Journal of Textile Research ›› 2026, Vol. 47 ›› Issue (02): 205-213.doi: 10.13475/j.fzxb.20250701101

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Synthesis and application of dyeing accelerant for reactive dyes

BAI Gang1,2, SUN Li3, DAI Shujiao1,4, SHEN Xiuyu1,2, LIU Yanchun1,2()   

  1. 1 School of Textile Science and Engineering, Shaoxing University, Shaoxing, Zhejiang 312000, China
    2 Key Laboratory of Clean Dyeing and Finishing Technology of Zhejiang Province, Shaoxing University, Shaoxing, Zhejiang 312000, China
    3 Ningbo Key Laboratory of Intelligent Manufacturing of Textiles and Garments, Zhejiang Fashion Institute of Technology, Ningbo, Zhejiang 315200, China
    4 Shaoxing Tujin Textile Co., Ltd., Shaoxing, Zhejiang 312000, China
  • Received:2025-07-03 Revised:2025-11-24 Online:2026-02-15 Published:2026-04-24
  • Contact: LIU Yanchun E-mail:864304478@qq.com

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Abstract:

Objective In the process of dyeing with reactive dyes, there are problems such as easy hydrolysis of reactive groups, low fixation and dye utilization rates, and high consumption of inorganic salts. Dyeing accelerants provide an effective way to solve these problems, as they can act as bridging groups to achieve covalent bonding between hydrolyzed dyes and fibers. A double active group dyeing accelerant with quaternary ammonium cationic and epoxy groups was designed and synthesized in this article. The epoxy group in its molecular structure can undergo bonding reactions with fibers, and the quaternary ammonium salt cationic groups can form ionic bonds with hydrolyzed dyes and unfixed dyes.

Method Trimethylallyl ammonium chloride (TMAAC) and allyl glycidyl ether (AGE) were used as reaction monomers to synthesize a double active group dyeing accelerant with epoxy and quaternary ammonium salt structure through free radical polymerization reaction. The synthesis process was optimized, and the molecular structure and thermal properties of the synthesized products were characterized. Dyeing accelerant was applied to cotton fabric dyeing, using Reactive Red 3BFN, Reactive Yellow HER, and Reactive Blue RGN as the dyes. The fixation rate, apparent color yield, and color fastness were tested.

Results The conversion rate of polymerization reaction increased with the increase of monomer AGE and TMAAC mass ratio. Initiator can accelerate the generation process of free radicals, but a large amount of free radicals were triggered when the dosage of initiator is too high, leading to collisions and quenching between free radicals, which would reduce the efficiency of the polymerization reaction. The conversion rate of polymerization reaction showed an increase with the increase of reaction temperature and reaction time, but excessive polymerization temperature would lead to chain cracking and side reactions. The research result analysis revealed 80 ℃ and 6 h as the optimal reaction temperature and reaction time. Infrared spectroscopy testing showed that the allyl double bonds in TMAAC and AGE disappeared. Thermogravimetric analysis tests showed that the dyeing accelerant has good thermal stability. The starting temperature for thermal decomposition was 165.80 ℃. The maximum weight loss rate temperature was 407.33 ℃. The apparent viscosity of the dyeing promoter decreases with increasing shear rate, which is consistent with the characteristics of pseudoplastic fluids. In the frequency range of 0.1-202 rad/s, the storage modulus G' is lerger than loss modulus G", the loss coefficient tanδ is lerger than 1, the elastic effect was dominant. When the angular frequency is greater than 202 rad/s, G'<G", tanδ>1, the viscous effect was dominant.

Conclusion To solve the problems of low fixation rate and high consumption of inorganic salt in reactive dyeing, a dyeing accelerant with double active group was synthesized through free radical polymerization reaction. The optimized process condition for synthesizing dyeing accelerant was that the dosage ratio of monomer AGE and TMAAC was 1∶3, initial concentration of total monomers was 30% of the total mass of the system, initiator dosage was 0.5% of the monomer mass, reaction temperature was 80 ℃, and reaction time was 6 h. Infrared spectroscopy testing showed that the synthesized product exhibited characteristic absorption peaks of epoxy groups and quaternary ammonium salts. Thermogravimetric analysis testing showed that the dyeing accelerant had good thermal stability below 300 ℃. By using dyeing accelerant during the dyeing process, the average fixation rate had been increased by 22.6%, and the consumption of inorganic salts can be reduced by 66%. Dyeing accelerant can play a bridging role between dye molecules and fiber molecules, significantly improving dye utilization and reducing inorganic salt onsumption. It has good application prospects in the field of printing and dyeing processing.

