Enhancement of Fatigue Life of Polylactic Acid Components through Post-Printing Heat Treatment

Designs Pub Date : 2024-01-11 DOI:10.3390/designs8010007

Moises Jimenez-Martinez, Julio Varela-Soriano, Rafael Carrera-Espinoza, S. G. Torres-Cedillo, Jacinto Cortés-Pérez

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Abstract

To reduce the carbon footprint of manufacturing processes, it is necessary to reduce the number of stages in the development process. To this end, integrating additive manufacturing processes with three-dimensional (3D) printing makes it possible to eliminate the need to use tooling for component manufacturing. Furthermore, using 3D printing allows the generation of complex models to optimize different components, reducing the development time and realizing lightweight structures that can be applied in different industries, such as the mobility industry. Printing process parameters have been studied to improve the mechanical properties of printed items. In this regard, although the failure of most structural components occurs under dynamic load, the majority of the evaluations are quasistatic. This work highlights an improvement in fatigue strength under dynamic loads in 3D-printed components through heat treatment. The fatigue resistance was improved regarding the number of cycles and the dispersion of results. This allows 3D-printed polylactic acid components to be structurally used, and increasing their reliability allows their evolution from a prototype to a functional component.

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通过印刷后热处理提高聚乳酸部件的疲劳寿命

为了减少制造过程的碳足迹，有必要减少开发过程中的阶段数量。为此，将快速成型制造工艺与三维（3D）打印技术相结合，就有可能使部件制造不再需要使用模具。此外，使用三维打印技术还可以生成复杂的模型来优化不同的组件，从而缩短开发时间，实现轻质结构，并将其应用于不同的行业，如移动行业。为了提高打印件的机械性能，对打印工艺参数进行了研究。在这方面，虽然大多数结构部件的失效都发生在动态载荷下，但大多数评估都是准静态的。这项工作强调了通过热处理提高 3D 打印部件在动态负载下的疲劳强度。耐疲劳性在循环次数和结果分散性方面都得到了改善。这使得三维打印聚乳酸部件可以在结构上使用，并提高了其可靠性，使其可以从原型发展为功能部件。

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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Designs

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