纺织学报 ›› 2024, Vol. 45 ›› Issue (04): 8-14.doi: 10.13475/j.fzxb.20230906101

• 纺织科技新见解学术沙龙专栏:绿色功能与智能纺织品 • 上一篇    下一篇

柔韧隔热纤维素基气凝胶制备与性能

时吉磊1,2, 唐春霞1,2, 付少海1,2, 张丽平1,2()   

  1. 1.江苏省纺织品数字喷墨印花工程技术研究中心, 江苏 无锡 214122
    2.生态纺织教育部重点实验室(江南大学), 江苏 无锡 214122
  • 收稿日期:2023-09-28 修回日期:2023-12-16 出版日期:2024-04-15 发布日期:2024-05-13
  • 通讯作者: 张丽平(1985—),女,教授,博士。主要研究方向为功能纤维材料。E-mail:zhangliping0328@163.com。
  • 作者简介:时吉磊(1998—),男,硕士生。主要研究方向为纤维素气凝胶材料。
  • 基金资助:
    国家自然科学基金项目(52203117)

Preparation and properties of flexible thermal insulating cellulose aerogel

SHI Jilei1,2, TANG Chunxia1,2, FU Shaohai1,2, ZHANG Liping1,2()   

  1. 1. Jiangsu Engineering Research Center for Digital Textile Inkjet Printing, Wuxi, Jiangsu 214122, China
    2. Key Laboratory of Eco-Textiles (Jiangnan University), Ministry of Education, Wuxi, Jiangsu 214122, China
  • Received:2023-09-28 Revised:2023-12-16 Published:2024-04-15 Online:2024-05-13

摘要:

纤维素基气凝胶骨架强度差、脆性强,受外力压缩后隔热性能有所下降,不利于实际应用。针对这一问题,通过引入双硅烷偶联剂1,2-二(三甲氧基硅基)乙烷(BTMSE)与纤维素纳米纤维(CNF)形成共价交联网络,借助冷冻干燥技术构筑微米级多孔柔韧的隔热纤维素气凝胶,分析了气凝胶的微观形貌、化学结构,研究了BTMSE加入量与气凝胶力学性能、导热系数之间的关系,探究了力学性能对隔热效果的影响。结果表明:气凝胶呈现典型的蜂窝状孔洞结构,具有98.15%的高孔隙率;共价交联作用使气凝胶能够承受自身500倍的重量而恢复原状,在应变为50%的情况下循环压缩200次后,应变损失仅为9.7%左右;由于低密度、交联网络和多孔结构的存在,气凝胶导热系数低至31.90 mW/(m·K);在60%压缩应变后导热系数增加量不超过1%。该改性气凝胶有望用于恶劣环境下的隔热保暖。

关键词: 硅烷偶联剂, 纤维素气凝胶, 导热系数, 力学强度, 压缩回弹性

Abstract:

Objective New generation of cellulose aerogel has become a research hotspot in recent years because of its wide source of raw materials, good biocompatibility, low density and low thermal conductivity, and has been widely used in civil, military, aerospace and other fields. However, cellulose-based aerogel has some disadvantages such as poor skeleton strength, brittleness, which seriously limit its development and application in the field of thermal insulation. Therefore, a cellulose-based aerogel with high strength and high compressive resilience was studied by introducing silane coupling agent to covalent crosslinking with cellulose.

Method A cellular-network aerogels with cellular-network structure was constructed by freeze-drying by using in situ covalent cross-linking of silane coupling agent 1,2-di (trimethoxysilyl) ethane (BTMSE) and cellulose nanofibers (CNF) to form strong interfacial interaction. By adjusting the content of silane coupling agent, the thermal insulation aerogel with high strength and good compressive resilience was obtained. The relationship between the amount of BTMSE added and the mechanical properties and thermal conductivity of aerogel was studied. The microstructure, chemical structure and thermal insulation properties of aerogel were analyzed.

Results Chemical bonding was considered first in studying the forming mechanism of CNF/BTMSE aerogel. Under acidic conditions, BTMSE was hydrolyzed to form reactive silanol, and covalently was polycopated with the hydroxyl group on cellulose to form Si—O—C bond, which acted as the cross-linking point between CNF. Chemical bonding enabled cross-linking and entangling among CNF to form network structure. The second was the investigation of the temperature-induced effect. In the process of low temperature freezing, water continuously formed ice crystals, and layered ice crystals gradually grew and squeezed nanofibers, so that the nanofibers gathered among the ice crystals, and the fibers were tightly stacked and intertwined to form a three-dimensional network structure. Finally, after freeze drying, the ice crystals were directly sublimated to form a honeycomb cell structure. Due to chemical crosslinking with siloxane, the CNF/BTMSE aerogel demonstrated a more regular pore structure. After BTMSE modification, the pore size of cellulose aerogel showed a decreasing trend, proving the formation of crosslinking network. Infrared spectroscopy and XPS spectroscopy confirmed the successful introduction of silane coupling agents in 3# aerogel (the mass ratio of CNF and BTMSE is 2∶3) and the covalent force with the hydroxyl group on cellulose. Under 60% compression strain, the strength of CNF aerogel was 13.1 kPa, and the strength of 3# aerogel was 34.8 kPa, and the deformation recovery rate was 97% after the external force was removed, indicating good resilience. In addition to higher compressive stress and resilience, the aerogel modified by silane coupling agent also showed excellent cyclic compressibility resistance. After 200 cycles of cyclic compression, the aerogel still maintained 90.4% of its initial height, and the strain loss was less than 10%. The regular pore structure formed by silane modification and the mesopole formed by crosslinked network make the aerogel demonstrated low thermal conductivity. The thermal conductivity of 3# aerogel was 31.90 mW/(m·K), representing good thermal insulation stability, and the thermal conductivity increase was kept below 1% after 60% compression strain, which is well below the 20% increase in CNF aerogels. The 3# aerogel produced a temperature difference of about 70 ℃ on a 130 ℃ platform, showing good thermal insulation performance.

Conclusion High strength and superelastic cellulose based aerogel materials were prepared by in situ covalent crosslinking and freeze-induced assembly. It improves the problems that the structure of pure cellulose aerogel with poor resilience is easy to collapse and the thermal insulation performance is decreased in real environment. It has great application value in flexible thermal insulation field.

Key words: silane coupling agent, cellulose aerogel, thermal conductivity, mechanical strength, compressive resilience

中图分类号: 

  • TS101.8

图1

CNF/BTMSE复合气凝胶的制备示意图"

图2

气凝胶的扫描电镜照片"

图3

气凝胶的孔径分布"

图4

CNF和3#气凝胶的红外光谱图"

图5

CNF和3#气凝胶的XPS谱图"

表1

CNF气凝胶和CNF/BTMSE复合气凝胶的物理性能"

样品
编号
密度/
(mg·cm-3)
孔隙率/
%
平均孔
径/μm
导热系数/
(mW·m-1·K-1)
CNF 10.76 98.85 44.2 34.80
1# 12.36 98.76 40.5 33.94
2# 14.43 98.54 27.6 32.99
3# 20.12 98.15 19.0 31.90
4# 25.15 96.75 18.1 33.10

图6

3#气凝胶的红外热成像照片"

图7

气凝胶在0%和60%应变压缩前后导热系数"

图8

与已报道的纤维素基气凝胶材料的隔热和力学性能比较"

图9

气凝胶在60%应变下的应力-应变曲线"

图10

3#气凝胶的力学稳定性"

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