NEW SOLUTIONS IN THE PRODUCTION OF COMPOSITES - MECHANICAL PROPERTIES OF COMPOSITES REINFORCED WITH TECHNICAL EMBROIDERY AND WOVEN FABRIC MADE OF FLAX FIBERS

Agata Poniecka, M. Barburski, D. Ranz, J. Cuartero, R. Miralbés
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Abstract

The main purpose of the article is to present the new possibilities of producing natural fiber composite reinforcement. In this case, a computer embroidery machine by ZSK type JCZA 0109-550 was used. A technical embroidery with a stitch length of 2 mm was made on the machine. The embroidery was made of flax roving with a linear density of 400 tex. The woven fabric was made of the same flax roving as the embroidery, with a surface mass of 400 g/m2. Composites were then produced from the technical embroidery and woven fabric using the infusion method with epoxy resin. The individual configurations differed from each other in the orientation of the roving in the embroidery samples. Samples for tensile strength and tensile elongation tests consisted of 4 layers, while samples for the DCB test consisted of 6 layers, with the addition of a separating foil between the 3rd and 4th layer. Composites were then subjected to strength tests - tensile strength, tensile elongation and DCB test (Double Cantilever Beam test), on the INSTRON machine. During the action of force along the direction of the fibers, composites containing technical embroidery as reinforcement were characterized by higher strength than composites containing woven fabric as reinforcement. Additionally, embroidery is a barrier to the formation of interlayer cracks. Technical embroidery is made on the basis of Tailored Fiber Placement (TFP) technology. This technology allows optimizing the mechanical values of the composite reinforcement.
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复合材料生产的新解决方案——用亚麻纤维制成的技术刺绣和机织物增强复合材料的机械性能
本文的主要目的是介绍生产天然纤维复合增强材料的新可能性。在这种情况下,使用的是ZSK型JCZA 0109-550电脑绣花机。在这台机器上制作了一种针长为2毫米的技术刺绣。刺绣材料为线密度为400特克斯的亚麻粗纱。机织物由与刺绣相同的亚麻粗纱制成,表面质量为400 g/m2。然后用环氧树脂灌注法将工艺刺绣和机织织物制成复合材料。刺绣样品中粗纱的方向各不相同。抗拉强度和抗拉伸长率测试的样品为4层,DCB测试的样品为6层,在第3层和第4层之间增加了隔离箔。然后在INSTRON机器上对复合材料进行强度测试——抗拉强度、抗拉伸长率和DCB测试(双悬臂梁测试)。在纤维方向受力过程中,含工艺绣花增强的复合材料比含机织物增强的复合材料具有更高的强度。此外,刺绣是层间裂缝形成的屏障。技术刺绣是在定制纤维放置(TFP)技术的基础上制作的。该技术可以优化复合增强材料的力学值。
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