基于静电纺丝-静电喷涂协同工艺的跨尺度传感纱一步法制备及其应用

doi:10.13475/j.fzxb.20250401101

纺织学报 ›› 2025, Vol. 46 ›› Issue (12): 101-109.doi: 10.13475/j.fzxb.20250401101

基于静电纺丝-静电喷涂协同工艺的跨尺度传感纱一步法制备及其应用

王小虎¹^,², 包安娜¹^,², 魏静雯¹^,², 赵晓曼¹^,², 韩潇¹^,², 洪剑寒¹^,²^,³^,⁴()

1.绍兴文理学院纺织科学与工程学院, 浙江绍兴 312000
2.浙江省清洁染整技术研究重点实验室,浙江绍兴 312000
3.绍兴文理学院纤维基复合材料国家工程研究中心绍兴分中心, 浙江绍兴 312000
4.绍兴文理学院国家碳纤维工程技术研究中心浙江分中心, 浙江绍兴 312000

收稿日期:2025-04-07 修回日期:2025-07-30 出版日期:2025-12-15 发布日期:2026-02-06
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:王小虎(2001—),男,硕士生。主要研究方向为静电纺丝技术和纳米纤维制品的研发。
基金资助:
浙江省自然科学基金探索公益项目(LTGY24E030001);浙江省大学生创新创业项目(S202510349050);绍兴文理学院校级科研项目(Y20240253);绍兴文理学院校级科研项目(Y20240258)

One-step fabrication and application of cross-scale sensing yarns via synergistic electrospinning-electrospraying process

WANG Xiaohu¹^,², BAO Anna¹^,², WEI Jingwen¹^,², ZHAO Xiaoman¹^,², HAN Xiao¹^,², HONG Jianhan¹^,²^,³^,⁴()

1. School of Textile Science and Engineering, Shaoxing University, Shaoxing, Zhejiang 312000, China
2. Key Laboratory of Clean Dyeing and Finishing Technology of Zhejiang Province, Shaoxing, Zhejiang 312000, China
3. Shaoxing Sub-center of National Engineering Research Center for Fiber-based Composites, Shaoxing University, Shaoxing, Zhejiang 312000, China
4. Zhejiang Sub-center of National Carbon Fiber Engineering Technology Research Center, Shaoxing University, Shaoxing, Zhejiang 312000, China

Received:2025-04-07 Revised:2025-07-30 Published:2025-12-15 Online:2026-02-06

摘要/Abstract

摘要：

针对目前浸渍、涂敷工艺引入导电材料存在步骤繁琐、效率低且界面结合力弱等问题,基于静电纺丝-静电喷涂协同机制,通过一步法连续成形工艺高效构筑核鞘结构跨尺度传感纱线。采用多针水浴静电纺丝技术,将聚氨酯(TPU)纳米纤维喷射于接收浴面上,同时通过静电喷涂技术,将碳纳米管(CNTs)均匀沉积于TPU纳米纤维表面,构建出稳定的导电网络,然后均匀包覆氨纶上,制得基于纳米纤维包覆纱(NFCY)的CNTs/NFCY传感纱。研究结果表明,该传感纱在0%~200%的宽应变范围呈现高达4.31的灵敏度系数,在反复拉伸循环中表现出优异的耐久性,经过约 3 h拉伸-释放循环仍能保持稳定输出。该传感纱在语音识别、运动监测等应用场景中表现出优秀的性能,在可穿戴电子和柔性传感技术上展示出巨大应用潜力。

关键词: 静电纺丝, 静电喷涂, 碳纳米管, 微/纳结构包覆纱, 氨纶, 传感纱线, 应变传感, 智能可穿戴纺织品

Abstract:

Objective To develop a cross-scale manufacturing technology that simultaneously optimizes the mechanical performance of the substrate and the construction of conductive networks, a custom-designed water-bath electrospinning apparatus was employed to fabricate cross-scale micro/nano structured composite yarns, which are expected to integrate high specific surface area with excellent mechanical properties. Through a synergistic electrostatic spraying process, conductive materials were directionally deposited to construct a conductive network, thereby enabling the preparation of stretchable strain-resistance sensing yarns applicable to motion detection, error correction, and speech recognition.

Method By integrating sheath yarns with electrospinning techniques, nanofiber membranes were deposited onto the surface of a water bath, while the self-rotation of the yarns facilitated the fabrication of nanofiber-coated yarns. During the deposition process, electrostatic spraying was simultaneously applied. Due to electrostatic repulsion, carbon nanotubes (CNTs) were uniformly deposited onto the surface of the nanofibers, forming a conductive network. As the coating process progressed, CNT-adhered nanofiber-coated yarns (NFCY-CNTs) were obtained.