Key words: dyeing accelerant, free radical polymerization reaction, reactive dye, fixation rate, inorganic salt, dye uptake, dyeing assistant

CLC Number: 

  • TS193.62

Fig.1

Synthetic route of dyeing accelerators"

Fig.2

Dyeing process curve"

Tab.1

Influence of monomer mass ratio on conversion rate"

AGE和TMAAC质量比 转化率/%
1∶1 84.2±0.9
1∶2 89.6±1.0
1∶3 91.7±1.0
1∶4 92.1±1.2

Tab.2

Influence of initial monomer mass fraction on conversion rate"

单体初始质量分数/% 转化率/%
10 72.5±0.8
20 83.6±0.9
30 91.7±1.0
40 92.0±1.1

Fig.3

Influence of initiator dosage on conversion rate"

Fig.4

Influence of reaction temperature on conversion rate"

Fig.5

Influence of reaction time on conversion rate"

Fig.6

Infrared spectra of dyeing accelerant, TMAAC and AGE"

Fig.7

Zeta potential distribution curves"

Fig.8

TG/DTG curves of dyeing accelerant"

Fig.9

Apparent viscosity shear rate curve of dyeing accelerant"

Fig.10

Influence of angular frequency on G', G" and tanδ"

Fig.11

Influence of shear strain on G', G" and tanδ"

Fig.12

Influence of dyeing accelerant on fixation rate"

Fig.13

Influence of dyeing accelerant on K/S values"

Fig.14

Mechanism of fixation reaction"

Fig.15

Influence of salt dosage on K/S values"

Tab.3

Rubbing fastness and soap washing fastness of fabrics"

