Journal of Textile Research ›› 2026, Vol. 47 ›› Issue (05): 9-17.doi: 10.13475/j.fzxb.20250800101

• Fiber Materials • Previous Articles     Next Articles

Preparation and properties of self-healing polyurethane ionogel fiber-based flexible sensing material

REN Yingying, LI Qianqian, LUO Mengying, WANG Dong, LI Mufang()   

  1. Key Laboratory of Textile Fiber and Products, Ministry of Education, Wuhan Textile University, Wuhan, Hubei 430200, China
  • Received:2025-08-01 Revised:2026-03-05 Online:2026-05-15 Published:2026-07-10
  • Contact: LI Mufang E-mail:limufang223@126.com

Abstract:

Objective Conventional ionogel sensors are critically limited by dense film formats, suffering from poor moisture/air permeability and wearing comfort. This study combines a self-healing polyurethane (SHPU) matrix, based on dynamic imine-urea bonds, with the ionic liquid EMIM:DCA to create a material engineered in both film and fiber forms. The primary objective is to establish a scalable material fabrication route (solution casting, wet spinning), optimizing conductivity, robust mechanical properties, efficient intrinsic self-healing, and reliable sensing capabilities essential for practical, long-term wearable health monitoring.

Method SHPU was synthesized via catalytic reaction using poly(tetramethylene ether) glycol (PTMEG), isophorone diisocyanate (IPDI), and dynamic chain extenders (2-amino-4-methyl-6-hydroxypyrimidine (UPy), dimethylglyoxime (DMG) and glycerol). SHPU dissolved in tetrahydrofuran (THF)/ethanol was blended with 10%-40% ionic liquid EMIM:DCA. Films were prepared by solution-casting, and fibers were wet-spun into a water coagulation bath, using solvent ratio and drawing speed to control the fiber morphology. The chemical structure was confirmed by Fourier transform intrared spectroscopy (FT-IR), and surface wettability, thermal stability, mechanical/self-healing properties, and morphology were characterized via contact angle, thermogravimtric analysis (TGA), tensile tests, and scanning electron microscopy (SEM), respectively. Fiber sensing performance was assessed by recording resistance changes during cyclic stretching using a coupled universal tester and source meter.

Results The experimental results revealed that the prepared films possess excellent thermal stability, with an initial thermal decomposition temperature exceeding 150 ℃. As EMIM:DCA content increased, the films became noticeably more hydrophilic, with water contact angle decreasing from 109.6° for pure SHPU to 47.91° for films containing 40% EMIM:DCA.

In terms of mechanical properties, the SHPU film containing 10% EMIM:DCA exhibited a tensile strength of 10.2 MPa and an elongation at break of 685%. Higher ionic liquid content caused reduction in strength but improved material compliance. All formulations showed outstanding self-healing ability. After being cut and healed at 80 ℃ for 12 h, stress healing efficiency exceeded 88% and strain healing efficiency exceeded 89% across the series. Notably, the 40% EMIM:DCA film achieved full (100%) stress self-healing. Optical microscopy confirmed that the cut interfaces closed effectively after healing.

SEM images confirmed that wet spinning produced continuous, uniform EMIM:DCA/SHPU fibers with smooth surfaces without obvious defects. The sensing performance of the fibers depended strongly on the EMIM:DCA content. Fibers with 30% EMIM:DCA offered an optimal balance, acting as effective strain sensors with a gauge factor of 3.58 within the 50%-120% strain range. These sensors responded rapidly, exhibiting both response and recovery times within 703 ms during hand-motion detection. In practical tests, the fiber sensors reliably monitored and distinguished complex human movements. Real-time resistance signals clearly captured variations corresponding to flexion and extension of the wrist, elbow, index finger, and middle finger. For example, elbow bending at different angles (0°, 30°, 60°, 90°) produced a distinct stepwise increase in relative resistance. Moreover, the sensors maintained stable signal output over 500 stretch-release cycles at 50% strain, demonstrating good durability for dynamic motion tracking.

