Fused Deposition Modeling of Carbon Fiber Reinforced High-Density Polyethylene: Effects on Microstructure and Mechanical Properties

IF 1 Q4 ENGINEERING, MANUFACTURING

Journal of Micro and Nano-Manufacturing Pub Date : 2022-06-27 DOI:10.1115/msec2022-85702

P. Pandit, Chang Liu, Giancarlo Corti, Yingbin Hu

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引用次数: 2

Abstract

Owing to its superior durability, good biocompatibility, and high recycling capability, high-density polyethylene (HDPE) has been widely applied into making prosthetic implants, liquid permeable membranes, corrosion-resistant pipes, etc., and gains its popularity in packaging, consumer goods, and chemical industries. Injection molding and blow molding are two most common conventional processes of making HDPE products. These conventional processes, however, are considered time-consuming and labor-intensive since molds are usually needed prior to fabricating parts. Moreover, manufacturing complex-structured parts (such as lattice and cellular structures) is a challenge for these conventional manufacturing processes. Facing these problems, it is crucial to find a time- and labor-saving process, which can be used to manufacture complicated structures in a cost-effective way. Additive manufacturing (AM) is such a process that needs no mold and is more affordable to create complex and highly customized parts. Among all types of AM processes, fused deposition modeling (FDM), which is primarily designed for thermoplastic materials, seemed to be a benevolent process for fabricating HDPE parts. Based on reported publications, however, it is difficult to print HDPE materials using FDM due to the problems of warping, shrinking, and weak bonding between printed HDPE parts and the substrate. In addition, the FDM-printed HDPE parts can demonstrate defects of porosities and delamination. To improve the printability of FDM, we conducted preliminary experiments and optimized processing parameters. For the first time, we added carbon fiber (CF) into HDPE to make CF-reinforced HDPE composites (CF-HDPE) using FDM and investigated the effects of CF on part quality, microstructure characteristics, and mechanical properties (including tensile properties and dynamic mechanical properties) of CF-reinforced HDPE composites. Experimental results show that the addition of CF was beneficial for not only improving the printability of FDM and quality of printed composite parts, but also for enhancing mechanical properties (such as Young’s Modulus and ultimate tensile strength) of the parts.

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碳纤维增强高密度聚乙烯的熔融沉积模型:对微观结构和力学性能的影响

高密度聚乙烯(HDPE)由于其优异的耐久性、良好的生物相容性和高回收能力，已被广泛应用于制造假体植入物、液体透膜、耐腐蚀管道等领域，在包装、消费品、化工等行业也得到了广泛的应用。注塑成型和吹塑成型是制造HDPE产品的两种最常见的常规工艺。然而，这些传统的工艺被认为是耗时和劳动密集型的，因为模具通常需要在制造零件之前。此外，制造复杂结构的部件(如晶格和细胞结构)对这些传统制造工艺来说是一个挑战。面对这些问题，寻找一种既省时又省力的工艺，以经济高效的方式制造复杂的结构是至关重要的。增材制造(AM)就是这样一种不需要模具的工艺，并且更经济地制造复杂和高度定制的零件。在所有类型的增材制造工艺中，主要为热塑性材料设计的熔融沉积建模(FDM)似乎是制造HDPE零件的有益工艺。然而，根据报道的出版物，由于翘曲、收缩和打印的HDPE部件与基板之间的弱粘合问题，使用FDM打印HDPE材料很困难。此外，fdm打印的HDPE部件会出现气孔和分层的缺陷。为了提高FDM的可打印性，我们进行了初步实验并优化了工艺参数。本文首次在HDPE中加入碳纤维(CF)，利用FDM技术制备CF-HDPE复合材料(CF-HDPE)，并研究了CF对CF-HDPE复合材料零件质量、微观结构特征和力学性能(包括拉伸性能和动态力学性能)的影响。实验结果表明，CF的加入不仅有利于提高FDM的可打印性和打印件的质量，而且有利于提高零件的力学性能(如杨氏模量和极限拉伸强度)。

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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来源期刊

Journal of Micro and Nano-Manufacturing ENGINEERING, MANUFACTURING-

CiteScore

2.70

自引率

0.00%

发文量

期刊介绍： The Journal of Micro and Nano-Manufacturing provides a forum for the rapid dissemination of original theoretical and applied research in the areas of micro- and nano-manufacturing that are related to process innovation, accuracy, and precision, throughput enhancement, material utilization, compact equipment development, environmental and life-cycle analysis, and predictive modeling of manufacturing processes with feature sizes less than one hundred micrometers. Papers addressing special needs in emerging areas, such as biomedical devices, drug manufacturing, water and energy, are also encouraged. Areas of interest including, but not limited to: Unit micro- and nano-manufacturing processes; Hybrid manufacturing processes combining bottom-up and top-down processes; Hybrid manufacturing processes utilizing various energy sources (optical, mechanical, electrical, solar, etc.) to achieve multi-scale features and resolution; High-throughput micro- and nano-manufacturing processes; Equipment development; Predictive modeling and simulation of materials and/or systems enabling point-of-need or scaled-up micro- and nano-manufacturing; Metrology at the micro- and nano-scales over large areas; Sensors and sensor integration; Design algorithms for multi-scale manufacturing; Life cycle analysis; Logistics and material handling related to micro- and nano-manufacturing.