Numerical evaluation of the infill pattern upon mechanical proprieties of 3D printed materials

Laszlo Racz , Mircea Cristian Dudescu
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引用次数: 0

Abstract

The effect of the structure that is printed inside an object, known as infill pattern, on mechanical proprieties of ABS specimens was investigated in this paper. Numerous studies demonstrated that parts created with fused deposition molding (FDM) technology present inferior mechanical properties due to additional porosity and anisotropy caused by the nature of the manufacturing process. In this regard the influence of printing parameters may be analyzed for correct evaluation of mechanical behavior and material constants. The methodology proposed in this paper consists of a numerical simulation of the fused deposition moulding 3D printed specimen, identification of the real cross-sectional area and evaluation of the strain-stress curves of the materials. There are several infill pattern geometries, each with benefits and compromises between material usage, printing time or mechanical strength of the obtained part. The current paper analysed specimens with 100% density (infill rate) but having different infill patterns: grid 0°-90° and ±45°, triangular 60°, fast honeycomb, full honeycomb and wiggle. The results are showing the dependence of the specimen's E modulus with the infill pattern and comparison of the strain-stress curves drawn with full cross-section and numerically calculated ones.

填充图案对 3D 打印材料力学特性的数值评估
本文研究了物体内部印刷结构(即填充图案)对 ABS 试样机械特性的影响。大量研究表明,采用熔融沉积成型(FDM)技术制造的零件,由于制造过程的性质造成了额外的孔隙率和各向异性,因此机械性能较差。在这方面,可以分析印刷参数的影响,以正确评估机械性能和材料常数。本文提出的方法包括对熔融沉积成型 3D 打印试样进行数值模拟、确定实际横截面积和评估材料的应变应力曲线。有几种填充图案几何形状,每种都有其优点,同时也会在材料使用、打印时间或所获部件的机械强度之间做出折衷。本文分析了密度为 100%(填充率)但具有不同填充模式的试样:0°-90° 和 ±45°网格、60° 三角形、快速蜂窝、全蜂窝和摇摆。结果显示了试样的 E 模量与填充模式的关系,以及全截面应变应力曲线与数值计算应变应力曲线的比较。
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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CiteScore
1.70
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