模拟绿叶颜色变化的温致变色织物制备及其性能

doi:10.13475/j.fzxb.20250301501

摘要/Abstract

摘要： 为提升视觉变色伪装材料的温度响应灵敏度,首先合成了一种新型荧烷变色染料,并与相变材料共混制备了高灵敏度温致变色复配物;其次,利用溶剂挥发法制备了快速温度响应性的变色微胶囊,并将其与普通分散染料进行配色,制备出绿色树叶(春季)-黄绿色树叶(秋季)可逆温致变色色浆;最后,采用丝网印花技术将其整理到涤纶/棉织物表面,制备了仿绿叶颜色变化的温致变色织物。表征分析了染料分子结构、复配物变色性能、温致变色微胶囊的表观形貌、粒径尺寸、热稳定性以及熔融-结晶性能;探究了仿绿叶颜色变化的温致变色织物的微观形貌、驱动温度、颜色对比度和响应性。结果表明:温致变色微胶囊的平均粒径为12 μm,耐热稳定性优良;温致变色织物变色区间为35~37 ℃,响应速率快,具有良好的循环耐久性(>100次),耐皂洗色牢度达3~4级,耐干、湿摩擦色牢度均达到4级,且成功模拟出树叶颜色自然随季节变化。

关键词: 荧烷染料, 微胶囊, 温致变色织物, 仿绿叶颜色, 仿生织物, 智能纺织品

Abstract:

Objective Conventional camouflage is achieved by the use of camouflage net or camouflage clothing with static color patterns. Although it can provide a certain camouflage effect for specific environment, it is difficult for it to adapt to complex and changeable environment. In order to overcome the disadvantage that static camouflage is easy to be identified in a changeable background, a study on adaptive discoloration camouflage fabrics was proposed, aiming to respond quickly to external changes and intelligently adjust its own characteristics to achieve a high degree of integration with the background.

Method In order to solve this problem, a new type of fluorane dye was designed and synthesized, and a highly sensitive two-component thermochromic system was prepared by physical blending of the fluorane dye and a phase change material. Microcapsule packaging technology was adopted to maintain the thermoal stability at high temperature, so as to provide the basis for realization of fast response discoloration camouflage. The thermochromic paste which can be used in natural environment camouflage was prepared by compounding discoloration microcapsules with ordinary disperse dyes in different proportions, and was screen printed on fabrics to produce thermochromic intelligent textiles.

Results The molecular structure of the dye was characterized and analyzed by ¹H NMR and high resolution mass spectrometry, and the apparent morphology and particle size of thermochromic microcapsules were observed by polarizing microscope and scanning electron microscope. The results showed that the sample was regular spherical, the surface was relatively smooth, and the average particle size was about 12 μm. The thermal stability and melting-crystallization properties of thermochromic microcapsules were also investigated. The thermogravimetric characteristic peaks of thermochromic microcapsules appeared at 220-340 ℃ and 360-500 ℃, corresponding to the thermal decomposition of core material composite and shell material polymethyl methacrylate (PMMA), respectively. The results showed that PMMA successfully encapsulated the thermochromic compound in the microcapsule and had a certain protective effect.

The micromorphology of ordinary polyester/cotton fabric and thermochromic cotton fabric was characterized by scanning electron microscope. The surface of the original polyester/cotton fabric was smooth, while the surface of the polyester/cotton fabric after layer printing was rough and the surface morphology changed obviously. A large number of microcapsules was attached to the surface of the fabric. In addition, the color performance of the fabric was explored. With the increase of the amount of thermochromic paste in the compound color paste, the fabric gradually turned yellow, the K/S value gradually decreased. The fabric color demonstrated an obvious lighter trend, which was kept stable when it reached a certain proportion. Secondly, owing to the increase of thermochromic paste, the response of the fabric to temperature change became more sensitive and more obviously. The discoloration cycle of the fabric was also tested, and the fabric showed excellent reversible discoloration performance in 100 cycles of rising and falling temperature. The camouflage fabric designed by screen printing was compared with the vegetation in nature, showing a good camouflage effect.

Conclusion A highly sensitive fluorane dye was designed and synthesized. The compound prepared by mixing with phase change material (tetradecyl alcohol) achieved color transformation at 2.5 ℃, and thermochromic microcapsules were prepared by solvent volatilization method. Using disperse dyes and thermochromic microcapsules as colorants, different proportions of green-yellow thermochromic pastes were prepared and finished on polyester/cotton fabrics by screen printing. With the increase of the ratio of thermochromic microcapsule pastes to disperse dye pastes, the color difference of the fabric before and after discoloration gradually increased. The discoloration range of the fabric is 35-37 ℃, still maintaining a narrow discoloration temperature range. After 100 discoloration cycles, the performance of the fabric kept consustancy, and the natural leaf color was successfully simulated. The material mainly realizes the change of its own color by adjusting the temperature, and has a color similar to that of different vegetation (such as green, yellow), which breaks the limitation of fixed color in traditional anti-reconnaissance methods and improves its applicability in different environments.

Key words: fluorane dye, microcapsule, thermochromic fabric, imitation green leaf color, biomimetic fabric, smart textile

中图分类号:

TS194.2

赵捷清, 王瑧, 秦孝天, 王成成, 张丽平. 模拟绿叶颜色变化的温致变色织物制备及其性能[J]. 纺织学报, 2025, 46(09): 19-26.

ZHAO Jieqing, WANG Zhen, QIN Xiaotian, WANG Chengcheng, ZHANG Liping. Preparation and properties of thermochromic camouflage fabrics simulating color changing of leaves[J]. Journal of Textile Research, 2025, 46(09): 19-26.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250301501

http://www.fzxb.org.cn/CN/Y2025/V46/I09/19

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