茜草植物染料染色羊绒纤维的摩擦牢度

摘要/Abstract

摘要： 茜草是最常用的红色天然染料，广泛应用于真丝和纤维素纤维染色。但生产中发现明矾作为媒染剂用于茜草植物染料染色羊绒纤维的摩擦牢度极差。通过对媒染、染色前后羊绒表面沉积物分析及其与摩擦牢度的相互关系，分析探讨了导致摩擦牢度低下的原因并提出改进方法。结果表明：适度去鳞片处理可有效减少明矾媒染时氢氧化铝在羊绒表面沉积，使茜草植物染料染色羊绒的干、湿摩擦牢度分别提高到2级和3级；酒石酸-明矾媒染羊绒表面无明显沉积，茜草植物染料染色后羊绒纤维的干、湿摩擦牢度分别提高到4级和5级，同时日晒、皂洗牢度也均在4级以上。

关键词: 茜草植物染料, 羊绒, 摩擦牢度, 酒石酸-明矾

Abstract: As the most commonly used red natural dye, madder is widely used in the dyeing of silk and cellulose fibers. Nevertheless, it is found that the rubbing fastness of cashmere fibers dyed with madder vegetable dyes with alum as the mordant is very poor, with the dry rubbing fastness reaching grade 1, and the wet rubbing fastness reaching grade 2–3, respectively. In contrast, the dry and wet rubbing fastness of cashmere fibers dyed with madder vegetable dyes with ferrous sulfate as mordant can reach grade 3 and grade 4. To explore the reason why the rubbing fastness of the two is so different, scanning electron microscopy tests were carried out on the cashmere dyed by alum and ferrous sulfate, respectively. The results showed that there was a large amount of solid sediment on the surface of cashmere fibers dyed by alum, but no solid sediment was found on the surface of cashmere dyed by ferrous sulfate. This is because the pH value of the solution during alum dyeing is higher than the precipitation point of the aluminum ion, and a large amount of aluminum hydroxide is deposited on the surface of cashmere during the dyeing process. As a result, the madder dye will react with aluminum ions on the surface of cashmere during dyeing, and the madder dye attached to the surface of cashmere cannot be diffused into the interior of the cashmere fiber, resulting in poor rubbing fastness. Ferrous sulfate dyeing is carried out under weak acidic conditions, ferrous ions are slowly and uniformly absorbed and diffused into cashmere fibers to have coordination reaction with cashmere, and the madder dye can diffuse into cashmere fibers and combine with fibers and ferrous ions during dyeing, so both the dry rubbing fastness and wet rubbing fastness are good. Previous studies have shown that the rubbing fastness of madder to silk and cellulose fibers is excellent, but that of cashmere is poor. In this regard, it is proposed to use hydrogen peroxide to moderate de-flake treatment of cashmere fibers. The results show that the hydrophobic scales on the surface of cashmere affect the rubbing fastness of alum dyeing and madder dyeing of cashmere. Moderate scale removal can effectively reduce the deposition on the surface of cashmere during alum dyeing, which has a certain effect on the improvement of the dry and wet rubbing fastness. The dry and wet rubbing fastness of unscaled cashmere can be improved to grade 2 and grade 3. The alum-organic acid system was used to dye the cashmere, and then madder dyeing was carried out. Consequently, the dry and wet rubbing fastness of the madder dyed cashmere was improved to grade 2 and grade 3–4. This is because acetic acid reduces the pH value of the dye solution and inhibits the hydrolysis of alum. However, due to the volatility of acetic acid, some acetic acid volatilized at 80℃, resulting in the rise of pH value of the dyeing solution, and the generation of a small amount of aluminum hydroxide. Further, the alum-acetic acid system is used to dye cashmere, and the dry and wet rubbing fastness of dyed cashmere fibers is increased to grade 4 and grade 5. This is because tartric acid effectively reduces the pH value of alum dye solution, and Al3+ can be evenly diffused into the interior of cashmere fibers and have coordination reaction with cashmere. During dyeing, madder dye can fully combine with Al3+ and fiber. Moreover, infrared spectrum shows that tartric acid can form hydrogen bond with cashmere, which makes tartric acid, cashmere fiber and madder binding. The dry and wet rubbing fastness of dyed cashmere has been improved to grade 4 and 5, respectively, and the soap fastness and sun fastness are all above grade 4, which lays the foundation for industrial application.

