The impact of 3D printing assumptions and CNC machining conditions on the mechanical parameters of the selected PET material

Q3 Materials Science
P. Krawulski, T. Dyl
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Abstract

This article focuses on a comparative analysis of the technology of additive shaping and multi-axis CNC machining. The authors examine the impact of 3D printing assumptions and CNC machining conditions on the strength of the selected PET material used to produce machine elements on the example of a shaft-type element. The purpose of the study is to identify a better production method.The analysis was carried out by producing six samples of different diameters and lengths from the same thermoplastic material (ethylene terephthalate) by both 3D printing (FDM) and CNC machining. The resulting samples were subjected to a static compression test, for which a universal testing machine by Zwick & Roell 100 kN was used. The following factors during the production of elements were compared: the difficulty of preparing the project, the time of execution, the cost of execution, the accuracy of the execution and the properties of the elements made.Elements made by CNC machining have higher compressive strength and yield strength, as well as lower relative expansion and relative shortening. Those produced by CNC machining are created as a monolith (semi-finished product), and the printed elements are incrementally shaped layer by layer. During the strength test, the spaces between the layers decrease, which in turn causes an increase in relative shortening and a decrease in strength properties.Further research is planned on the analysis of manufacturing technology using incremental shaping technology (e.g. change of filling density, change of filling type, change of material) compared to CNC machining.In the conducted tests, a universal method was used, which can be translated into a comparative study of elements made of other materials.The research carried out allowed for the initial assessment of the use of PET material for the production of machine elements through 3D printing and CNC machining.
3D打印假设和CNC加工条件对所选PET材料力学参数的影响
本文重点对增材成形技术和多轴数控加工技术进行了对比分析。作者以轴型元件为例,研究了3D打印假设和CNC加工条件对用于生产机器元件的选定PET材料强度的影响。研究的目的是确定一种更好的生产方法。通过3D打印(FDM)和CNC加工,用相同的热塑性材料(对苯二甲酸乙酯)生产了6个不同直径和长度的样品,进行了分析。得到的样品进行静态压缩试验,使用Zwick & Roell 100 kN万能试验机。对元素制作过程中的以下因素进行了比较:项目准备的难度、执行的时间、执行的成本、执行的准确性以及所制作的元素的性能。通过CNC加工制成的元件具有较高的抗压强度和屈服强度,以及较低的相对膨胀和相对缩短。通过CNC加工生产的那些是作为一个整体(半成品)创建的,并且打印的元素是逐层递增的形状。在强度试验中,层与层之间的间距减小,从而导致相对缩短量增加,强度性能下降。计划进一步研究使用增量成型技术的制造技术(如填充密度的变化、填充类型的变化、材料的变化)与CNC加工的对比分析。在进行的测试中,使用了一种通用的方法,这种方法可以转化为对由其他材料制成的元素的比较研究。进行的研究允许通过3D打印和CNC加工对PET材料用于生产机器元件的使用进行初步评估。
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
Archives of materials science and engineering
Archives of materials science and engineering Materials Science-Materials Science (all)
CiteScore
2.90
自引率
0.00%
发文量
15
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