Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (06): 113-119.doi: 10.13475/j.fzxb.20230506001

• Dyeing and Finshing Engineering • Previous Articles     Next Articles

Preparation and application of durable aqueous organic-inorganic hybrid fluorine-free water-repellant finishing agents

MA Yiping1,2, FAN Wuhou1,2,3(), HU Xiao1,4, WANG Bin1,2, LI Linhua1,2, LIANG Juan1,2, WU Jinchuan1,4, LIAO Zhengke1,3,4   

  1. 1. Sichuan Textile Scientific Research Institute Co., Ltd., Chengdu, Sichuan 610083, China
    2. High-tech Organic Fibers Key Laboratory of Sichuan Province, Chengdu, Sichuan 610083, China
    3. Sichuan & Zhejiang Industrial Technology Research Institute of Printing and Dyeing, Chengdu, Sichuan 610083, China
    4. Sichuan Yixin Technology Co., Ltd., Chengdu, Sichuan 610083, China
  • Received:2023-05-23 Revised:2024-03-04 Online:2024-06-15 Published:2024-06-15

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Abstract:

Objective Fabrics with water-repellent finishing have been extensively favored by consumers as one of the most widely used functional fabrics, and hydrophobic coatings and their applications prospects attract interests from both the academic and industrial comunities. However, their application is hindered by some major bottlenecks, especially the poor durability. Therefore, a method for preparing hydrophobic coatings with excellent mechanical stability is urgently necessary.

Method To tackle the poor durability of water-repellent finishing fabrics, this study innovatively introduced low surface energy polysiloxane segments and long carbon chain hexadecyl at the same time. A novel durable water-based hybrid fluorine-free water-repellant finishing agents (NSW) were prepared by amino modification of silica sol emulsion to enhance the interfacial interaction between the organic and inorganic components. This modification corresponded to the long-chain alkyl silane modified sol emulsion and polysiloxane modified waterborne polyurethane emulsion respectively. The specific methods used were described below. A polysiloxane modified polyurethane prepolymer (SiWPU) was synthesized through the polyaddition reaction of polydimethylsiloxane (PDMS), polyethylene glycol (PEG), dimethylol propionic acid (DMPA) and isophorone diisocyanate (IPDI). A method of the long-chain alkyl silane and amino modified sol emulsion (Si-NPs) was provided through the hydrolysis polycondensation reaction of hexadecyl trimethoxysilane (HDTMS), silane coupling agent (KH-550) and tetraethyl silicate (TEOS). Si-NPs were added drop by drop in the emulsification process of Si-WPU, silica nanoparticles were adhered to the polyurethane chain segment taking advantage of the difference in the rate of isocyanate group react with amino and hydroxyl group, and isocyanate group exhibits a higher rate of reaction with amino compared with hydroxyl group.

Results The chemical composition of Si-NPs and NSW were investigated using Fourier transform infrared spectroscopy. The most stable emulsion was achieved when KH-550 mass fraction was 1.5% (Si-NPs-1.5 and NSW-1.5), and the stability analysis of Si-NPs and NSW-1.5 were demonstrated using particle size tester and Zeta potential analyzer. In addition, the research also focused on the hydrophobic effects of the amount of aminosilane coupling agent in the silica sol. Baking temperature on the property of finished polyester/cotton fabric was also discussed in detail, and the hydrophobic performance and the wash resistance on the surface of finished polyester/cotton fabric were also investigated. It was found that when the mass ratio of KH-550 was 1.5% and the baking temperature remained at 160 ℃, NSW formed a complete water-repellent membrane. Under the conditions of these application environment on the surface of treated fabric with water contact angle (WCA) of 131.8°, the WCA of the treated fabric dropped by only 2.8°after 20 rubbing cycles and exhibited good washability. The surface morphology of the treated polyester/cotton fabric before and after washing was observed in order to study the water wash resistance on the surface of finished polyester/cotton fabric more intuitively, and the results of SEM images showed that micro-nano rough structures existed on the surface of finished polyester/cotton fabric. Additionally, the repellent effect of the treated fabric on different liquids was also studied to demonstrate the above viewpoint.

Conclusion It is confirmed through the research that when the mass ratio of KH-550 is 1.5% and the baking temperature remains at 160 ℃, the surface of the finished fabric exhibits the best water resistance performance. In view of the poor durability of finishing agents, a method for preparing fully aqueous and organic-inorganic hybrid fluorine-free water-repellant finishing agents was identified, which is to combine the long-chain alkyl silane modified sol emulsion and polysiloxane modified waterborne polyurethane emulsion for the stable preparation of waterproofing agents.

Key words: fluorine-free water-repellant finishing agent, water-repellant finishing, organic-inorganic hybrid, functional textile

CLC Number: 

  • TS190.8

Tab.1

Particle size and Zeta potential of Si-NPs and NSW"

样品名称 粒径/nm Zeta电位/mV
Si-NPs-0 97.3 -39.3
NSW-0 187.4 -38.7
Si-NPs-0.5 111.3 -38.9
NSW-0.5 223.4 -36.4
Si-NPs-1.0 119.8 -35.0
NSW-1.0 246.7 -32.8
Si-NPs-1.5 139.7 -32.7
NSW-1.5 390.2 -31.3
Si-NPs-2.0 209.3 -26.4
NSW-2.0

Fig.1

Infrared spectra of NSW and IPDI"

Fig.2

Infrared spectra of KH-550 and Si-NPs-1.5 emulsion"

Fig.3

Influence of mass ratio of KH-550 on water contact angles of treated fabrics"

Fig.4

Influence of mass ratio of KH-550 on washability of treated fabrics"

Fig.5

Influence of mass ratio of drying temperature on water contact angles of treated fabrics"