Key words: madder vegetable dye, , cashmere, rubbing fastness, tartaric acid-alum

中图分类号:

TS 193.6

俞建伟, 侯战昌, 陈超, 余志成. 茜草植物染料染色羊绒纤维的摩擦牢度[J]. 现代纺织技术, 2024, 32(2): 105-111.

YU Jianweia, b, HOU Zhanchang, CHEN Chao, YU Zhichenga, b. The rubbing fastness of cashmere fibers dyed with madder vegetable dyes[J]. Advanced Textile Technology, 2024, 32(2): 105-111.

参考文献

[1]杜海娟, 张海燕, 杨小明, 等. 茜草中红色素的提取与染色性能研究[J]. 中原工学院学报, 2018, 29(4): 11-17,69.
DU Haijuan, ZHANG Haiyan, YANG Xiaoming, et al. Study on the extraction and dyeing properties of red pigment in madder[J]. Journal of Zhongyuan University of Technology, 2018, 29(4): 11-17, 69.
[2]孙闻莺. 中国古代染色文化与植物染料研究[J]. 纺织报告, 2020 ,39(12): 126-128.
SUN Wenying. Study on dyeing culture and plant dyes in ancient China[J]. Textile Reports, 2020, 39(12): 126-128.
[3]谈君婕. 红色天然染料的制备及在纯棉针织物上的应用[D]. 常州：常州大学, 2021.
TAN Junjie. Preparation of Red Natural Dye and Its Application in Cotton Knitted Fabric[D]. Changzhou: Changzhou University, 2021.
[4]金光, 薛娟丽, 段静静. 基于纤维跨距长度曲线的山羊绒长度及其分布测试[J]. 毛纺科技, 2019 , 47(7): 76-79.
JIN Guang, XUE Juanli, DUAN Jingjing. Test of length and distribution of cashmere based on fiber span length curve[J]. Wool Textile Journal, 2019, 47(7): 76-79.
[5]程彦, 田君, 李星, 等. 茜草植物染料在羊绒纤维染色中的应用[J]. 毛纺科技, 2019, 47(8): 45-47.
CHENG Yan, TIAN Jun, LI Xing, et al. Application of rubia vegetable dyes in cashmere fiber dyeing[J]. Wool Textile Journal, 2019, 47(8): 45-47.
[6]袁小红. 茜草植物染料提取工艺及染色性能研究[J]. 中原工学院学报, 2011, 22(5): 45-48.
YUAN Xiaohong. The extraction process of madder dye and its dyeing properties[J]. Journal of Zhongyuan University of Technology, 2011, 22(5): 45-48.
[7]倪宇超, 夏建明, 董超萍. 真丝织物的茜草根植物染料染色[J]. 印染, 2022, 48(5): 40-42,54.
NI Yuchao, XIA Jianming, DONG Chaoping. Dyeing of silk fabric with natural colorants extracted from madder root [J]. China Dyeing & Finishing, 2022, 48(5): 40-42,54.
[8]王建国, 朱正, 蒙龙伟, 等. 没食子酸对胡桃醌染色性能的影响[J]. 天然产物研究与开发, 2019, 31(6): 1082-1090.
WANG Jianguo, ZHU Zheng, MENG Longwei, et al. Effect of gallic acid on the dyeing performance of Juglone[J]. Natural Product Research and Development, 2019, 31(0): 1082-1090.
[9]葛化博, 吕秀君, 万明, 等. 天然植物基染料提升色牢度的研究进展及展望[J]. 毛纺科技, 2021, 49(11): 101-109.
GE Huabo, LÜ Xiujun, WAN Ming, et al. Research progress and prospect of color fastness of natural plant-based dye[J]. Wool Textile Journal, 2021, 49(11): 101-109.
[10]SINHA K, AIKAT K, DAS P, et al. Dyeing of modified cotton fiber with natural Terminalia arjuna dye: Optimization of dyeing parameters using response surface methodology[J]. Environmental Progress ＆ Sustainable Energy, 2016, 35(3): 719-728．

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