Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (05): 186-194.doi: 10.13475/j.fzxb.20240801401

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Aromatic primary amination modification of mercerized wool and its room temperature diazo coupling staining

ZHU Daquan1, CUI Zhihua1(), GAO Pu2, ZHU Jie3, ZHANG Bin3, ZHU Yuewen3, CHEN Weiguo4   

  1. 1. College of Textile Science and Engineering(International Institute of Silk), Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
    2. Jiaxing Nanhu University, Jiaxing, Zhejiang 314000, China
    3. Zhejiang Zhongding Textile Co., Ltd., Jiaxing, Zhejiang 314511, China
    4. Zhejiang Sci-Tech University Tongxiang Research Institute, Jiaxing, Zhejiang 314500, China
  • Received:2024-08-09 Revised:2025-02-06 Online:2025-05-15 Published:2025-06-18
  • Contact: CUI Zhihua E-mail:zhhcui@zstu.edu.cn

RichHTML

6

PDF (PC)

30

Abstract:

Objective Aiming at many deficiencies in wool dyeing technology, such as the complex conventional dyeing process, high energy consumption, and harsh reaction conditions, a new type of mercerized wool reactive dyeing technology is developed. First, isatoic anhydride is adopted to perform aromatic primary amination modification on mercerized wool. Then, azo pigments are generated in situ on mercerized wool through diazotization and coupling reactions, achieving rapid reactive dyeing at room temperature. The in-situ synthesis and covalent fixation of dye molecules in the fiber matrix have been successfully realized.
Method In a DMF-water mixed system, isatoic anhydride was adopted to aminate mercerized wool, resulting in aromatic aminated wool. The modification rate of isatoic anhydride on mercerized wool was determined by the residual method. At room temperature, a mixed solution of hydrochloric acid (HCl) and sodium nitrite (NaNO2) was adopted to diazotize the aromatic aminated wool. Further studies on the storage stability of diazotized wool under wet and dry conditions were conducted. Under room temperature and weak alkaline conditions, diazotized wool underwent coupling reactions with different coupling components, achieving coupling coloration and producing coupled colored woolen fabrics.
Results Mercerized wool was modified with aromatic primary amination, diazotization and coupled coloring modifications to achieve coloration. Diazotized wool reacted with different coupling components to produce different colors. Isatioc anhydride was completely hydrolyzed to o-aminobenzoic acid and the ultraviolet-visible absorption spectra of the hydrolyzed mixture was measured and the wavelength of its maximum absorbance was 309 nm. Using the standard working curve for hydrolysis of different concentrations of isatioc anhydride, the maximum consumption of isatoic anhydride modification on 1 g mercerized wool was found to be 0.022 5 g, and the reaction of diazotized wool with γ acid required 0.074 4 mmol γ acid. The K/S values of dry diazotized wool were basically unchanged after storage for different periods of time, indicating that the storage stability of dry diazotized wool was high. Fourier transform attenuated total reflection infrared spectroscopy characterization showed characteristic Infrared Spectroscopy peaks at different stages. Aromatic primary aminated wool showed an aryl ring adjacent disubstitution peak at 751 cm-1 on the aryl ring, diazotized wool had a diazonium salt stretching vibration peak at 2 334 cm-1, while the sulfonate characteristic peaks of coupled chromogenic wool were at 1 167 and 1 036 cm-1. The color fastness to soap washing and color fastness to rubbing of the coupled colored fabrics were evaluated and the results showed that the color fastness to soap washing of the coupled colored fabrics reached level 4 and the color fastness to rubbing was level 3-4.
Conclusion The following conclusions can be drawn. 1) The acylation of isatioc anhydride can achieve a good aromatic amination modification on mercerized wool, with electron-rich groups such as amino, imino, hydroxyl, and mercapto as potential modification sites. The modification conditions of 40 ℃ and pH 8 are relatively mild, and under these conditions, the maximum modification reaction amount of isatoic anhydride on mercerized wool is 0.022 5 g. 2) Aromatic aminated wool can undergo a rapid diazotization reaction with nitrite at room temperature, and the resulting diazotized wool has excellent dry storage stability, with the K/S value remaining essentially stable within 10 d after coupled dyeing, which is favorable for long-term storage and application. 3) Diazotized wool can rapidly couple and color with coupling components of different structures under room temperature and weakly alkaline conditions, resulting in dyed mercerized wool with deep color and excellent color fastness performance. The depth value reaches 30, the color fastness to soap washing reaches level 4, and the color fastness to rubbing is above level 3. This is an energy-saving and efficient new reactive dyeing method for wool.

