Taguchi DoE analysis and characterization of 17-4 PH stainless steel parts produced by material extrusion (MEX) process

IF 3.9 Q2 ENGINEERING, INDUSTRIAL

Advances in Industrial and Manufacturing Engineering Pub Date : 2024-02-03 DOI:10.1016/j.aime.2024.100138

Mahmoud Naim , Mahdi Chemkhi , Julien Kauffmann , Akram Alhussein

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引用次数: 0

Abstract

Material extrusion (MEX) of metallic components is an indirect additive manufacturing (AM) process that is recently gaining a lot of attention in the industry. This multi-step process with debinding and sintering, provides an inexpensive safe alternative, that is effective, flexible and office-friendly for several corporations compared to other metal AM techniques. However, optimizing the manufacturing parameters of the MEX process is still challenging due to the lack of research on their impact on the mechanical and surface properties of the fabricated materials.

For this purpose, this paper investigates how various processing parameters impact the mechanical properties and surface roughness of 17-4 PH stainless steel parts produced by MEX. The parameters analyzed include layer thickness, build orientation, number of contours, and aging thermal treatment for 1 h at $482 °C$ (H900). A Taguchi design of experiments (DoE) was employed to conduct the parametric analysis and the results were post-evaluated via the analysis of variance (ANOVA). The experimental results show that H900 treatment increases the micro-hardness by ∼50 HV_0.3 and contributes in augmenting the ultimate tensile strength (UTS) by ∼200 MPa. The build orientation and its interaction with the layer thickness have the highest impact on the surface roughness. Moreover, the amount of enclosed porosity is higher in the samples with lower layer thickness. The absorbed impact energy ( $W_{a b s}$ ) is relatively low due to the enclosed porosity content and is not linked to the analyzed processing parameters. The best mechanical properties were obtained for parts built with solid infills, 0° build orientation, 0.125 mm layer thickness, two contours, and H900 as a post-treatment.

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通过材料挤压（MEX）工艺生产的 17-4 PH 不锈钢部件的田口 DoE 分析和特征描述

金属部件的材料挤压（MEX）是一种间接增材制造（AM）工艺，最近在业界受到广泛关注。与其他金属增材制造技术相比，这种带有脱脂和烧结的多步骤工艺为多家公司提供了一种廉价、安全的替代方案，而且高效、灵活、便于办公。然而，由于缺乏对制造材料的机械和表面性能影响的研究，优化 MEX 工艺的制造参数仍具有挑战性。为此，本文研究了各种加工参数如何影响 MEX 生产的 17-4 PH 不锈钢零件的机械性能和表面粗糙度。分析的参数包括层厚、构建方向、轮廓数量以及在 482°C (H900) 温度下进行 1 小时的时效热处理。采用田口实验设计（DoE）进行参数分析，并通过方差分析（ANOVA）对结果进行后评估。实验结果表明，H900 处理使微观硬度提高了 ∼50 HV0.3，并使极限拉伸强度（UTS）提高了 ∼200 MPa。构建方向及其与层厚度的相互作用对表面粗糙度的影响最大。此外，层厚度较低的样品中封闭孔隙率较高。由于封闭气孔的存在，吸收的冲击能量（Wabs）相对较低，且与分析的加工参数无关。采用实心填充、0° 构建方向、0.125 毫米层厚、两种轮廓和 H900 作为后处理的零件获得了最佳机械性能。

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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来源期刊

Advances in Industrial and Manufacturing Engineering Engineering-Engineering (miscellaneous)

CiteScore

6.60

自引率

0.00%

发文量

审稿时长

18 days