Structural stability of Polylactide rope drums with a hybrid Gyroid-spokes infill structure, manufactured through fused filament fabrication

innoTRAC Journal Pub Date : 2022-12-08 DOI:10.14464/innotrac.v2i1.516

R. Hofmann, Armin Bochert, T. Schmidt

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Abstract

Additive manufacturing (AM) offers greater design freedom than conventional manufacturing processes. AM allows for components with complex infill structures of e. g. triply periodic-minimal surfaces (TPMS) that lead to significant weight reduction. Nevertheless, AM is mainly used in specialised engineering branches such as aerospace and medical engineering. This is due to high system cost and the high energy costs of the machines used, which utilise selective laser sintering (SLS), laser powder bed fusion (LPBF), or stereolithography (SLA). Fused filament fabrication (FFF) can offer cheaper and more energy-efficient machines. A series of tensile tests with FFF rope drum bodies made from polylactide (PLA) aims to investigate the stability of FFF machine elements. The test specimens possess a novel, hybrid infill structure comprised of straight spokes and a TPMS-gyroid surface. Compared to previous investigations, the specific breaking force – relative to the test specimens’ weight – increased by up to 159%. Whereas the infill density affects tensile strength as well as deformation, the infill distribution between the TPMS and spokes part of said hybrid structure affects especially the deformation behaviour. The results show that FFF machine elements such as the tested drum bodies have a realistic perspective for use in future products with regard to static strength.

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采用熔丝法制造的螺旋-辐条混合填充结构聚乳酸绳筒的结构稳定性

增材制造(AM)提供了比传统制造工艺更大的设计自由度。增材制造允许具有复杂填充结构的部件，例如三周期最小表面(TPMS)，从而显著减轻重量。然而，增材制造主要用于专业工程分支，如航空航天和医学工程。这是由于高系统成本和使用的机器的高能源成本，这些机器利用选择性激光烧结(SLS)，激光粉末床熔融(LPBF)或立体光刻(SLA)。熔丝制造(FFF)可以提供更便宜和更节能的机器。以聚乳酸(PLA)为材料，对FFF绳筒体进行了一系列拉伸试验，研究了FFF机械元件的稳定性。试验样品具有一种新型的混合填充结构，由直辐条和tpms -陀螺表面组成。与之前的研究相比，比断裂力-相对于试件的重量-增加了159%。而填充密度影响拉伸强度和变形，TPMS和辐条部分之间的填充分布尤其影响变形行为。结果表明，FFF机器元件，如测试的鼓体，在静强度方面具有现实的前景，可用于未来的产品。

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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innoTRAC Journal

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