Bio-Lightweight Structures by 3D Foam Printing

2021 IEEE 6th International Forum on Research and Technology for Society and Industry (RTSI) Pub Date : 2021-09-06 DOI:10.1109/rtsi50628.2021.9597272

D. Tammaro, Andrea Lorenzo Henry Detry, Luca Landonfi, F. Napolitano, M. Villone, P. Maffettone, A. Squillace

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引用次数: 5

Abstract

An innovative additive manufacturing technique is reported, which enables 3D printing of lightweight cellular structures with multiscale density control and carbon fibre reinforcement to improve mechanical performances. We present a model-based design of the process (including heat transport in the 3D printer nozzle) allowing to control the foam morphology in the printing process. The proposed approach is validated using polylactic acid, which is a bio-based compostable polymer employed in the biomedical, agricultural, and chemical engineering fields, that is blown with carbon dioxide to produce both reinforced foamed strands and structures. These have been characterized by microscopy and mechanical tests. The results show that the addition of fibres in the polymer matrix induces cells breakage resulting in a double-cell-sized morphology. The mechanical characterization of our 3D printed lightweight cellular composites revealed that the reinforced cellular structures have a higher compression strength than the non-reinforced ones.

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3D泡沫打印的生物轻质结构

报道了一种创新的增材制造技术，该技术可以通过多尺度密度控制和碳纤维增强来提高机械性能，从而实现轻型细胞结构的3D打印。我们提出了一个基于模型的过程设计(包括3D打印机喷嘴中的热传输)，允许在打印过程中控制泡沫形态。聚乳酸是一种生物基可堆肥聚合物，应用于生物医学、农业和化学工程领域，用二氧化碳吹制，可以产生增强泡沫链和结构。这些已被显微镜和机械测试表征。结果表明，在聚合物基质中加入纤维会导致细胞断裂，从而形成双细胞大小的形态。3D打印轻质蜂窝复合材料的力学特性表明，增强的蜂窝结构比未增强的蜂窝结构具有更高的抗压强度。

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

2021 IEEE 6th International Forum on Research and Technology for Society and Industry (RTSI)

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