Results This paper introduces the one-step fabrication method for NFCY-CNTs, based on an independently developed water-bath electrospinning system, utilizing a coupled electrospinning-electrospraying technique. Experimental results demonstrated the successful construction of a multilayer structured composite yarn, where the core yarn provided mechanical support, the electrospinning process formed the nanofiber coating layer, and the electrospraying technique achieved directional deposition of a CNTs network so as to establish conductive pathways. Systematic characterization revealed that NFCY-CNTs possessed a dense and uniform nanofiber coating layer, with strong interfacial adhesion between CNTs and the fiber layer. The micro/nano structural integrity remained stable after prolonged tensile stress and washing treatments. Mechanical tests showed a synergistic reinforcement effect between the core yarn and the outer coating, with the breaking strength increasing from (1 092.8 ± 22.9) cN to (1 182.1 ± 28.0) cN, and the elongation at break improving from (577.6 ± 12.25)% to (585.3 ± 8.20)%, confirming the mechanical enhancement offered by the composite structure. The conductive network endowed the yarn with excellent strain-sensing performance, with its gauge factor exhibiting a strain-dependent graded response. Stable electrical signal output was maintained under long-term cyclic loading and the composite yarn demonstrated a consistent strain-resistance response even within small strain ranges. Experimental results verify the yarn's high sensitivity and fast response in joint motion monitoring, posture analysis, and speech vibration sensing, confirming its potential for intelligent medical monitoring, sports biomechanics assessment, and human-machine interfaces. Highlighting its potential for wearable sensing applications.

Conclusion This study proposes a one-step synergistic electrospinning-electrospraying technology for constructing NFCY-CNTs. The technique achieves uniform nanofiber coating and orderly assembly through electrospinning, which enhances the yarn's surface properties and increases the mechanical strength of the yarn. Concurrently, electrospraying facilitates directional CNT deposition to form a stable 3D conductive network, resulting in a linear resistance response over a broad strain range (0%-200%). To address interfacial instability in flexible sensing yarns, a medical elastic bandage-inspired fixation strategy was implemented to suppress yarn slippage and ensure reliable dynamic signal acquisition for more than 5 000 cycles. In summary, this fabrication strategy broadens functional yarn design via nanomaterial synergy and enables future integration of miniaturized signal processors with optimized multiscale compatibility, advancing flexible e-textiles toward wearable health monitoring applications.

Key words: electrospinning, electrospraying, carbon nanotube, micro/nano structured composite yarn, polyurethane fiber, sensing yarn, strain sensing, smart wearable textiles

中图分类号:

TS176

王小虎, 包安娜, 魏静雯, 赵晓曼, 韩潇, 洪剑寒. 基于静电纺丝-静电喷涂协同工艺的跨尺度传感纱一步法制备及其应用[J]. 纺织学报, 2025, 46(12): 101-109.

WANG Xiaohu, BAO Anna, WEI Jingwen, ZHAO Xiaoman, HAN Xiao, HONG Jianhan. One-step fabrication and application of cross-scale sensing yarns via synergistic electrospinning-electrospraying process[J]. Journal of Textile Research, 2025, 46(12): 101-109.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250401101

http://www.fzxb.org.cn/CN/Y2025/V46/I12/101

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参考文献 27

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样品	断裂强力/cN	断裂伸长率/%
氨纶	1 092.8±22.9	577.6±12.25
NFCY	1 182.1±28.0	585.3±8.19
CNTs/NFCY	924.7±27.3	483.7±7.03

应变/%	E_GF值	线性拟合方程
5	1.44	y = 0.00 9 8x - 0.020 7(R²=0.928 6)
10	2.21	y = 0.013 8 x - 0.053 6(R²=0.944 1)
25	2.42	y = 0.019 7 x - 0.095 4(R²=0.966 3)
50	2.72	y = 0.019 8 x + 0.004 6(R²=0.994 2)
100	4.31	y = 0.024 6 x - 0.084 8(R²=0.988 6)
200	2.80	y = 0.023 8 x -0.064 9(R²=0.972 7)

基于静电纺丝-静电喷涂协同工艺的跨尺度传感纱一步法制备及其应用

One-step fabrication and application of cross-scale sensing yarns via synergistic electrospinning-electrospraying process

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