染料 耐摩擦色牢度/级 耐皂洗色牢度/级
湿 变色 沾色
粘胶
活性红3BFN 4 4 4~5 4 4~5
活性黄HER 4 4 4 4 4~5
活性蓝RGN 4 4 5 4 4~5
[1] 王政凯, 张红娟, 王辉强, 等. 多活性基绿色活性染料的合成及在丝织物上的应用性能[J]. 印染, 2024, 50(3): 6-10.
WANG Zhengkai, ZHANG Hongjuan, WANG Huiqiang, et al. Synthesis of green multi-reactive dyes and the application on silk fabrics[J]. China Dyeing & Finishing, 2024, 50(3): 6-10.
[2] 吴伟, 纪柏林, 毛志平. 活性及分散染料染色新技术[J]. 纺织学报, 2023, 44(5): 1-12.
WU Wei, JI Bolin, MAO Zhiping. Review of new dyeing technologies for reactive dyes and disperse dyes[J]. Journal of Textile Research, 2023, 44(5): 1-12.
doi: 10.1177/004051757404400101
[3] 陈小文, 吴伟, 钟毅, 等. 棉织物的活性染料低含水率焙蒸固色工艺[J]. 纺织学报, 2021, 42(7): 115-122.
CHEN Xiaowen, WU Wei, ZHONG Yi, et al. Low-moisture content baking and steaming color fixation process for cotton fabrics padded with reactive dyes[J]. Journal of Textile Research, 2021, 42(7): 115-122.
[4] 邵敏, 王丽君, 李美琪, 等. 非水介质-微水体系中活性染料的水解和键合性能[J]. 纺织学报, 2022, 43(11): 94-103.
doi: 10.13475/j.fzxb.20220812110
SHAO Min, WANG Lijun, LI Meiqi, et al. Hydrolysis and bonding properties of reactive dyes in non-aqueous medium with minimal water systems[J]. Journal of Textile Research, 2022, 43(11): 94-103.
doi: 10.13475/j.fzxb.20220812110
[5] 韩博, 王玉霖, 舒大武, 等. 活性染料染色废水的循环染色[J]. 纺织学报, 2023, 44(8): 151-157.
HAN Bo, WANG Yulin, SHU Dawu, et al. Reactive dyeing using recycled dyeing wastewater[J]. Journal of Textile Research, 2023, 44(8): 151-157.
[6] 胡玲玲, 范雪荣. 双卤代均三嗪活性染料水解反应机制及其动力学[J]. 纺织学报, 2013, 34(10): 68-75.
HU Lingling, FAN Xuerong. Hydrolysis mechanism and kinetics of bis(halogeno-s-trazine) reactive dyes[J]. Journal of Textile Research, 2013, 34(10): 68-75.
[7] PARMAR T V, DESAI H H. "Synthesis, characterization & dyeing properties of bi-functional reactive dye "diazotized 5-(4-methoxy phenyl)-1,3-thiazole-2-amine-cyanurated napthionic acid-para cresidine vinyl sulphone""[J]. Chemistry & Biology Interface, 2021, 11(3): 116-123.
[8] GUO Q, CHEN W G, CUI Z H, et al. Reactive dyeing of silk using commercial acid dyes based on a three-component Mannich-type reaction[J]. Coloration Technology, 2020, 136(4): 336-345.
doi: 10.1111/cote.v136.4
[9] 王辉强, 张红娟, 沈楚良, 等. 红色活性染料结构与棉织物无盐染色性能关系研究[J]. 丝绸, 2025, 62(5): 53-60.
WANG Huiqiang, ZHANG Hongjuan, SHEN Chuliang, et al. Study on the relationship between structure of red reactive dyes and salt-free dyeing performance of cotton fabrics[J]. Journal of Silk, 2025, 62(5): 53-60.
[10] 王小丽, 鹿旺, 房磊, 等. 基于聚二甲基二烯丙基氯化铵阳离子改性的棉织物低盐低碱染色[J]. 印染, 2025, 51(5): 12-16, 39.
WANG Xiaoli, LU Wang, FANG Lei, et al. Low-salt and low-alkali dyeing of cotton fabrics based on cationic modification with polydiallyldimethylammonium chloride[J]. China Dyeing & Finishing, 2025, 51(5): 12-16, 39.
[11] 王静, 张建新, 吴明华. 聚酰胺-胺在棉织物低盐低碱活性染料染色中的应用[J]. 染整技术, 2024, 46(12): 25-30.
WANG Jing, ZHANG Jianxin, WU Minghua. Application of polyamide-amine for low salt and low alkali dyeing of cotton fabrics[J]. Textile Dyeing and Finishing Journal, 2024, 46(12): 25-30.
[12] 易菁源, 裴刘军, 朱赫, 等. 非水介质染色体系中分散染料对涤纶/棉混纺织物的沾色研究[J]. 纺织学报, 2023, 44(5): 29-37.
YI Jingyuan, PEI Liujun, ZHU He, et al. Study on disperse dye staining on polyester/cotton blended fabrics in non-aqueous medium dyeing system[J]. Journal of Textile Research, 2023, 44(5): 29-37.
[13] 张卫卫, 李春燕, 梁娟. 棉用活性染料无醛固色剂的合成及应用[J]. 印染, 2024, 50(4): 46-48, 65.
ZHANG Weiwei, LI Chunyan, LIANG Juan. Preparation and characterization of formaldehyde free fixing agents for cotton reactive dyes[J]. China Dyeing & Finishing, 2024, 50(4): 46-48, 65.
[14] WANG Y H, HUANG H. A study on the dye fixation mechanism of waterborne polyurethane[J]. Chemistry Select, 2023, 8(12): e202204620.
[15] PROSVIRNINA A P, BUGROV A N, DOBRODUMOV A V, et al. Bacterial cellulose nanofibers modification with 3-(trimethoxysilyl)propyl methacrylate as a crosslinking and reinforcing agent for 3D printable UV-curable inks[J]. Journal of Materials Science, 2022, 57(44): 20543-20557.
doi: 10.1007/s10853-022-07902-5
[16] 邢洋洋, 王冲, 付中禹, 等. PAN链缠结的影响因素及其对PAN/DMSO溶液流变行为的影响[J]. 中国塑料, 2020, 34(4): 1-5.
doi: 10.19491/j.issn.1001-9278.2020.04.001
XING Yangyang, WANG Chong, FU Zhongyu, et al. Effect of influencing factor of PAN chain entanglement on rheological behavior of PAN/DMSO solution[J]. China Plastics, 2020, 34(4): 1-5.
doi: 10.19491/j.issn.1001-9278.2020.04.001
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