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关于层压物体制造的熔融沉积成型(FDM)打印的ABS/TPU多材料试样:对其力学和形态特征的深入研究

On Laminated Object Manufactured FDM-Printed ABS/TPU Multimaterial Specimens: An Insight into Mechanical and Morphological Characteristics.

作者信息

Kumar S, Singh I, R Koloor S S, Kumar D, Yahya M Y

机构信息

Department of Mechanical Engineering, CT University, Ferozepur Rd, Sidhwan Khurd, Ludhiana 142024, Punjab, India.

Institute for Structural Engineering, Department of Civil Engineering and Environmental Sciences, Universität der Bundeswehr München, Werner-Heisenberg-Weg 39, 85579 Neubiberg, Germany.

出版信息

Polymers (Basel). 2022 Sep 28;14(19):4066. doi: 10.3390/polym14194066.

DOI:10.3390/polym14194066
PMID:36236014
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9573760/
Abstract

Fused deposition modeling (FDM) printing of commercial and reinforced filaments is a proven and well-explored method for the enhancement of mechanical properties. However, little has hitherto been reported on the multi-material components, fused or laminated together into a single specimen by using the laminated object manufacturing (LOM) technique for sustainable/renewable polymers. TPU is one such durable and flexible, sustainable material exhibiting renewable and biocompatible properties that have been explored very less often in combination with the ABS polymer matrix in a single specimen, such as the LOM specimen. The current research work presents the LOM manufacturing of 3D-printed flexural specimens of two different, widely used polymers available viz. ABS and TPU and tested as per ASTM D790 standards. The specimens were made and laminated in three layers. They were grouped into two categories, namely ABS: TPU: ABS (ATA) and TPU: ABS: TPU (TAT), which are functionally graded, sandwiched structures of polymeric material. The investigation of the flexural properties, microscopic imaging, and porosity characteristics of the specimens was made for the above categories. The results of the study suggest that ATA-based samples held larger flexural strength than TAT laminated manufactured samples. A significant improvement in the peak elongation and break elongation of the samples was achieved and has shown a 187% increase in the break elongation. Similarly, for the TAT-based specimen, flexural strength was improved significantly from approximately 6.8 MPa to 13 MPa, which represents a nearly 92% increase in the flexural strength. The morphological testing using Tool Maker's microscopic analysis and porosity analysis has supported the observed trends of mechanical behavior of ATA and TAT samples.

摘要

商业长丝和增强长丝的熔融沉积成型(FDM)打印是一种成熟且经过充分探索的增强机械性能的方法。然而,迄今为止,关于通过使用分层实体制造(LOM)技术将多种材料融合或层压成单个试样的可持续/可再生聚合物的多材料组件的报道很少。热塑性聚氨酯(TPU)就是这样一种耐用、灵活的可持续材料,具有可再生和生物相容性,但在单个试样(如LOM试样)中与丙烯腈-丁二烯-苯乙烯共聚物(ABS)聚合物基体结合使用的情况很少被研究。当前的研究工作展示了使用两种不同的、广泛使用的聚合物进行3D打印弯曲试样的LOM制造,即ABS和TPU,并按照ASTM D790标准进行测试。试样制作并层压成三层。它们被分为两类,即ABS:TPU:ABS(ATA)和TPU:ABS:TPU(TAT),这是聚合物材料的功能梯度夹心结构。对上述类别试样的弯曲性能、微观成像和孔隙率特征进行了研究。研究结果表明,基于ATA的试样比TAT层压制造的试样具有更大的弯曲强度。试样的峰值伸长率和断裂伸长率有显著提高,断裂伸长率增加了187%。同样,对于基于TAT的试样,弯曲强度从约6.8MPa显著提高到13MPa,弯曲强度提高了近92%。使用工具制造商显微镜分析和孔隙率分析进行的形态测试支持了ATA和TAT试样观察到的力学行为趋势。

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