Conclusion EMIM:DCA/SHPU iongel films and fibers with different EMIM:DCA contents were successfully prepared by solution casting and wet spinning techniques. By regulating the content of EMIM:DCA, the sensing performance of the composite materials was enhanced. EMIM:DCA exhibited excellent compatibility with the SHPU matrix and could be uniformly dispersed within the SHPU matrix. The EMIM:DCA/SHPU films showed good mechanical self-healing properties and outstanding thermal stability. After cutting, the EMIM:DCA/SHPU conductive composite fibers could be self-healed. The EMIM:DCA/SHPU conductive fibers featured excellent sensitivity, with both response time and self-healing time for hand movements reaching the millisecond level. The sensors could accurately capture the movement states of the wrist, elbow, fingers and other parts, and output stable resistance response signals, demonstrating broad application potential in the field of flexible sensing.

Key words: functional polymer material, self-healing polyurethane, wet spinning, ionogel fiber, flexible sensor

CLC Number: 

  • TS102.5

Fig.1

Preparation diagram of EMIM:DCA/SHPU ionogel fibers"

Fig.2

FT-IR spectra of SHPU film, EMIM:DCA ionic liquid, and EMIM:DCA/SHPU films with different EMIM: DCA mass fractions"

Fig.3

Contact angles of EMIM:DCA/SHPU ionogel films with different EMIM:DCA mass fractions"

Fig.4

Thermogravimetric analysis diagrams of EMIM:DCA/SHPU films with different EMIM:DCA contents. (a) TG curves; (b) DTG curves"

Fig.5

Self-healing mechanism of EMIM: DCA/SHPU conductive film"

Fig.6

Stress-strain diagrams of EMIM: DCA/SHPU films with different EMIM:DCA contents in original state and after self-healing at 80 ℃ for 12 h"

Tab.1

Healing efficiency of mechanical properties for EMIM: DCA/SHPU films after self-healing at 80 ℃ for 12 h"

试样
编号
EMIM:DCA
质量分数/%
初始强度/
MPa
修复后
强度/MPa
应力自修
复率/%
应变自修
复率/%
1 10 10.23 9.07 88.48 100
2 20 7.37 7.06 95.82 96.84
3 30 3.90 3.45 88.49 93.47
4 40 2.27 2.27 100 89.85

Fig.7

Optical images of fracture interface self-healing performance process of EMIM:DCA/SHPU ionogel films"

Fig.8

SEM images of surface, cross-section, and high-magnification cross-section of EMIM:DCA/SHPU fibers"

Fig.9

Schematic diagram of sensing mechanism of EMIM: DCA/SHPU fiber sensors"

Fig.10

Resistance-strain curves of EMIM:DCA/SHPU fibers with different EMIM:DCA mass fractions"

Fig.11

Relative resistance change curve of EMIM: DCA/SHPU during 500 loading-unloading cycles"

Fig.12

Human motion detection performance of EMIM:DCA/SHPU sensors. (a) Elbow joint motion;(b) Wrist joint motion; (c) Index finger motion; (d) Middle finger motion"