Key words: wool, isatoic anhydride, chemical modification of protein residue, diazo-coupling reaction, dyeing

CLC Number: 

  • TS131.8

Fig.1

K/S value curves of coupled colored wool before and after high-temperature color stripping with DMF. (a) Using γ acid as coupling component; (b) Using H acid as coupling component; (c) Using sulfonic pyrazolone as coupling component"

Fig.2

Modification reactions of mercerized wool by aromatic primary amination, diazotization and coupled coloring"

Fig.3

Color changes of mercerized wool fabrics after different treatments"

Fig.4

K/S value curves of mercerized wool before and after treatment"

Fig.5

Nitrosation reaction of tyrosine residues in mercerized wool"

Fig.6

Diazotization and decomposition mechanism of aliphatic amino groups in mercerized wool"

Fig.7

Absorbance of mixed products hydrolyzed with different concentrations of isatoic anhydride"

Tab.1

Relationship between dosage of isatoic anhydride and modification reaction rate"

靛红酸酐
用量/g		 吸光度
A		 残留量/
g		 修饰反应量/
(g·g-1羊毛)		 修饰
反应率/%
0.02 0.166 0.011 0 0.009 0 45.0
0.04 0.362 0.024 0 0.016 0 40.0
0.06 0.596 0.039 5 0.020 5 34.2
0.08 0.872 0.057 8 0.022 2 27.8
0.10 1.169 0.077 5 0.022 5 22.5

Fig.8

K/S value curves of mercerized wool and aromatic aminated wool colored by Ehrlich reagent"

Fig.9

Coloration mechanism of aromatic primary aminated wool by Ehrlich reagent"

Fig.10

Absorbance of γ acid solution before and after coupled coloring"

Fig.11

Stability of diazotized wool in dry and wet states"

Fig.12

Mechanism of diazo transformation of diazotized wool"

Tab.2

ESI mass spectral data of reaction of simulant with isatoic anhydride"

模拟物 模拟对应芳伯
胺化产物		 模拟产物理论
相对分子质量		 质荷比
A a 216.051 239.077、455.244
B b 256.082 279.138、535.313
C c 293.066 316.184
D d 165.079 188.006
E e 233.012 256.043、489.101

Fig.13

Amino acid residue mimics (a) and their corresponding aromatic primary amination products(b)"

Fig.14

Infrared spectra of chemically modified mercerized wool"

Fig.15

SEM images of mercerized wool (a) and its coupled colored wool (b)(×1 500)"

Tab.3

Color fastness of dyed wool fabrics"