Fig.6

Influence of drying temperature on washability of treated fabrics"

Fig.7

SEM images of untreated polyester/cotton fabric(a), treated fabric(b) and treated fabric after 20 washing cycles(c) (×2 000)"

Fig.8

Photos of contact angles and different liquids on surface of treated fabric and treated fabric after 20 washing cycles"

[1] CHU S, LETCHER R J. In vitro metabolic formation of perfluoroalkyl sulfonamides from copolymer surfactants of pre- and post-2002 scotchgard fabric protector pro-ducts[J]. Environmental Science & Technology, 2014, 3(27):184-191.
[2] LIU J, JIA Y, JIANG Q, et al. Highly conductive hydrogel polymer fibers toward promising wearable thermoelectric energy harvesting[J]. Journal of Materials Chemistry A, 2018, 10(50): 44033-44040.
[3] HU X, CHEN G, WANG X, et al. Tuning thermoelectric performance by nanostructure evolution of a conducting polymer[J]. Journal of Materials Chemistry A, 2015, 3(42):20896-20902.
[4] XU Q B, WANG L J, FU F Y, et al. Fabrication of fluorine-free superhydrophobic cotton fabric using fumed silica and diblock copolymer via mist modification[J]. Progress in Organic Coatings, 2020, 11 (148):84-89.
[5] 尚轲, 任文君, 徐天祺, 等. 基于有机硅改性聚氨酯/二氧化硅的超疏水棉织物制备及其性能分析[J]. 浙江理工大学学报, 2024, 51(1):82-90.
SHANG Ke, REN Wenjun, XU Tianqi, et al. Preparation and performance analysis of superhydrophobic cotton fabrics based on silicone-modified on silicone-modified polyurethene/silica[J]. Journal of Zhejiang Sci-Tech University, 2024, 51(1):82-90.
[6] 马逸平, 樊武厚, 吴晋川, 等. 水性耐久杂化型无氟织物防水剂的制备及应用[J]. 纺织学报, 2022, 43(2):183-188.
MA Yiping, FAN Wuhou, WU Jinchuan, et al. Preparation and application of fully aqueous organic-inorganic hybrid fluorine-free water repellant finishing agents[J]. Journal of Textile Research, 2022, 43(2):183-188.
[7] 王海峰, 武迪, 张小玲, 等. 有机硅嵌段水性聚氨酯整理剂的合成和应用[J]. 印染, 2017, 16 (3):37-40.
WANG Haifeng, WU Di, ZHANG Xiaoling, et al. Synthesis and application of organosilicon block waterborne polyurethane finishing agent[J]. China Dyeing & Finishing, 2017, 16(3):37-40.
[8] YE H, WANG J, LIANG F, et al. Simple spray deposition of a water-based superhydrophobic coating with high stability for flexible applications[J]. Journal of Materials Chemistry A, 2017, 5(20): 9882-9890.
[9] WU Q, HU J. A novel design for wearable thermoelectric generator based on 3D fabric struc-ture[J]. Smart Materials and Structures, 2017, 26(4): 61-65.
[10] GUO B, FENG X J, ZHU P H, et al. Simple one-pot approach toward robust and boiling-water resistant superhydrophobic cotton fabric and the application in oil/water separation[J]. Journal of Materials Chemistry A, 2017, 5(41): 21866-21874.
[11] YANG C A, TAN Q, ZHONG G Q, et al. Structure-property relationship of a series of novel mesogen-jacketed liquid-crystalline polymers containing semirigid side chain with different numbers of alkoxy terminal groups[J]. Polymer, 2010, 51 (2):422-429.
[12] KAZEM D S, SHAHIN T, AKBAR H. Facile route to synthesis of functionalised poly(methylalkoxy) siloxane under mild and aerobic conditions in the presence of platinum catalysts[J]. Journal of Organometallic Chemistry, 2009, 694(25):4107-4115.
[13] BAE Y M, KIM H S, LEE H, et al. Fabrication of hierarchical structures on a polymer surface to mimic natural superhydrophobic surfaces[J]. Advanced Materials, 2007, 19(17): 2330-2335.
[14] YANG C A, TAN Q, ZHONGG Q, et al. Structure-property relationship of a series of novel mesogen-jacketed liquid-crystalline polymers containing semirigid side chain with different numbers of alkoxy terminal groups[J]. Polymer, 2010, 51 (2):422-429.
[15] REN J J, GUO F, HU F, et al. A simple way to an ultra-robust superhydrophobic fabric with mechanical stability, UV durability, and UV shielding property[J]. Journal of Colloid and Interface Science, 2018, 52(2): 57-62.
[16] ZHU M, XIAO B F, SHEN Z, et al. Facile fabrication of a superhydrophobic fabric with mechanical stability and easy-repairability[J]. Journal of Colloid and Interface Science, 2012, 380 (1): 182-186.
doi: 10.1016/j.jcis.2012.04.063 pmid: 22652590
[17] 陈迪, 黄杉, 杨园园, 等. 超浸润性γ-氨丙基三乙氧基硅烷-TiO2包覆织物的制备及其水净化性能[J]. 复合材料学报, 2022, 39(10): 4620-4630.
CHEN Di, HUANG Shan, YANG Yuanyuan, et al. Preparation of superwetting γ-amino-propyltriethoxysilane-TiO2 coated fabric and its water purification performances[J]. Acta Materiae Compositae Sinica, 2022, 39(10): 4620-4630.
[18] WANG D, SHAN F, LI G, et al. Definition of superhydrophobic states[J]. Advanced Materials, 2007, 19(21): 3423-3424.
[19] PAINTER J. Waterproof, breathable fabric laminates: a prospective from film to market place[J]. Journal of Coated Fabrics, 1996, 26 (10): 107-130.
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