[1] ZHAO C Z, PARK J, ROOT S E, et al. Skin-inspired soft bioelectronic materials, devices and systems[J]. Nature Reviews Bioengineering, 2024, 2(8): 671-690.
doi: 10.1038/s44222-024-00194-1
[2] YUAN Y M, LIU B H, ADIBEIG M R, et al. Microstructured polyelectrolyte elastomer-based ionotronic sensors with high sensitivities and excellent stability for artificial skins[J]. Advanced Materials, 2024, 36(11): 2310429.
doi: 10.1002/adma.v36.11
[3] 王汉琛, 吴嘉茵, 黄彪, 等. 生物相容性纳米纤维素自愈合水凝胶的构建及其性能[J]. 纺织学报, 2023, 44(12): 17-25.
doi: 10.13475/j.fzxb.20220704301
WANG Hanchen, WU Jiayin, HUANG Biao, et al. Fabrication and properties of biocompatible nanocellulose self-healing hydrogels[J]. Journal of Textile Research, 2023, 44(12): 17-25.
doi: 10.13475/j.fzxb.20220704301
[4] CHEN Z J, SHEN T Y, ZHANG M H, et al. Tough, anti-fatigue, self-adhesive, and anti-freezing hydrogel electrolytes for dendrite-free flexible zinc ion batteries and strain sensors[J]. Advanced Functional Materials, 2024, 34(26): 2314864.
doi: 10.1002/adfm.v34.26
[5] CAI Y W, WANG G G, MEI Y C, et al. Self-healable, super-stretchable and shape-adaptive triboelectric nanogenerator based on double cross-linked PDMS for electronic skins[J]. Nano Energy, 2022, 102: 107683.
doi: 10.1016/j.nanoen.2022.107683
[6] LI M F, LI Q Q, WANG W W, et al. Tough and self-healing polyurethane elastomer and its application for fiber-based self-encapsulating strain sensor[J]. Chemical Engineering Journal, 2025, 513: 162791.
doi: 10.1016/j.cej.2025.162791
[7] 刘锦锋, 杜康存, 肖畅, 等. 多孔MXene/热塑性聚氨酯纤维的制备及其应力应变传感性能[J]. 纺织学报, 2025, 46(3): 41-48.
LIU Jinfeng, DU Kangcun, XIAO Chang, et al. Preparation of porous MXene/thermoplastic polyurethane fiber and its stress-strain sensing performance[J]. Journal of Textile Research, 2025, 46(3): 41-48.
[8] 阳腾, 孙志慧, 伍思钰, 等. 基于聚氨酯/炭黑/锦纶导电纱线的织物应变传感器制备及其性能[J]. 纺织学报, 2024, 45(12): 80-88.
doi: 10.13475/j.fzxb.20230905001
YANG Teng, SUN Zhihui, WU Siyu, et al. Preparation and performance of fabric sensor based on polyurethane/carbon black/polyamide conductive yarn[J]. Journal of Textile Research, 2024, 45(12): 80-88.
doi: 10.13475/j.fzxb.20230905001
[9] FU C Y, WANG K, TANG W Y, et al. Multi-sensorized pneumatic artificial muscle yarns[J]. Chemical Engineering Journal, 2022, 446: 137241.
doi: 10.1016/j.cej.2022.137241
[10] WANG X W, ZHENG S J, XIONG J F, et al. Stretch-induced conductivity enhancement in highly conductive and tough hydrogels[J]. Advanced Materials, 2024, 36(25): 2313845.
doi: 10.1002/adma.v36.25
[11] 于梦菲, 高文丽, 任婧, 等. 摩擦纳米发电机用皮芯结构纤维的制备及其性能[J]. 纺织学报, 2025, 46(5): 1-9.
YU Mengfei, GAO Wenli, REN Jing, et al. Preparation and properties of core-sheath fiber for triboelectric nanogenerator[J]. Journal of Textile Research, 2025, 46(5): 1-9.
doi: 10.1177/004051757604600101
[12] LYU X L, ZHANG H Q, SHEN S T, et al. Multi-modal sensing ionogels with tunable mechanical properties and environmental stability for aquatic and atmospheric environments[J]. Advanced Materials, 2024, 36(45): 2410572.
doi: 10.1002/adma.v36.45
[13] LI H L, XU F C, WANG J L, et al. Self-healing fluorinated poly(urethane urea) for mechanically and environmentally stable, high performance, and versatile fully self-healing triboelectric nanogenerators[J]. Nano Energy, 2023, 108: 108243.
doi: 10.1016/j.nanoen.2023.108243
[14] JIANG N, CHANG X H, HU D W, et al. Flexible, transparent, and antibacterial ionogels toward highly sensitive strain and temperature sensors[J]. Chemical Engineering Journal, 2021, 424: 130418.
