Microstructural Analysis of Wound Composites with Considerations on the Fiber Winding Force

Quality Production Improvement and System Safety Pub Date : 2023-09-01 DOI:10.21741/9781644902691-6

P. Krysiak

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Abstract

Abstract. The paper concerns issues related to the fabrication and microstructural analysis of carbon and glass fiber-reinforced epoxy composites. For the purposes of the tests, ring samples of carbon fiber and glass fiber were fabricated, each sample being made of the same amount of material. The rings were produced by circumferentially wrapping fibers onto a rigid core. During winding, the fiber tension was changed for each sample to investigate whether the amount and distribution of fibers in the composite depending on the force applied. The applied tension forces ranged from 18 to 138 N. In the next stage of tests, small fragments were cut out of the rings, cutting perpendicularly to the arrangement of fiber bundles. The cut elements were then embedded in epoxy resin. The microsections prepared in this were ground using a grinding disc with a gradation of 80 to 4000 and then polished, washed and dried. After these treatments, microscopic photos of the tested surfaces were taken. Observations were made using a NEOPHOT 32 microscope with an integrated camera and a KEYENCE VHX microscope. The volume fraction of voids and discontinuities in the matrix, as well as the volume fraction of fibers, were determined by measuring the percentage of the surface areas occupied by the appropriate components of the composite. On each cross-section of individual samples, photographs were taken in three planes parallel to the composite layers and three planes perpendicular to the fibers  in the matrix system. The image analysis method was used for verification, in which it is assumed that the assessment of fiber distribution in a two-dimensional section is representative of its volumetric distribution. This method is mainly used to analyze the distribution of fibers with a constant cross-section. The most important conclusions from the conducted analyses allow the authors to state that in both composites the fibers in the matrix are highly packed and that there was no significant and noticeable effect of fiber tension during winding on the "packing" density of fibers in the composites.

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考虑纤维缠绕力的缠绕复合材料微观组织分析

摘要本文研究了碳纤维和玻璃纤维增强环氧复合材料的制备和微观结构分析。为了测试的目的，制造了碳纤维和玻璃纤维的环形样品，每个样品由相同数量的材料制成。这些环是通过将纤维环绕在刚性芯上而产生的。在缠绕过程中，改变每个样品的纤维张力，以研究纤维在复合材料中的数量和分布是否取决于施加的力。施加的拉力范围从18到138牛顿。在下一阶段的测试中，从环上剪下小碎片，垂直于纤维束的排列。然后将切割的元件嵌入环氧树脂中。在此过程中制备的显微切片使用分级为80至4000的研磨盘进行研磨，然后抛光，洗涤和干燥。经过这些处理后，拍摄了被测表面的显微照片。使用NEOPHOT 32集成相机显微镜和KEYENCE VHX显微镜进行观察。基体中空隙和不连续的体积分数，以及纤维的体积分数，是通过测量复合材料中适当组分所占表面积的百分比来确定的。在单个样品的每个横截面上，分别在与复合材料层平行的三个平面和与基质系统中的纤维垂直的三个平面上拍摄照片。采用图像分析方法进行验证，其中假设对二维截面纤维分布的评估代表其体积分布。该方法主要用于分析等截面纤维的分布。从所进行的分析中得出的最重要的结论使作者能够指出，在这两种复合材料中，基体中的纤维都是高度堆积的，并且在缠绕过程中纤维张力对复合材料中纤维的“堆积”密度没有显著和明显的影响。

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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Quality Production Improvement and System Safety

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