The effect of tensile deformation of knitted fabrics on their electromagnetic shielding ability, electrical resistance, and porosity

IF 2.2 4区 工程技术 Q1 MATERIALS SCIENCE, TEXTILES
Sundaramoorthy Palanisamy, Veronika Tunakova, Jana Ornstova, Monika Vysanska, Jiri Militky
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Abstract

Nowadays, electrically conductive textile materials are widely used also for sensing applications in addition to being used as antistatic, electromagnetic shielding, for creating smart textiles, etc. The main aim of this paper is to study the effect of tensile deformation applied on knitted fabrics on their electromagnetic shielding ability, electrical resistance, and porosity to gain knowledge for the construction of textile-based wireless strain sensors. For the experiment, silver-coated yarn was chosen to produce knitted fabrics with two different patterns and three levels of stitch densities. The uniaxial and biaxial deformation was applied to samples and at the same time, the change of electromagnetic shielding ability, electric resistance, and porosity of the sample set was evaluated. It can be summarized, that the vertical stretch has the highest positive effect on the electromagnetic shielding ability and the maximum shielding sensitivity is 12 % compared to other deformation types. In general, the electrical resistance decreases during increased stretch due to the increasing number of contacts between electrically conductive yarns, which causes a decrease in the contact resistance and also a decrease in total electrical resistance. The highest positive effect on the porosity of samples represents biaxial deformation. The finding that the overall shielding efficiency is positively influenced by the electrical conductivity of the sample and at the same time negatively influenced by the increasing porosity during tensile deformation was the motivation to construct a simple regression model for the prediction of the electromagnetic shielding ability of the sample during its extension.
针织物的拉伸变形对其电磁屏蔽能力、电阻和孔隙率的影响
如今,导电纺织材料除了用作抗静电、电磁屏蔽和制造智能纺织品等用途外,还广泛应用于传感领域。本文的主要目的是研究针织物的拉伸变形对其电磁屏蔽能力、电阻和孔隙率的影响,为构建基于纺织品的无线应变传感器提供知识。在实验中,选用镀银纱线制作两种不同图案和三种针迹密度的针织物。对样品施加单轴和双轴变形,同时评估样品组的电磁屏蔽能力、电阻和孔隙率的变化。可以总结出,垂直拉伸对电磁屏蔽能力的积极影响最大,与其他变形类型相比,最大屏蔽灵敏度为 12%。一般来说,在拉伸过程中,由于导电纱之间的接触数量增加,导致接触电阻减小,总电阻也随之减小,从而使电阻减小。双轴变形对样品孔隙率的积极影响最大。在拉伸变形过程中,样品的导电率会对总体屏蔽效率产生积极影响,同时孔隙率的增加又会对总体屏蔽效率产生消极影响,这一发现促使我们建立了一个简单的回归模型,用于预测样品在拉伸过程中的电磁屏蔽能力。
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
Journal of Industrial Textiles
Journal of Industrial Textiles MATERIALS SCIENCE, TEXTILES-
CiteScore
5.30
自引率
18.80%
发文量
165
审稿时长
2.3 months
期刊介绍: The Journal of Industrial Textiles is the only peer reviewed journal devoted exclusively to technology, processing, methodology, modelling and applications in technical textiles, nonwovens, coated and laminated fabrics, textile composites and nanofibers.
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