Electrical Resistivity of Conductive Leather and Influence of Air Temperature and Humidity

IF 0.7 Q3 MATERIALS SCIENCE, TEXTILES

TEKSTILEC Pub Date : 2021-12-02 DOI:10.14502/tekstilec2021.64.298-304

I. Kazani, M. Hylli, P. Berberi

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引用次数: 3

Abstract

Leather is a material that has been used in different applications for centuries. Today, living in the era of high-tech¬nology, we are surrounded by smart products. For this reason, traditional products must be changed or im¬proved in order to support and make us more comfortable while using them. For instance, the touch screen display in electronics products is a smart phone’s or a tablet computer’s primary input device. Still, traditional leather will not function properly in a cold climate or other specific conditions. To make it conductive in such conditions, the double in-situ polymerization of the pyrrole coating method was used. The aim of this study was to observe the electrical properties of conductive leather. At the same time, it stands up to a wide range of different air temperatures, and relative and absolute humidity. These properties are essential because de¬signers and textile engineers should be familiar with them when they decide to use materials in different smart products. Electricity conductivity tests were carried out in year-round temperatures from 7.5 °C to 28.1 °C, with a relative humidity from 18% to 77% and a vapor air concentration from 2.77 g/kg to 12.46 g/kg. The so-called “multiple-step method” was used to test leather’s electrical resistivity for the first time. The method considers a material’s compressional properties and provides an indicator inherent for a material’s electrical properties, regardless of the mass and shape of samples. The results showed a strong dependence between water vapor air concentration and electrical resistivity, described using the formula ρ = 1.3103 H−1.04 Ωm, with a correlation coefficient of 0.87. There was no relation between relative humidity and electrical resistivity, and resistivity and air temperature. Also, the results confirmed again that changes in the shape of the sample used during tests did not influence the measurement’s results, but supported the appropriateness of the measuring method.

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导电皮革的电阻率及空气温度和湿度的影响

皮革是一种已经在不同应用中使用了几个世纪的材料。今天，生活在高科技时代，我们被智能产品所包围。因此，必须改变或改进传统产品，以便在使用时为我们提供支持并使我们更舒适。例如，电子产品中的触摸屏显示器是智能手机或平板电脑的主要输入设备。尽管如此，传统皮革在寒冷的气候或其他特定条件下仍无法正常工作。为了使其在这种条件下导电，使用了吡咯涂层法的双原位聚合。本研究的目的是观察导电皮革的电学性能。同时，它能承受各种不同的空气温度、相对湿度和绝对湿度。这些特性至关重要，因为设计人员和纺织工程师在决定在不同的智能产品中使用材料时应该熟悉它们。电导率测试在7.5°C至28.1°C的全年温度下进行，相对湿度为18%至77%，蒸汽空气浓度为2.77 g/kg至12.46 g/kg。首次采用所谓的“多步法”测试皮革的电阻率。该方法考虑了材料的压缩特性，并为材料的电学特性提供了固有的指标，而与样品的质量和形状无关。结果表明，水蒸气-空气浓度与电阻率之间存在很强的相关性，用公式ρ=1.3103H−1.04Ωm描述，相关系数为0.87。相对湿度和电阻率、电阻率和空气温度之间没有关系。此外，结果再次证实，测试期间使用的样品形状的变化不会影响测量结果，但支持测量方法的适当性。

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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