Robust profiled carbon rovings made of multiple yarns for textile reinforcements in concrete and asphalt matrix

IF 1.6 4区工程技术 Q2 MATERIALS SCIENCE, TEXTILES

Textile Research Journal Pub Date : 2024-05-10 DOI:10.1177/00405175241249923

Paul Penzel, Lars Hahn, Markus Clauß, Christiane Weise, Alexander Zeißler, Marko Butler, Chokri Cherif

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Abstract

The load-bearing behavior and the performance of composites depends largely on the bond between the individual components. Conventional grid-like textile reinforcement structures with thin and smooth yarn structures transmit forces primarily by an adhesive bond with the surrounding matrix. A sufficient load transmission is not possible. Thick, pultruded rebars made of fiber-reinforced plastics can be profiled by subtractive (e.g. milling) or additive (e.g. wrapping) techniques in order to create a rip-like structure and increased shear bond. Yet the discontinuous fiber course results in material inefficiency. A newly developed profiling technique allows a tetrahedral profiling of the complete roving structure, yet considering its anisotropic properties. In the article, we present this approach, and the first results from single yarn tensile and pull-out tests of single, double and triple plied profiled rovings in concrete and asphalt matrix. Thus, the highest bond is achieved in the brittle concrete matrix. Plied rovings with strong tetrahedral profiles show up to 600% higher bond stress compared with rovings with circular profiles, while maintaining high tensile properties. However, splitting-induced failure of the reinforced test specimens occurs, making plied profiled rovings favorable for high concrete cover and less brittle matrixes; for example, asphalt. The reinforced asphalt specimens show at −10°C similar bond properties, but at 30°C the bond decreases by 80%. In summary, the study shows that bond properties of profiled rovings are superior to conventional circular rovings, and promise a high material efficiency for use in concrete and asphalt reinforcements.

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用于混凝土和沥青基体纺织加固的多纱强力异型碳纤维粗纱

复合材料的承载行为和性能在很大程度上取决于各个组件之间的粘合。传统的网格状纺织加固结构具有细而光滑的纱线结构，主要通过与周围基体的粘合力传递力。这种结构无法传递足够的载荷。由纤维增强塑料制成的厚拉挤钢筋可通过减法（如铣削）或加法（如缠绕）技术进行剖面加工，以形成类似撕裂的结构并增加剪切粘结力。然而，不连续的纤维路线会导致材料效率低下。新开发的仿形技术可以对完整的粗纱结构进行四面体仿形，同时考虑其各向异性。在文章中，我们介绍了这种方法，以及在混凝土和沥青基体中对单股、双股和三股异型粗纱进行单纱拉伸和拔出试验的首次结果。因此，在脆性混凝土基体中实现了最高的粘结力。与圆形轮廓的粗纱相比，具有强四面体轮廓的粗纱在保持高拉伸性能的同时，粘结应力最多可提高 600%。然而，加固试样会出现因分裂而导致的破坏，这使得多层异形索有利于高混凝土覆盖率和脆性较低的基体，例如沥青。加筋沥青试样在 -10°C 时显示出相似的粘结性能，但在 30°C 时粘结性能降低了 80%。总之，这项研究表明，异形索的粘结性能优于传统的圆形索，并有望在混凝土和沥青加固材料中实现更高的材料效率。

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

Textile Research Journal 工程技术-材料科学：纺织

CiteScore

4.00

自引率

21.70%

发文量

309

审稿时长

1.5 months

期刊介绍： The Textile Research Journal is the leading peer reviewed Journal for textile research. It is devoted to the dissemination of fundamental, theoretical and applied scientific knowledge in materials, chemistry, manufacture and system sciences related to fibers, fibrous assemblies and textiles. The Journal serves authors and subscribers worldwide, and it is selective in accepting contributions on the basis of merit, novelty and originality.