Experimental Investigation on the 3D Printing of Nylon Reinforced by Carbon Fiber through Fused Filament Fabrication Process, Effects of Extruder Temperature, and Printing Speed

IF 3.4 4区 化学 Q2 POLYMER SCIENCE International Journal of Polymer Science Pub Date : 2024-05-10 DOI:10.1155/2024/1234797
Mahmoud Moradi, Zeinab Malekshahi Beiranvand, Nahid Salimi, Saleh Meiabadi, Jonathan Lawrance
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Abstract

This study investigated how the extruder temperature, printing speed, and specimen geometry interact during a tensile test of continuous carbon fiber-reinforced nylon matrix composites produced by the fused deposition modelling (FDM) process. The investigation utilized statistical techniques. For this purpose, tensile examinations were done on manufactured samples using a testing apparatus. The study’s objective is to identify the most efficient specimen geometry for tensile testing result optimization and to maximize the 3D printing process’s capability for producing complex, freeform patterns in these composites. In this study, the input parameters required for the response surface methodology (RSM) were varying extruder temperature (240-255°C) and printing speed (60-80 mm/s), and experimental responses included modulus, elongation at break, and weight. The findings of the regression analysis showed output responses are influenced by both input variables. The results showed that the strength of the samples was significantly influenced by the input parameters. To draw the surface and residual plots, the software of design expert software was used. The interaction between the two input variables suggests raising the extruder temperature and decreasing printing speed, which leads to printing heavier samples. Inversely, the diversity between the forecasted and real responses for the optimal specimens is less than 10% which is assumed to be acceptable for the design of experiments (DOE). The analysis took into account the lower and upper ranges of the input variable with the goal of enhancing both the most modulus and fracture elongation while simultaneously degrading the weight of the specimens. To achieve this objective, the extruder temperature and printing speed are between 240 and 250°C and 65 and 75 mm/s, respectively.
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通过熔融长丝制造工艺对碳纤维增强尼龙进行三维打印的实验研究,以及挤出机温度和打印速度的影响
本研究探讨了在对采用熔融沉积模塑(FDM)工艺生产的连续碳纤维增强尼龙基复合材料进行拉伸测试时,挤出机温度、印刷速度和试样几何形状如何相互作用。调查采用了统计技术。为此,使用测试仪器对制造的样品进行了拉伸试验。研究的目的是确定最有效的试样几何形状,以优化拉伸测试结果,并最大限度地提高 3D 打印工艺在这些复合材料中制作复杂、自由形态图案的能力。在本研究中,响应面方法(RSM)所需的输入参数是不同的挤出机温度(240-255°C)和打印速度(60-80 mm/s),实验响应包括模量、断裂伸长率和重量。回归分析结果表明,输出响应受两个输入变量的影响。结果表明,样品的强度受输入参数的影响很大。绘制曲面图和残差图时使用了 design expert 软件。两个输入变量之间的相互作用表明,提高挤出机温度和降低打印速度会导致打印出更重的样品。相反,最佳试样的预测反应和实际反应之间的差异小于 10%,这对于实验设计(DOE)来说是可以接受的。分析考虑了输入变量的上限和下限范围,目的是提高最大模量和断裂伸长率,同时减轻试样重量。为实现这一目标,挤出机温度和印刷速度分别为 240 至 250°C 和 65 至 75 mm/s。
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来源期刊
CiteScore
6.10
自引率
0.00%
发文量
55
审稿时长
>12 weeks
期刊介绍: The International Journal of Polymer Science is a peer-reviewed, Open Access journal that publishes original research articles as well as review articles on the chemistry and physics of macromolecules.
期刊最新文献
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