偶合
组分		 最大
吸收
波长/nm		 剥色后
最大
K/S		 耐皂洗色牢度/级 耐摩擦色牢度/级
变色 沾色 湿
羊毛
γ酸 520 30.6 4~5 4~5 4 4 3~4
H酸 530 34.9 4~5 5 4~5 4~5 3~4
对磺酸
吡唑酮		 410 33.0 5 5 5 4~5 4~5
[1] MURPHY A R, JOHN P S, KAPLAN D L. Modification of silk fibroin using diazonium coupling chemistry and the effects on hMSC proliferation and differentiation[J]. Biomaterials, 2008, 29(19): 2829-2838.
doi: 10.1016/j.biomaterials.2008.03.039 pmid: 18417206
[2] 肖金秋, 修景海, 吴祖望. SN型活性染料在羊毛上的染色性能研究[J]. 纺织学报, 2003, 24(5):60-62.
XIAO Jinqiu, XIU Jinghai, WU Zuwang. A study of the dyeing property of SN reactive dyes on wool[J]. Journal of Textile Research, 2003, 24(5): 60-62.
[3] 赵涛. 染整工艺与原理[M]. 2版. 北京: 中国纺织出版社, 2020: 92-95.
ZHAO Tao. Dyeing and finishing process and principle[M]. 2nd ed. Bejing: China Textile & Apparel Press, 2020: 92-95.
[4] 车环禹, 刘千禧, 于晓庆, 等. 水解活性染料在羊毛织物上的应用[J]. 毛纺科技, 2023, 51(1):45-50.
CHE Huanyu, LIU Qianxi, YU Xiaoqing, et al. Application of hydrolyzed reactive dyes on wool dyeing[J]. Wool Textile Journal, 2023, 51(1): 45-50.
[5] HU Y, WANG W, YU D. Functional modification of wool fabric by thiol-epoxy click chemistry[J]. Fibers and Polymers, 2016, 17(1): 30-35.
[6] ZHANG X Y, SUN Y F, QIU T, et al. An eco-friendly and low-temperature dyeing for wool fibres using dihydroxyacetone induced Maillard reaction[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2023. DOI:10.1016/j.colsurfa.2023.132695.
[7] CHEN W G, WANG Z Q, CUI Z H, et al. Study on coloration of silk based on coupling reaction with a diazonium compound[J]. Fibers and Polymers, 2014, 15: 966-970.
[8] DEMIR A, ARIK B, OZDOGAN E, et al. The comparison of the effect of enzyme, peroxide, plasma and chitosan processes on wool fabrics and evaluation for antimicrobial activity[J]. Fibers and Polymers, 2010, 11(7): 989-995.
[9] BOOSTANI B, BIDOKI S M, FATTAHI S. Using an eco-friendly deep eutectic solvent for waterless anti-felting of wool fibers[J]. Journal of Cleaner Production, 2023. DOI:10.1016/j.jclepro.2022.135732.
[10] 陈丽萍, 陈维国, 崔志华, 等. 氯化改性羊毛的低温高效Mannich反应染色方法[J]. 毛纺科技, 2022, 50(3):30-35.
CHEN Liping, CHEN Weiguo, CUI Zhihua, et al. Low temperature reactive dyeing of chlorinated wool with acid dye based on Mannich reaction[J]. Wool Textile Journal, 2022, 50(3): 30-35.
[11] WADE R H, REEVES W A. Preparation and some properties of the anthranilate of cotton[J]. Textile Research Journal, 1964, 34(10): 836-839.
[12] HOOKER J M, ESSERS-KAHN A P, FRANCIS M B. Modification of aniline containing proteins using an oxidative coupling strategy[J]. Journal of the American Chemical Society, 2006, 428(49): 15558-15559.
[13] 唐培堃. 精细有机合成化学及工艺学[M]. 2版. 天津: 天津大学出版社, 2002:199-201.
TANG Peikun. Fine organic synthetic chemistry and technics[M]. 2nd ed. Tianjin: Tianjin University Press, 2002: 199-201.
[14] LI B, LI J Y, SHEN Y Q, et al. Development of environmentally friendly wool shrink-proof finishing technology based on L-cysteine/protease treatment solution system[J]. International Journal of Molecular Sciences, 2022. DOI:10.9930/ijms232113553.
[15] 李学崇, 陈维国, 崔志华, 等. 稳定性重氮色盐对蚕丝的低温偶合染色性能[J]. 丝绸, 2023, 60(11):10-17.
LI Xuechong, CHEN Weiguo, CUI Zhihua, et al. Low temperature coupling properties of stable diazoniumnium color salt on silk[J]. Journal of Silk, 2023, 60(11): 10-17.
