Parametric study of piezoresistive structures in continuous fiber reinforced additive manufacturing

IF 5.3 Q2 MATERIALS SCIENCE, COMPOSITES Composites Part C Open Access Pub Date : 2024-01-15 DOI:10.1016/j.jcomc.2024.100431
Tim Heitkamp , Marijn Goutier , Karl Hilbig , Simon Girnth , Nils Waldt , Günter Klawitter , Thomas Vietor
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Abstract

Recent advancements in fiber reinforced additive manufacturing leverage the piezoresistivity of continuous carbon fibers. This effect enables the fabrication of structural components with inherent piezoresistive properties suitable for load measurement or structural monitoring. These are achieved without necessitating additional manufacturing or assembly procedures. However, there remain unexplored variables within the domain of continuous fiber-reinforced additive manufacturing. Crucially, the roles of fiber curvature radii and sensing fiber bundle counts have yet to be comprehensively addressed. Additionally, the compression-sensitive nature of printed carbon fiber-reinforced specimens remains a largely unexplored research area. To address these gaps, this study presents experimental analyses on tensile and three-point flexural specimens incorporating sensing carbon fiber strands. All specimens were fabricated with three distinct curvature radii. For the tensile specimens, the number of layers was also varied. Sensing fiber bundles were embedded on both tensile and compression sides of the flexural specimens. Mechanical testing revealed a linear-elastic behavior in the specimens. It was observed that carbon fibers supported the majority of the load, leading to brittle fractures. The resistance measurements showed a dependence on both the number of sensing layers and the radius of curvature, and exhibited a slight decreasing trend in the cyclic tests. Compared with the sensors subjected to tensile stress, the sensors embedded on the compression side showed a lower gauge factor.

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连续纤维增强增材制造中压阻结构的参数研究
纤维增强增材制造技术的最新进展利用了连续碳纤维的压阻效应。这种效应可制造出具有固有压阻特性的结构组件,适用于负载测量或结构监测。实现这些功能无需额外的制造或组装程序。然而,在连续纤维增强增材制造领域,仍存在一些尚未探索的变量。最重要的是,纤维曲率半径和传感纤维束数量的作用尚未得到全面解决。此外,打印碳纤维增强试样的压缩敏感性在很大程度上仍是一个未开发的研究领域。为了填补这些空白,本研究对包含传感碳纤维股的拉伸和三点弯曲试样进行了实验分析。所有试样均以三种不同的曲率半径制作。拉伸试样的层数也有变化。传感纤维束被嵌入弯曲试样的拉伸和压缩侧。机械测试表明,试样具有线弹性行为。据观察,碳纤维承受了大部分载荷,导致脆性断裂。电阻测量结果显示与传感层数和曲率半径有关,并在循环测试中呈现出轻微的下降趋势。与承受拉伸应力的传感器相比,嵌入压缩侧的传感器的测量系数较低。
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来源期刊
Composites Part C Open Access
Composites Part C Open Access Engineering-Mechanical Engineering
CiteScore
8.60
自引率
2.40%
发文量
96
审稿时长
55 days
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