智能发热服装用柔性碳纳米管电加热元件的制备及应用

doi:10.13475/j.fzxb.20241204101

摘要/Abstract

摘要：

针对传统电加热保暖服装柔韧性、舒适性差等问题,需开发一种用于服装的可加热、轻柔、耐水洗的电加热元件。碳纳米管因轻质、高导电、高红外发射率等特点在柔性电热材料中的应用受到广泛关注。为此,通过真空抽滤法制备湿法碳纳米管导电薄膜,采用涂层法制备了碳纳米管复合皮芯导电纤维,并制成织物,进而将膜和织物分别作为加热元件,将其发热和可穿戴性能与传统的电阻丝加热元件和化学气相沉积法制备的碳纳米管膜对比。结果表明:同功率下碳纳米管导电薄膜升温速率快,高达1.96 ℃/s(电阻丝最低,为0.53 ℃/s),柔性好,比电阻丝高350%;碳纳米管导电织物升温温度最高,达121.54 ℃(电阻丝最低,为56.87 ℃),柔性比电阻丝高150%~335%,相比于其它电加热元件具有透气性(透气率为463 mm/s);碳纳米管系列加热元件均耐水洗,水洗2次后质量变化最大为7.1%,电阻变化最大为3.8%;在发热服装的应用中,碳纳米管导电薄膜和导电织物因其优异功能,可满足智能发热服装的多元化市场要求。

关键词: 碳纳米管, 导电薄膜, 导电织物, 电加热元件, 智能发热服装

Abstract:

Objective In order to meet the demand for warmth and comfort of warm clothing in cold environment, intelligent warm clothing was developed. Carbon nanotube (CNT) is a new type of conductive material with high thermal conductivity, high strength and high electrical conductivity, and its excellent performance makes it widely applicable to the preparation of flexible heat-generating electronic devices. In this research, two types of heating elements are made of CNT materials, including CNT conductive film heating element and CNT conductive fabric heating element. The heating module is the core of heating clothing, aiming to meet the needs of wearing and heating.
Method CNT were dispersed by grinding and then mixed with waterborne polyurethane (WPU) to obtain CNT conductive slurry. CNT conductive films were prepared from the CNT slurry by vacuum filtration. CNT conductive fibers were prepared by coating the CNT slurry on the surface of polyester fibers using sizing and weaving the CNT conductive fibers into fabrics. The film and fabric were prepared, respectively, as simple heating elements, and compared with conventional resistance wire heating elements and CVD-CNT films prepared by CVD method to analyze its heating performance and wearability such as washability, permeability, flexibility and perspective.
Results In the heating test (with the power of the four electric heating elements set to 31 W by adjusting the heating area and voltage), the heating rate of CNT conductive film was found to be the highest, up to 1.96 ℃/s (the resistance wire was the lowest, 0.53 ℃/s). The heating temperature of CNT conductive fabric was the highest, up to 121.54 ℃ (the lowest temperature of resistance wire was 56.87 ℃). It showed that the thermal image of the resistance wire during heating was a curve, while the images of the other three of thermal images were two-dimensional planes. The washability test showed, that the heating elements made of CNT conductive film, CVD-CNT film and CNT conductive fabric were washable. After two washing cycles, the mass of CVD-CNT film was reduced the most, by 7.1%, and the resistance was increased the most, by 3.8%, while the resistance wire heating elements were not washable. The air permeability test showed that CNT fabric has air permeability of 463 mm/s, and other heating elements had no air permeability. The flexibility test showed that the flexibility of CNT conductive film, CVD-CNT film and CNT fabric (the test direction is radial) was almost the same, which was above 300% higher than that of resistance wire and above 60% higher than that of CNT fabric (the test direction is weft). Finally, the moisture permeability of four electric heating elements was tested. The results showed that the moisture permeability of CNT conductive film was 2 980 g/(m²·24 h), that of CNT-CVD film was 2 880 g/(m²·24 h) and that of CNT conductive fabric was 3 970 g/(m²·24 h). Obviously, CNT conductive fabric has good moisture permeability. Because the effective working area of resistance wire heating elements was a curve, the moisture permeability could not be tested.
Conclusion The successfully prepared CNT conductive films and CNT conductive fabrics can be assembled into electric heating elements and tested for heating performance. The results indicate that CNT conductive films not only generate heat quickly, but also exhibit excellent flexibility. CNT fabric has a high heating temperature, good permeability and certain flexibility. Introducing CNT into the heating module not only solves the problem of missing heating elements in intelligent heating clothing, but also expands the market application of CNT, proving the feasibility of CNT as a heating element and providing strong reference for the design of subsequent CNT heating systems.

Key words: carbon nanotube, conductive film, conductive fabric, electric heating fabric, intelligent heating clothing

中图分类号:

TS941

孙晚红, 张鹏飞, 陈勇, 张林, 潘跃山, 宋飞虎, 刘恩星, 王玉萍. 智能发热服装用柔性碳纳米管电加热元件的制备及应用[J]. 纺织学报, 2025, 46(05): 17-22.

SUN Wanhong, ZHANG Pengfei, CHEN Yong, ZHANG Lin, PAN Yueshan, SONG Feihu, LIU Enxing, WANG Yuping. Preparation and application of flexible carbon nanotube electric heating element for intelligent heating clothing[J]. Journal of Textile Research, 2025, 46(05): 17-22.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20241204101

http://www.fzxb.org.cn/CN/Y2025/V46/I05/17

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参考文献 9

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材料种类	最高温度/ ℃	最高温度的90%/℃	升温至最高温度90%的时间/s	升温速率/ (℃·s^-1)
CNT导电薄膜	117.84	106.06	54.0	1.96
CNT导电织物	121.54	109.39	77.9	1.40
电阻丝	56.87	51.18	97.0	0.53
CNT-CVD膜	81.75	73.58	56.9	1.29

材料种类	温度平均值/℃	温度方差
CNT导电薄膜	114.32	2.71
CNT导电织物	115.88	4.66
电阻丝	55.68	8.98
CNT-CVD膜	81.16	3.64

材料种类	水洗前后质量/g
材料种类	水洗前	水洗1次	水洗2次
CNT导电薄膜	0.017	0.017	0.016
CNT导电织物	0.036	0.034	0.034
CNT-CVD膜	0.014	0.013	0.013

材料种类	水洗前后电阻/Ω
材料种类	水洗前	水洗1次	水洗2次
CNT导电薄膜	6.64	6.81	6.88
CNT导电织物	4.05	4.11	4.12
CNT-CVD膜	41.69	40.50	40.11