全针织结构多模态柔性电容传感器的构筑及其传感性能

doi:10.13475/j.fzxb.20250602201

纺织学报 ›› 2026, Vol. 47 ›› Issue (1): 123-131.doi: 10.13475/j.fzxb.20250602201

全针织结构多模态柔性电容传感器的构筑及其传感性能

邵剑波¹^,², 岳欣琰², 陈雨², 韩潇²^,³, 洪剑寒¹^,²^,³()

1.绍兴理工学院纺织服装与设计学院, 浙江绍兴 312000
2.绍兴文理学院纺织科学与工程学院, 浙江绍兴 312000
3.浙江省清洁染整技术研究重点实验室, 浙江绍兴 312000

收稿日期:2025-06-10 修回日期:2025-07-30 出版日期:2026-01-15 发布日期:2026-01-15
通讯作者: 洪剑寒(1982—),男,教授,博士。主要研究方向为新型纺织材料的制备与应用。E-mail:jhhong@usx.edu.cn。
作者简介:邵剑波(2002—),男,硕士生。主要研究方向为针织结构柔性器件的设计开发与应用。
基金资助:
国家级大学生创新创业训练计划项目(202310349025);浙江省自然科学基金探索公益项目(LTGY24E030001)

Construction and sensing performance of all knitted multi-modal flexible capacitive sensor

SHAO Jianbo¹^,², YUE Xinyan², CHEN Yu², HAN Xiao²^,³, HONG Jianhan¹^,²^,³()

1. School of Textile, Apparel and Art Design, Shaoxing Institute of Technology, Shaoxing, Zhejiang 312000, China
2. School of Textile Science and Engineering, Shaoxing University, Shaoxing, Zhejiang 312000, China
3. Key Laboratory of Clean Dyeing and Finishing Technology of Zhejiang Province, Shaoxing, Zhejiang 312000, China

Received:2025-06-10 Revised:2025-07-30 Published:2026-01-15 Online:2026-01-15

摘要/Abstract

摘要：

为获得具有拉伸-压力-非接触感知功能的全针织结构多模态柔性电容传感器,以镀银聚酰胺6为芯纱,利用涤纶与聚氨酯进行双重包覆,得到了聚氨酯-涤纶/镀银聚酰胺6复合导电纱线,并将其织制成纬平针组织的全针织结构柔性电容传感器。测试了复合导电纱线的相关性能,分析了传感器的拉伸、压力及非接触感知传感性能。结果表明:相较于芯纱,复合导电纱线的断裂强力与断裂伸长率分别提升了216.9%与9.33%,但导电能力有所下降;传感器具有良好的多模态传感能力,在拉伸传感中,灵敏系数最高可达0.324 3,在8.8 mm/s的拉伸速度下,拉伸1 000 s,电容波动较小,重复性较好;在压力传感中,可识别物体质量,且在同种压力作用下电容变化稳定;在非接触传感中,具有多方向敏感性,且可识别物体尺寸、靠近速度和距离。该传感器可用于监测人体呼吸体征及关节弯曲角度。

关键词: 全针织结构, 复合导电纱线, 柔性传感器, 电容传感器, 传感性能, 人体运动监测, 智能纺织品

Abstract:

Objective Flexible sensors, as the core components of intelligent textiles, have become a new research hotspot. Multi-modal sensors have a broader market prospect by virtue of their ability to monitor various external signals. At present, research on multi-modal flexible capacitive sensors mainly focuses on three-dimensional and one-dimensional structures. Three-dimensional flexible sensors are difficult to miniaturize due to their relatively large thickness and area. Long time wearing of one-dimensional flexible capacitive sensors has been reported to cause a sense of compression or friction discomfort to the skin. Therefore, it is of great significance to develop a two-dimensional knitted flexible sensor that is comfortable to wear and well integrated with clothing.

Method Silver-coated polyamide fiber (SCP) was used as the core yarn, on which double-layer polyester (PET) was wrapped, with the inner layer being S-twist and the outer layer being Z-twist, and the twist factor was 1 000 twists/m. PET/SCP yarn was thus prepared. A layer of waterborne polyurethane (PU) was coated on the outer surface of the PET/SCP yarn to obtain PU-PET/SCP composite conductive yarn, which was used as raw material to prepare an all knitted multi-modal flexible capacitive sensor. The influence of coating process on the performance of core yarn was studied. The tensile, pressure and non-contact sensing properties of the sensor were analyzed, and the sensor was applied to human activity monitoring.

