Comparison of Quality of Porous Structure Specimens Produced by Different Additive Technologies and from Different Materials

Q1 Mathematics

Applied Sciences Pub Date : 2024-01-12 DOI:10.3390/app14020648

Jozef Tkac, T. Tóth, O. Mizera, V. Molnár, G. Fedorko, M. Dovica

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引用次数: 0

Abstract

Lattice and gyroid structures are often subjected to additive technologies to produce various types of products, and the current market has a number of 3D printers that can be used for their production. The quality of the products produced in this way can be assessed on the basis of technical parameters and the filament used. Such an approach, however, is insufficient. In terms of quality, other product parameters need to be assessed, such as the surface texture and the internal structure’s porosity. For such an assessment, we can use the industrial tomography method and the method of roughness measurement via an optical microscope. The paper presents research on the assessment of the surface texture and porosity in lattice and gyroid structures. For the research, two types of test specimens—a specimen with a lattice structure and a specimen with a gyroid structure—were prepared. The obtained results proved that the 3D printing technology directly impacted the surface texture and porosity. For experimental specimens produced by SLS technology, we found that it was very important to carefully remove the excess powder, as unremoved powder can significantly affect the porosity results. For specimens produced by FDM technology, the research confirmed that some “gaps” between the layers were not pores but defects created during specimen production. When analyzing the surface using the Alicon Infinite G5 optical microscope, we found that the measured roughness results were directly impacted by the specimen’s surface color, the structure’s geometry, and the ambient light, which was confirmed by a red lattice experimental specimen, the surface of which could not be scanned. Based on the above, it can be stated that the selection of 3D technology for additive production needs must be given adequate attention regarding the quality of the created structures and textures.

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不同添加剂技术和不同材料制作的多孔结构试样质量比较

格子结构和陀螺结构通常采用添加技术来生产各类产品，目前市场上有许多三维打印机可用于生产这些产品。通过这种方式生产出的产品的质量可以根据技术参数和所使用的长丝进行评估。然而，这种方法是不够的。就质量而言，还需要评估其他产品参数，如表面纹理和内部结构的孔隙率。为了进行这样的评估，我们可以使用工业层析成像法和通过光学显微镜测量粗糙度的方法。本文介绍了关于评估晶格结构和陀螺结构表面纹理和孔隙率的研究。在研究过程中，制备了两种类型的试样--晶格结构试样和陀螺结构试样。研究结果证明，三维打印技术直接影响了试样的表面纹理和孔隙率。对于用 SLS 技术制作的实验试样，我们发现仔细去除多余的粉末非常重要，因为未去除的粉末会严重影响孔隙率结果。对于用 FDM 技术制作的试样，研究证实层与层之间的一些 "缝隙 "并非气孔，而是试样制作过程中产生的缺陷。在使用 Alicon Infinite G5 光学显微镜分析表面时，我们发现所测得的粗糙度结果会受到试样表面颜色、结构几何形状和环境光线的直接影响，这一点在一个无法扫描其表面的红色晶格实验试样上得到了证实。综上所述，在选择三维技术进行增材制造时，必须充分关注所制造结构和纹理的质量。

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

Applied Sciences Mathematics-Applied Mathematics

CiteScore

6.40

自引率

0.00%

发文量

审稿时长

11 weeks

期刊介绍： APPS is an international journal. APPS covers a wide spectrum of pure and applied mathematics in science and technology, promoting especially papers presented at Carpato-Balkan meetings. The Editorial Board of APPS takes a very active role in selecting and refereeing papers, ensuring the best quality of contemporary mathematics and its applications. APPS is abstracted in Zentralblatt für Mathematik. The APPS journal uses Double blind peer review.