INVESTIGATING ENERGY ABSORPTION CAPABILITY OF ADDITIVELY MANUFACTURED CUBOCTAHEDRAL LATTICE STRUCTURES VIA TAGUCHI’S METHOD: EFFECTS OF PROCESS PARAMETERS

International Journal of 3D Printing Technologies and Digital Industry Pub Date : 2023-11-27 DOI:10.46519/ij3dptdi.1322642

Bahman Paygozar, R. M. Görgülüarslan

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Abstract

This research aimed to investigate the influence of process parameters of 3D printing on the energy absorption capacity of Cuboctahedral lattice structures. Cubic 3×3×3 Cuboctahedral lattices made of struts with 1.5 mm in diameter were analyzed. Design of experiments was done through Taguchi method (L9). Nine experiments with three repetitions were designed in order to examine the effects of process parameters (i.e., print temperature, print speed, layer thickness, and line width) on the specific absorbed energy. In this regard, for each sample of each experiment, a compression uniaxial test was performed under a constant cross-head velocity of 2 mm/min. Subsequently, the compression response of each specimen was recorded as load-displacement data. To draw the amount of absorbed energy from the aforementioned data, a MATLAB code was utilized to calculate the enclosed area under the curve up to the densification point. Then, to reveal the effectiveness of each process parameter S/N ratio analysis was conducted using Taguchi’s method. As the result, layer thickness was the most effective factor. To approve the exactness of the approach employed, two verification tests were also conducted.

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通过田口方法研究快速成型立方八面体晶格结构的能量吸收能力：工艺参数的影响

本研究旨在探讨三维打印工艺参数对立方体晶格结构能量吸收能力的影响。研究分析了由直径为 1.5 毫米的支柱组成的 3×3×3 立方体晶格。实验设计采用田口方法（L9）。设计了九次重复三次的实验，以考察工艺参数（即打印温度、打印速度、层厚度和线宽）对比值吸收能量的影响。为此，每个实验的每个样品都在 2 毫米/分钟的恒定横头速度下进行了单轴压缩测试。随后，每个试样的压缩响应被记录为载荷-位移数据。为了从上述数据中得出所吸收的能量，利用 MATLAB 代码计算了直至致密化点的曲线下封闭面积。然后，使用田口方法进行了信噪比分析，以揭示各工艺参数的有效性。结果显示，层厚度是最有效的因素。为了证实所采用方法的准确性，还进行了两次验证试验。

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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International Journal of 3D Printing Technologies and Digital Industry

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