Results After PET wrapping and PU coating, the mechanical properties of the composite yarns were significantly improved, with the breaking strength and elongation at break increased by 216.9% and 9.33%, respectively. The composite conductive yarns were knitted into a flexible capacitive sensor with the plain knitted structure on a computerized flat knitting machine, and the sensor was designed to have multi-modal external force detection capabilities. In the tensile sensing tests in both the transverse and longitudinal directions, the capacitance of the sensor gradually increased with the increase of strain. The maximum sensitivity coefficient reached 0.324 3. Under the condition of stretching at a speed of 8.8 mm/s for 250 s at different elongation rates for a total of 1 000 s, the capacitance change of the sensor was relatively stable, demonstrating good repeatability. The sensor had good linearity, with R² values of the fitting equations being higher than 0.97 at different elongation rates, indicating that within a certain strain range, the ΔC/C₀ and elongation rate of the sensor showed a good linear correlation. In the pressure sensing test, by placing weights on the sensor, it was found that the sensor had good recognition ability for weights of different masses, and the capacitance change was stable for weights of the same mass, demonstrating good pressure sensing characteristics. In the non-contact sensing performance test, the sensor demonstrated multi-directional sensitivity. When an object approaches in either the vertical or horizontal direction, the sensor can display a relatively stable capacitance change signal. When an object approached the sensor without contact, the capacitance of the sensor gradually decreased with both the diminishing distance to the object and the increasing area of the object. This sensor demonstrates excellent non-contact sensing capabilities. It can identify the size (from a finger to a palm) and speed of approaching objects, and the corresponding relative capacitance changes are respectively significant. The speed detection was validated at specific vertical and horizontal palm movement frequencies.For human body monitoring, it precisely measures arm and knee bending (by 0°-90°) and detects respiratory rate by capturing the periodic capacitance variations caused by abdominal movements during breathing.

Conclusion A core-spun yarn structure was fabricated using SCP as the core yarn and PET as the sheath, subsequently over-coated with a PU layer to produce PU-PET/SCP composite conductive yarn. The composite conductive yarn exhibited excellent mechanical properties. The knitted capacitive sensors based on the PU-PET/SCP composite conductive yarn demonstrated the capability to monitor three types of external loading, i.e. stretching, pressure, and non-contact interactions. The two-dimensional knitted structure of the sensor features compact dimensions in both area and thickness, ensuring enhanced wearing comfort. Owing to these characteristics, this sensor shows significant application potential in fields such as human motion monitoring, healthcare, and robotics.

Key words: all knitted structure, composite conductive yarn, flexible sensor, capacitive sensor, sensing performance, human motion monitoring, smart texiles

中图分类号:

TS101.922

邵剑波, 岳欣琰, 陈雨, 韩潇, 洪剑寒. 全针织结构多模态柔性电容传感器的构筑及其传感性能[J]. 纺织学报, 2026, 47(1): 123-131.

SHAO Jianbo, YUE Xinyan, CHEN Yu, HAN Xiao, HONG Jianhan. Construction and sensing performance of all knitted multi-modal flexible capacitive sensor[J]. Journal of Textile Research, 2026, 47(1): 123-131.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250602201

http://www.fzxb.org.cn/CN/Y2026/V47/I1/123

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纱线	断裂强力/N	断裂伸长率/%
SCP	7.85±0.64	37.10±2.27
PET/SCP	24.21±0.46	42.09±0.86
PU-PET/SCP	24.88±0.49	40.56±0.83

纱线	单位电阻/(Ω·cm^-1)
纱线	芯层	外层
SCP	4.49±0.97	—
PET/SCP	4.91±1.00	超量程,>5×10⁷
PU-PET/SCP	5.24±1.26	超量程,>5×10⁷

方向	伸长率/%	G_GF	线性拟合方程
横向	20	0.079 1	y_T=1.923x-0.131, R²=0.978
	30	0.159 3	y_T=3.250x+0.134, R²=0.994
	40	0.160 3	y_T=3.251x+0.244, R²=0.995
	50	0.173 6	y_T=3.333x-0.445, R²=0.996
纵向	20	0.277 0	y_v=6.661x-0.490, R²=0.990
	30	0.301 6	y_v=7.193x-0.316, R²=0.979
	40	0.306 9	y_v=7.965x-1.022, R²=0.979
	50	0.324 3	y_v=8.931x-1.052, R²=0.977

全针织结构多模态柔性电容传感器的构筑及其传感性能

Construction and sensing performance of all knitted multi-modal flexible capacitive sensor

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