[1] ZHU Menghui, GE Meitong, DONG Zhijia, CONG Honglian, MA Pibo. Structure and heat-moisture properties evaluation of double-sided wool/polyester weft-knitted fabrics [J]. Journal of Textile Research, 2025, 46(05): 179-185.
[2] ZHAO Qiangqiang, WANG Hanxing, ZHANG Fengxuan, HE Jinxin, ZHOU Jun, ZHOU Zhaochang, DONG Xia. Light fastness of dyed cotton fabrics modified with poly(hexamethylene biguanide) hydrochloride [J]. Journal of Textile Research, 2025, 46(04): 109-118.
[3] JIN Rushi, CHEN Wanming, LIU Guojin, LIU Chenghai, QI Dongming, ZHAI Shimin. Application progress in biochars in printing and dyeing wastewater treatment [J]. Journal of Textile Research, 2025, 46(04): 235-243.
[4] ZHU Wenshuo, XUE Yuan, SUN Xianqiang, XUE Jingli, JIN Guang. Full color gamut matching of wool blended yarn based on seven primary color fibers [J]. Journal of Textile Research, 2025, 46(04): 71-80.
[5] YAO Yiting, AO Limin, ZHANG Zhanwang, SU Youpeng. Testing method of pile face properties for felting knitted wool fabrics [J]. Journal of Textile Research, 2025, 46(03): 100-108.
[6] LI Huan, MENG Wenjun, ZHANG Jing, JIANG Zhe, WEI Yimin, ZHOU Man, WANG Qiang. Dyeing wool with indigo dye in deep eutectic solvent system [J]. Journal of Textile Research, 2025, 46(03): 123-130.
[7] YIN Lianbo, LI Jiawei, DUAN Huimin, SONG Lixiang, CHEN Yushuang, LI Xunxun, QI Dongming. Cyclic dyeing with wastewater from liquid dispersed dyeing process [J]. Journal of Textile Research, 2025, 46(03): 131-140.
[8] XIE Xiaokang, JIANG Hua, WANG Ye, SHI Lulu. Reaction mechanism between α-trifluoromethyl phenyl diazo ester dye and synthetic fiber [J]. Journal of Textile Research, 2025, 46(02): 145-152.
[9] GUO Qing, MAO Yangshun, REN Yajie, LIU Jimin, WANG Huaifang, ZHU Ping. Simultaneous in-situ dyeing and flame retardant functionalization of wool fabrics based on laccase catalysis [J]. Journal of Textile Research, 2025, 46(02): 161-169.
[10] SHI Jingjing, YANG Enlong. Effect of advance-feeding on structure and performance of cotton/wool segment colored yarns [J]. Journal of Textile Research, 2024, 45(12): 67-73.
[11] HAN Huayu, YANG Wenlong, WANG Fu, HU Liu, HU Yi. Preparation of benzo[a]phenoxazine based functional dyes and their application on modified polyester fabrics [J]. Journal of Textile Research, 2024, 45(10): 128-136.
[12] WANG Le, DUAN Zhixin, YAO Jinbo, LIU Jianyong, LU Jianjun. Eco-friendly mercerization of wool carpet using protease method based on substrate activation [J]. Journal of Textile Research, 2024, 45(09): 129-136.
[13] WU Tao, LI Jie, BAO Jinsong, WANG Xinhou, CUI Peng. Modeling of carbon footprints for producing wool blended fabrics and model applications [J]. Journal of Textile Research, 2024, 45(09): 97-105.
[14] LÜ Zihao, XU Huihui, YUAN Xiaohong, WANG Qingqing, WEI Qufu. Preparation and properties of photodynamic antimicrobial spunlaced cotton made by integrated dyeing and finishing [J]. Journal of Textile Research, 2024, 45(08): 26-34.
[15] WANG Yuxi, TANG Chunxia, ZHANG Liping, FU Shaohai. Preparation of carbon black nanoparticles by Steglich esterification and its ethylene glycol dispersity [J]. Journal of Textile Research, 2024, 45(07): 104-111.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd