湿响应纤维束的制备及其驱动性能

doi:10.13475/j.fzxb.20251002301

摘要/Abstract

摘要：

为解决传统驱动系统能耗高、环境负荷重等问题,以成本低、易降解且吸湿性能优异的粘胶纤维为原料,开发了“旋转型”和“收缩型”2种利用环境水汽驱动的智能湿度响应纤维束。“旋转型”湿响应纤维束通过吸湿膨胀引发解捻,实现旋转驱动;“收缩型”湿响应纤维束则在湿度刺激下实现长度方向上的收缩。借助光学显微镜、X射线衍射仪、拉力试验机、水雾测试等对粘胶以及湿响应纤维束进行表征分析。结果表明:经热拉伸处理的粘胶纤维吸湿膨胀率提升64.47%绝对增幅,断裂应力提高12.53%。当纤维束捻度为18 捻/cm时,“旋转型”湿响应纤维束最大扭转行程可达1 075.5(°)/cm、最大扭转速率为65.1(°)/(cm·s);“收缩型”湿响应纤维束在捻度为18 捻/cm、节距为0.15 cm时,展现出最佳驱动性能,最大收缩率为76.7%,最大收缩速率为23.3%/s。此外,“收缩型”湿响应纤维束表现出极佳的湿度响应灵敏性,可在体温蒸发水滴产生的水雾驱动下实现62.22%的收缩。该研究为基于湿响应驱动的智能纺织器件及全纤维驱动器的设计提供了新思路与新策略。

关键词: 粘胶纤维, 热拉伸, 加捻, 智能纤维, 湿响应, 驱动性能

Abstract:

Objective To address the high energy consumption and environmental burden of traditional actuators, this study aims to develop sustainable, humidity-driven smart fibers based on viscose, a biodegradable material with excellent hygroscopicity. Two types of humidity-responsive fiber bundles were designed, which are a “rotatable” type that performs torsional actuation through moisture-induced untwisting, and a “contractile” type that exhibits axial contraction under humidity stimuli.

Method Viscose fibers were thermally stretched at 60 ℃ first to improve molecular orientation and mechanical strength. The "rotatable" humidity-responsive fiber bundles were fabricated by twisting three viscose fibers with varying twist levels (10-20 twists/cm) and folding them to form double-helix structures. The "contractile" humidity-responsive fiber bundles were prepared by helically winding the "rotatable" humidity-responsive fiber bundles onto steel rods and thermally setting them at 95 ℃. Morphological, structural, and mechanical properties were characterized using optical microscopy, X-ray diffraction (XRD), and tensile testing. Humidity-induced torsion and contraction behaviors were recorded under controlled water mist concentrations using optical and video analysis.

Results Research results demonstrated that thermal stretching significantly enhanced the hygroscopic expansion and mechanical performance of the viscose fibers. The swelling ratio of thermally stretched fibers increased by 64.47%, and their tensile strength improved by 12.5%. XRD results revealed a rise in molecular orientation factor of the thermally stretched fibers from 0.82 to 0.86, confirming enhanced structural order.For "rotatable" humidity-responsive fiber bundles, torsional performance strongly depended on the twist level. The optimal actuation was achieved at a twist of 18 twists/cm, producing a maximum rotation angle of 1 075.5(°)/cm and a maximum rotational speed of 65.1(°)/(cm·s) under a water mist flux of 0.11 g/s. These fibers also exhibited excellent reversibility, completing full forward and reverse rotations upon humidity cycling. The actuation mechanism was explained by a geometric model linking fiber swelling and untwisting dynamics. For "contractile" humidity-responsive fiber bundles, both twist and coil pitch significantly influenced contraction performance. The best contraction occurred at a twist of 18 twists/cm and a pitch of 0.15 cm, achieving a maximum contraction ratio of 76.7% and a contraction rate of 23.3 %/s. Increasing water vapor concentration accelerated actuation speed without affecting maximum deformation. Notably, these bundles demonstrated high humidity sensitivity. When stimulated by body-temperature vapor from evaporating water droplets, a contraction of 62.22% was witnessed within 82 s. These findings demonstrate that viscose-based fiber bundles can serve as efficient, reversible, and green actuators for low-power soft systems. A proof-of-concept "smart window" driven by the "rotatable" humidity-responsive fiber bundles illustrated their potential in adaptive, energy-free environmental control devices.

Conclusion This work developed two types of humidity-responsive viscose fiber bundles successfully with distinct actuation modes. Thermal stretching effectively improved molecular orientation and hygroscopic expansion, providing a structural foundation for enhanced actuation. The "rotatable" humidity-responsive fiber bundles exhibited superior torsional performance, while the "contractile" humidity-responsive fiber bundles achieved remarkable linear contraction and high sensitivity to ambient humidity. Structural parameters such as twist density and coil pitch were identified as key factors influencing actuation efficiency. The study provides a new design strategy for sustainable, humidity-driven soft actuators that convert environmental water vapor energy into mechanical motion without external power. Such fiber-based actuators hold great promise for applications in smart textiles, adaptive ventilation systems, and self-regulating wearable devices, offering a low-cost and eco-friendly alternative to conventional energy-consuming actuators.

Key words: viscose fiber, thermal stretching, twisting, smart fiber, humidity-responsive, driving performance

中图分类号:

TS102.6

李凯, 王雨萌, 张逸龙, 杨湙雯, 董浩珍, 吴晶. 湿响应纤维束的制备及其驱动性能[J]. 纺织学报, 2026, 47(02): 126-134.

LI Kai, WANG Yumeng, ZHANG Yilong, YANG Yiwen, DONG Haozhen, WU Jing. Preparation of humidity-responsive fiber bundles and their actuation performance[J]. Journal of Textile Research, 2026, 47(02): 126-134.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20251002301

http://www.fzxb.org.cn/CN/Y2026/V47/I02/126

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