Optimization of Mechanical Properties and Surface Characteristics of PLA+ 3D Printing Materials

IF 2.3 4区 工程技术 Q3 ENGINEERING, CHEMICAL
A. Kadhum, S. Al-Zubaidi, S. S. A. AlKareem
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引用次数: 0

Abstract

Recently, there is a growing demand towards adopting 3D printing technology in various sectors due to its potential merits. The mechanical properties and surface quality of the final product are influenced by the process parameters. Therefore, this study aims to optimize the infill density and pattern beside printing speed and temperature to achieve optimum mechanical properties and surface characteristics of PLA+ 3D-printed material. The Taguchi method was applied with L9 array, and tensile and surface roughness tests were carried out to evaluate the performance of specimens in terms of the obtained ultimate tensile strength, Young’s modulus, tensile strain (%), and surface roughness. The selected parameters with their levels were as follows: printing temperature (205, 215, and 225°C), printing speed (20, 50, and 80 mm/s), infill density (30%, 60%, and 90%), and infill pattern (triangle, cubic, and concentric). The findings revealed the significant impact of the infill density followed by the infill pattern on the mechanical and surface performances of the PLA+ material. From the other side, the Taguchi method was integrated with grey relational analysis (GRA) as a multiobjective optimization to find out the optimum mechanical properties and surface characteristics of the 3D-printed PLA+ part. Accordingly, 215°C, 50 mm/s, 90%, and triangle pattern achieved optimum mechanical properties (24 MPa, 3.14 GPa, and 13.72%) and surface roughness (3.21 µm).
PLA+ 3D打印材料力学性能和表面特性的优化
最近,由于其潜在的优点,在各个领域采用3D打印技术的需求不断增长。最终产品的力学性能和表面质量受工艺参数的影响。因此,除了打印速度和温度外,本研究旨在优化填充密度和图案,以获得PLA+ 3d打印材料的最佳力学性能和表面特性。采用L9阵列的Taguchi方法,进行拉伸和表面粗糙度试验,从获得的极限拉伸强度、杨氏模量、拉伸应变(%)和表面粗糙度等方面评价试件的性能。选择的参数及其级别如下:打印温度(205、215和225℃),打印速度(20、50和80 mm/s),填充密度(30%、60%和90%),填充图案(三角形、立方和同心)。研究结果表明,填充密度和填充模式对PLA+材料的力学性能和表面性能有显著影响。另一方面,将Taguchi方法与灰色关联分析(GRA)相结合,作为多目标优化方法,找出3d打印PLA+零件的最佳力学性能和表面特征。因此,在215°C、50 mm/s、90%和三角形模式下,获得了最佳的力学性能(24 MPa、3.14 GPa和13.72%)和表面粗糙度(3.21µm)。
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来源期刊
International Journal of Chemical Engineering
International Journal of Chemical Engineering Chemical Engineering-General Chemical Engineering
CiteScore
4.00
自引率
3.70%
发文量
95
审稿时长
14 weeks
期刊介绍: International Journal of Chemical Engineering publishes papers on technologies for the production, processing, transportation, and use of chemicals on a large scale. Studies typically relate to processes within chemical and energy industries, especially for production of food, pharmaceuticals, fuels, and chemical feedstocks. Topics of investigation cover plant design and operation, process design and analysis, control and reaction engineering, as well as hazard mitigation and safety measures. As well as original research, International Journal of Chemical Engineering also publishes focused review articles that examine the state of the art, identify emerging trends, and suggest future directions for developing fields.
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