doi: 10.1016/j.cej.2021.130418
[1] ZHAO Meining, LI Bo, SUN Yanli, WU Hailiang, TIAN Shiyi. Development of regenerated wool keratin-based composite fibers with photothermal transformation [J]. Journal of Textile Research, 2026, 47(04): 17-25.
[2] WU Xinyuan, DONG Zijing, WANG Ruixia, YAN Ziyue, SUN Tingwen, HU Ye, WU Yingnan, SUN Runjun. Preparation of polyurethane/carbon black conductive plied yarn and its strain sensing performance [J]. Journal of Textile Research, 2026, 47(04): 96-103.
[3] FENG Xiaoli, GONG Junyao, XIA Liangjun, XU Weilin. Research progress in magnetoelectric flexible sensors [J]. Journal of Textile Research, 2026, 47(03): 107-117.
[4] GUO Yiming, YU Shuang, ZHAO Fan, WANG Fujun. Construction and performance evaluation of fiber-based piezoelectric sensors for vascular monitoring [J]. Journal of Textile Research, 2026, 47(03): 118-128.
[5] SUN Xiaoyun, YUE Chengfei, ZHANG Ruquan. Preparation and performance of flexible temperature sensor based on laser-induced graphene [J]. Journal of Textile Research, 2026, 47(03): 129-138.
[6] XUE Baoxia, FENG Jiaxin, SHAO Ziyang, LU Jiaxin, LIU Jing, NIU Mei, ZHANG Li. Effect of pre-crosslinked copper ions on structure and properties of carboxymethyl cellulose antibacterial aerogel fibers [J]. Journal of Textile Research, 2026, 47(03): 52-59.
[7] ZHANG Ran, ZHU Shiling, WANG Dong, LIU Qiongzhen, LU Ying. Preparation and properties of bismuth sulfide/carbon nanotube/polyvinylidene fluoride composite temperature-sensing fibers [J]. Journal of Textile Research, 2026, 47(02): 18-25.
[8] LIU Yiming, LI Lin, DU Xianjing, LIU Pan, YIN Xia, TIAN Mingwei. Preparation of elastic conductive yarns with internal spiral structure and regulation of their strain-insensitive performance [J]. Journal of Textile Research, 2026, 47(01): 115-122.
[9] 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(01): 123-131.
[10] HU Weilin, BAI Jie, LIU Dan, BAI Meng, LI Juan, LI Qizheng. Research progress in e-textiles based on machine learning model [J]. Journal of Textile Research, 2026, 47(01): 268-276.
[11] CHEN Kelin, LI Zhuo, WANG Xiaoge, LI Chengjin, HU Jianchen, ZHANG Keqin. Preparation and performance of photochromic fibers based on polyhydroxyalkanoates by microfluidic wet spinning [J]. Journal of Textile Research, 2026, 47(01): 46-53.
[12] LIU Ke, WANG Yuxi, CHENG Pan, ZHU Liping, XIA Ming, MEI Tao, XIANG Yang, ZHOU Feng, GAO Fei, WANG Dong. Preparation of porous sulfonated hydrogenated styrene-butadiene block copolymer fiber membrane and its adsorption performance for lysozyme [J]. Journal of Textile Research, 2025, 46(12): 1-10.
[13] ZHANG Ying, GUO Mingjing, WANG Lijun. Design of knitted temperature sensors and their sensing performance under wearing conditions [J]. Journal of Textile Research, 2025, 46(12): 123-132.
[14] YAO Xiaojun, XU Enting, YANG Xueyuan, FANG Lei, BAO Wei, FANG Kuanjun. Regulation of polyvinylpyrrolidone on structure and properties of polyethylene terephthalate hollow fiber membranes [J]. Journal of Textile Research, 2025, 46(12): 66-73.
[15] DENG Jing, WANG Ruining, SUN Runjun, ZHANG Yajuan, GUO Haibing, LEI Ke. Sodium alginate modified waterborne polyurethane/liquid metal conductive sensing fibers for pulse monitoring [J]. Journal of Textile Research, 2025, 46(12): 74-82.
Viewed
Full text


Abstract

Cited

  Shared   
  Discussed   
No Suggested Reading articles found!