法制造)的性能与纯 PETG 进行了比较。这项研究包括热学和流变学分析、机械测试以及形态和结构调查。研究结果表明,PETG/RFPG 8.0 wt%复合材料在拉伸和弯曲测试中表现出色(强度分别提高了 16.3% 和 16.9%),而 PETG/RFPG 10.0 wt%复合材料在显微硬度方面表现最好。PETG/RFPG 6.0 wt% 的尺寸偏差和孔隙率结果都显示出其优异的性能,与纯 PETG 相比分别提高了 67.3% 和 87.1%。这些结果表明,RFPG 是一种很有前途的 MEX 三维打印增强添加剂,它可以取代常用的无机填料,促进三维打印的可持续发展。
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Valorization of recycled fine powder glass (RFPG) in additive manufacturing: Optimization of the RFPG content in polyethylene terephthalate glycol (PETG) and multi-response analysis
A cyclic economy and sustainability-driven production are key aspects of the industry. Recycled feedstocks are steadily replacing virgin materials to produce parts and as sustainable additives to develop eco-friendly composites. The reinforcing potential of recycled fine powder glass (FPG) on terephthalate glycol (PETG) is investigated. The performances of six different compounds (with FPG loadings of 2.0, 4.0, 6.0, 8.0, 10.0, and 12.0 wt%) in filament and three-dimensional (3D) specimens form (manufactured with the material extrusion – MEX method) were compared with PETG pure. This research included thermal and rheological analyses, mechanical tests, and morphological and structural investigations. According to these findings, the PETG/RFPG 8.0 wt% composite presented remarkable results in the tensile and flexural (16.3 % and 16.9 % strength increase, respectively) tests, while PETG/RFPG 10.0 wt% had the greatest performance concerning microhardness. Both the dimensional deviation and porosity results show excellent performance in the case of PETG/RFPG 6.0 wt%, by being 67.3 % and 87.1 % improved vs. the PETG pure. These results indicate that RFPG is a promising reinforcement additive for MEX 3D printing that can replace the commonly used inorganic fillers and promote the sustainability of 3D printing.
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