纺织学报 ›› 2023, Vol. 44 ›› Issue (01): 100-105.doi: 10.13475/j.fzxb.20211100606

• 纺织工程 • 上一篇    下一篇

捻度对棉/氨纶/银丝包芯纱性能的影响

李龙(), 吴磊, 林思伶   

  1. 西安工程大学 纺织科学与工程学院, 陕西 西安 710048
  • 收稿日期:2021-11-01 修回日期:2022-09-29 出版日期:2023-01-15 发布日期:2023-02-16
  • 作者简介:李龙(1964―),男,教授,博士。主要研究方向为天然纤维材料资源及其纺织技术。E-mail:lilong2188@126.com
  • 基金资助:
    陕西省教育厅科研计划项目(18JK0337)

Influence of yarn twist on properties of cotton/spandex/silver wire core spun yarns

LI Long(), WU Lei, LIN Siling   

  1. School of Textile Science & Engineering, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
  • Received:2021-11-01 Revised:2022-09-29 Published:2023-01-15 Online:2023-02-16

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摘要:

为了制备具有良好纺织特性的弹性导电纱线材料,以棉粗纱、氨纶、银丝为原料,通过设计原料的喂入方式及在环锭纺纱机的前罗拉与导纱钩之间附加定位装置,纺制以氨纶为纱芯、银丝与棉纤维螺旋包缠氨纶且棉纤维位于纱线表面的弹性导电包芯纱,探究捻度对纱线弹性、导电性、耐磨性和断裂强力的影响。以银丝紧贴氨纶表面包缠为模型,计算得到不同捻度下包芯纱中紧贴氨纶表面包缠的银丝长度的理论值。实验结果表明:包芯纱的弹性随捻度变化,在70捻/(10 cm)时包芯纱定伸长伸长弹性率、定负荷伸长弹性率较大;在包芯纱伸直(不伸长)状态下,纱线实测电阻值随捻度的增大而增大;在包芯纱伸长10%的状态下其实测电阻值小于伸直状态下等长度包芯纱实测电阻值,且在75 捻/(10 cm)时伸长状态与伸直状态下的相同长度包芯纱的实测电阻值之差较小。

关键词: 包芯纱, 导电纱线, 银丝, 氨纶, 捻度, 导电性

Abstract:

Objective The application of conductive yarns in flexible and wearable smart devices has attracted extensive attention from many researchers. The key objectives of this research included preparing elastic and conductive yarns with excellent textile properties such as color attributes, wearing comfort, and environmental friendliness.
Method In order to prepare a conductive yarn with favorable textile properties, cotton roving, silver wire and spandex were selected as the raw materials. By designing the feeding of raw materials and attaching a positioning device between the front roller and the yarn guide in the ring spinning machine, an elastic conductive core yarn with spandex as the core, silver yarn and cotton fibers as the sheath with cotton fibers on the surface of the yarn was produced to investigate the influence of yarn twist on the elasticity, conductivity, abrasion resistance and breaking strength of the core spun yarn. Using the model of silver wire tightly wrapped around the spandex surface (Fig.2), the theoretical value of the length of silver wire wrapped around the spandex surface in the core spun yarn with different yarn twist was calculated.
Results The experimental results showed that the elasticity of core spun yarn varied with yarn twist, and the elasticity of core spun yarn at constant elongation and at constant load was larger at a yarn twist of 70 twist/(10 cm) than yarns with other yarn twists (Fig.4). In the unstretched straight state of the core spun yarn, the measured resistance of the yarn increased with the increase of yarn twist (Tab. 2), because increasing the yarn twist causes the pitch of the wrapping silver wire to decrease and the length of the silver wire in the unit length of core spun yarn to increase. At 10% elongation of the core spun yarn, the measured resistance of the yarn was smaller than that of the same length of core spun yarn in the unstretched state, and the difference between the measured resistance of the same length of core yarn in the elongated state and in the unstretched state was smaller at a twist of 75 twist/(10 cm) (Tab. 3). At 10% elongation of the core spun yarn, the measured resistance of the core yarn per unit length was greater than the theoretical resistance of the straight silver wire, indicating that when the core spun yarn elongation is at 10%, the silver wire in the yarn was not at the completely straightened state, and the yarn elongation caused the pitch of the silver wire over the spandex became larger and the actual length of the silver wire in the core spun yarn per unit length became smaller. At 75 twist/(10 cm), the core spun yarn showed higher wear resistance. Because when the twist is too high, the torque of cotton fibers in the yarn is high, the fiber stress increases, causing the cotton fibers to be easily worn off and the wear resistance of the core spun yarn is reduced.
Conclusion The elasticity and conductivity of core spun yarn are closely related to the yarn twist level. For the actual core spun yarns, the silver wire is not tightly wrapped around the surface of the spandex core, and there are cotton fibers between the spandex and the silver wire, causing the theoretical resistance value per unit length to be smaller than the measured resistance value. Since cotton fibers can be dyed in different colors and the cotton fibers are distributed on the surface of the core spun yarn, this work can be used to further develop elastic and conductive yarns in different colors and comfortable to wear for the transmission of electrical signals in smart wearable textiles, powering electronic textiles, and electrical heating devices. The preparation process of this core spun yarn is environmental friendly. In the application of flexible and wearable smart devices, such elastic and conductive core spun yarsn have a good development prospect.

Key words: core spun yarn, conductive yarn, silver wire, spandex, yarn twist, electrical conductivity

中图分类号: 

  • TS114.7

图1

包芯纱纺纱示意图"

图2

银丝紧贴氨纶表面包缠示意图"

表1

不同捻度下的β, L与Lt值"

捻度/(捻·(10 cm)-1) β/(°) L/(10-1cm) Lt/cm
65 86.46 2.488 2 1.617
70 86.71 2.487 5 1.741
75 86.93 2.487 0 1.865
80 87.12 2.486 6 1.989
85 87.29 2.486 2 2.113
90 87.44 2.485 9 2.237

图3

不同捻度包芯纱的耐磨次数"

图4

不同捻度包芯纱的弹性率"

图5

不同捻度纱线的断裂强力"

表2

实测电阻与理论电阻的计算结果"

捻度/(捻·(10 cm)-1) Ry Ry标准差/Ω Rt
65 1.055 2 0.028 3 1.017 3
70 1.229 8 0.082 4 1.095 3
75 1.340 3 0.061 6 1.173 3
80 1.735 1 0.079 4 1.251 3
85 1.762 7 0.067 1 1.329 3
90 1.816 1 0.043 6 1.407 3

图6

包芯纱的外观形貌"

表3

伸长10%后包芯纱的实测电阻值"

捻度/(捻·(10 cm)-1) Rs Rs标准差 /Ω Ry-Rs
65 0.877 2 0.023 1 0.178 0
70 0.997 1 0.063 2 0.232 7
75 1.226 7 0.052 3 0.113 6
80 1.576 0 0.061 4 0.159 1
85 1.591 2 0.058 7 0.171 5
90 1.662 2 0.040 3 0.153 9
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