材料科学
3D打印
熔融沉积模型
正交数组
田口方法
复合材料
抗压强度
韧性
高效能源利用
聚酰胺
杨氏模量
结构工程
机械工程
工程类
电气工程
作者
Constantine David,Dimitrios Sagris,Markos Petousis,Nektarios K. Nasikas,Amalia Moutsopoulou,Evangelos Sfakiotakis,Nikolaos Mountakis,Chrysa Charou,Nectarios Vidakis
出处
期刊:Applied sciences
[Multidisciplinary Digital Publishing Institute]
日期:2023-07-30
卷期号:13 (15): 8819-8819
被引量:37
摘要
Both energy efficiency and robustness are popular demands for 3D-printed components nowadays. These opposing factors require compromises. This study examines the effects of seven general control variables on the energy demands and the compressive responses of polyamide (PA6) material extrusion (MEX) 3D printed samples. Nozzle Temperature, Layer Thickness, Orientation Angle, Raster Deposition Angle, Printing Speed, Bed Temperature, and Infill Density were studied. An L27 orthogonal array was compiled with five replicas. A total of 135 trials were conducted, following the ASTM D695-02a specifications. The stopwatch method was used to assess the construction time and energy usage. The compressive strength, toughness, and elasticity modulus were experimentally determined. The Taguchi technique ranks each control parameter’s impact on each response measure. The control parameter that had the greatest impact on both energy use and printing time was layer thickness. Additionally, the infill density had the greatest influence on the compressive strength. Quadratic regression model equations were formed for each of the response measures. The ideal compromise between mechanical strength and energy efficiency is now reported, with merit related to technological and economic benefits.
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