Printing vertical flat surfaces in thermoset big area additive manufacturing

IF 4.2 Q2 ENGINEERING, MANUFACTURING Additive manufacturing letters Pub Date : 2024-07-01 DOI:10.1016/j.addlet.2024.100226
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Abstract

In extrusion-based additive manufacturing, achieving high surface quality typically involves using small layer heights to reduce the size of grooves between layers. However, this approach can be both less effective and time-consuming in big-area additive manufacturing. Therefore, the current focus is on investigating methods for printing with fewer layers without compromising surface quality. In this study, single-strand walls were printed using a two-component thermoset material, where different nozzle designs and printing strategies are explored to achieve the flattest possible surface. The success of each approach was evaluated by measuring the percentage of material that required removal to achieve a perfect vertical flat wall. The results suggested that incorporating vertical wings to contain the material in the desired shape was beneficial. Furthermore, the study introduced the idea of adjustable layer heights to mitigate layer deformation. This deformation is most noticeable in the initial layers but largely affects all subsequent printed layers. Finally, making the wings have an angle with regard to the printing direction or trapezoidal wings, served as a pressure funnel that produced the greatest improvement in surface quality. These changes allowed for a reduction of the amount of material which would need to be removed to achieve a flat wall without grooves from 14.3% for a standard print from a round nozzle, to 2.5% for an optimized strand. The research shows a promising path to producing entirely flat vertical structures, even when printing with still-deformable, thermoset materials in the context of big-area additive manufacturing.

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在热固性大面积增材制造中打印垂直平面
在基于挤压的增材制造中,要获得较高的表面质量,通常需要使用较小的层高来减小层间沟槽的尺寸。然而,在大面积增材制造中,这种方法既不有效又耗时。因此,目前的重点是研究在不影响表面质量的前提下使用较少层进行打印的方法。在这项研究中,使用双组分热固性材料打印了单股壁,并探索了不同的喷嘴设计和打印策略,以获得尽可能平整的表面。通过测量实现完美垂直平壁所需去除材料的百分比,评估了每种方法的成功率。结果表明,采用垂直翼将材料控制在所需形状是有益的。此外,该研究还引入了可调节层高的理念,以减轻层变形。这种变形在初始层中最为明显,但在很大程度上会影响所有后续打印层。最后,使翼片与印刷方向成一定角度或梯形翼片可作为压力漏斗,从而最大程度地改善表面质量。这些变化使得为获得无凹槽的平壁而需要去除的材料量从圆形喷嘴标准打印的 14.3% 减少到优化股的 2.5%。这项研究表明,即使在大面积增材制造的背景下使用仍可变形的热固性材料进行打印,也有希望生产出完全平坦的垂直结构。
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
Additive manufacturing letters
Additive manufacturing letters Materials Science (General), Industrial and Manufacturing Engineering, Mechanics of Materials
CiteScore
3.70
自引率
0.00%
发文量
0
审稿时长
37 days
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