莱赛尔纤维及其制品颜色构建技术的研究进展

doi:10.13475/j.fzxb.20250205402

Abstract

Abstract:

Significance As an important regenerated cellulose fiber, Lyocell fiber has excellent properties and comprehensive preparation techniques, which has been attracted extensive attention. Owing to the green production process, Lyocell fiber has become the most promising regenerated cellulose fiber, which have extensively applied in various fields, such as textiles, clothing, household goods, and so on. The unique fibrillating properties of Lyocell fibers pose a challenge to the dyeing techniques. In the conventional Lyocell fiber dyeing process, in order to promote dyeing in an aqueous solution and improve the dyeing rate, plenty of water and salt auxiliaries have been used. However, these dyeing methods are facing environmental and energy challenges, including high water consumption, high energy consumption, the discharge of additives, and serious pollution of wastewater. Therefore, aiming at the current limitations, color construction of Lyocell fiber has been extensively investigated. In order to achieve color construction of Lyocell fiber with diverse colors, high fastness, eco-friendly processes, and promote the sustainable industrial development of resources and the environment, the latest progress in different technologies of color construction for Lyocell fiber and its products has been systematically summarized. +++Progress Environmental pollution associated with the conventional dyeing methods has been the research focus due to the use of salt reagents and wastewater. Therefore, attention has been attracted to the clean dyeing methods for the color construction of Lyocell fiber. This review paper focuses on the more environmentally friendly color construction methods of Lyocell fiber, including surface modification dyeing, dope dyeing, ultrasonic-assisted dyeing, and high-temperature vat dyeing. Based on the systematic analysis of the research status for Lyocell fiber color construction, the development and challenges of different dyeing methods were reviewed. Surface modification dyeing enables a more stable binding force between the fiber and dye, hence improving the color fastness and reducing the fiber fibrillation, but the dyeing process is limited by the complicated process. The technique of stock solution coloring omits the subsequent dyeing process of fiber, while the achievement of color types and color adjustment is difficult to solve. Ultrasonic-assisted dyeing contributed to the rapid transfer of dye from liquid to fiber, reducing energy consumption and the use of salt auxiliaries for which complicated process is inescapable. Complete chromatography, high color fastness, and short time are the characteristics of high-temperature vat dyeing. However, the energy dissipation is a key point to be overcome in the process of green development in the future. The utilization of natural dyes can reduce environmental pollution, and mordant dyeing can improve the dyeing effect, but the K/S value and color fastness is vital in the practical application process. +++Conclusion and Prospect Compared with the conventional dyeing methods, non-aqueous media dyeing technology not only helps reduce the wastewater discharge of the dyeing process, but also provides a new opportunity for the sustainable development of the dyeing industry in coping with water scarcity to promote green textile production and achieve sustainable development of the textile industry, promoting technological transformation and upgrading. Compared to the mentioned dyeing methods, appropriate non-water or less-water dyeing methods for cellulose fibers, which can effectively reduce water consumption and wastewater emission, show significant advantages of sustainable development. Related green dyeing technology has been widely investigated in cellulose fiber dyeing, which can apply to promote the green sustainable development of Lyocell fiber color construction, contributing to the establishment of a green ecological circular development system in the textile dyeing and finishing industry.

Key words: Lyocell fiber, color construction, surface modification dyeing, dope dyeing, ultrasonic-assisted dyeing, high-temperature vat dyeing, mordant dyeing, clean dyeing technique

CLC Number:

TS193.6

WANG Xuelin, HU Wanjin, ZHOU Sijie, DU Lixin, XIA Liangjun, XU Weilin. Research progress in color construction of Lyocell fiber and its products[J].Journal of Textile Research, 2025, 46(11): 247-254.

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URL: http://www.fzxb.org.cn/EN/10.13475/j.fzxb.20250205402

http://www.fzxb.org.cn/EN/Y2025/V46/I11/247

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References 40

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染色方法	特点	不足
改性	色牢度高,减少原纤化	流程较复杂
原液着色	减少染色步骤	颜色调整困难
超声波辅助	耗能低	流程较复杂
高温还原	时间短	耗能较高
天然染料媒染	染料环保	K/S值较低

染色方法	介质	染料	助剂	时间/min	温度/℃	K/S值	参考文献
阳离子改性染色	去离子水	C.I. Pigment Red 22	阳离子改性剂HYM	30	90	16.20	[22]
阴离子改性染色	去离子水	灵菌红素	1,2,3,4-丁烷四羧酸	20	90	2.71	[23]
阴离子改性染色	去离子水	黄连提取液	1,2,3,5-丁烷四羧酸	60	70	6.30	[24]
原液着色	NMMO溶液	炭黑	—	—	—	34.58	[28]
原液着色	NMMO溶液	靛蓝	—	—	—	9.99	[29]
超声波辅助染色	去离子水	Ramazol Blue RGB	—	360	25~30	25.50	[31]
超声波辅助染色	去离子水	C.I. Reactive Blue 250	—	45	50	17.12	[32]
高温还原染料染色	去离子水	Red GB	分散剂、流平剂等	40	90	26.09	[34]
天然染料媒染染色	去离子水	天然栀子黄色素	单宁酸	60	90	7.45	[35]
天然染料媒染染色	去离子水	万寿菊提取液	硫酸亚铁	30	90	7.81	[36]

Research progress in color construction of Lyocell fiber and its products

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