低温高效精练剂的制备及其应用性能

doi:10.13475/j.fzxb.20250704601

摘要/Abstract

摘要：

为解决传统棉织物前处理工艺高温强碱、用水量大、能耗高、纤维损伤严重等问题,设计并制备了一种由阴离子表面活性剂α-烯烃磺酸钠、非离子表面活性剂异构十三醇聚氧乙烯醚与两性表面活性剂十四烷基二甲基氧化胺按3∶7∶1比例复配的低温高效精练剂。采用单因素实验对低温低碱短流程工艺进行系统研究与优化,通过表面张力测试、润湿性能表征及各项稳定性分析,揭示了表面活性剂三元体系形成混合胶束产生协同增效作用,显著降低临界胶束含量并增强表面活性。结果表明:制备的低温高效精练剂具有优异的表面活性,临界胶束含量低至0.01%,临界胶束浓度处表面张力值达25.33 mN/m,沉降时间为4.43 s,其耐碱、抗氧化、高温稳定性能优良;一浴法低温练漂最优工艺参数为:精练剂 1.4 g/L(以有效含量计),NaOH 3.5 g/L,Na₂SiO₃ 2 g/L,30% H₂O₂ 6~14 g/L,精练温度85℃,精练时间55 min;经最优工艺处理后棉织物毛效可达14.0 cm、白度为81.23%、强力保留率为82.12%。

关键词: 棉织物, 低温, 前处理, 复配, 表面活性剂, 精练剂

Abstract:

Objective Conventional cotton fabric pre-treatment processes are plagued by high energy consumption, extensive water usage, and significant fiber damage due to their reliance on high temperatures and strong alkali. In order to address these critical limitations, this study aimed to develop a novel, low-temperature high-efficiency scouring agent. The primary objective was to design a synergistic surfactant composite that enables a short process under mild conditions, thereby reducing environmental impact while preserving fabric integrity. Establishing an optimized low-temperature bleaching process was also a key task to validate the agent's industrial applicability.

Method A low-temperature high-efficiency scouring agent was designed and prepared by compounding anionic surfactant sodium alpha-olefin sulfonate(AOS), nonionic surfactant isotridecanol ethoxylate, and amphoteric surfactant tetradecyl dimethylamine oxide (OA-14) at a weight ratio of 3∶7∶1. The short process utilizing low temperature and low alkali was systematically studied and optimized via single-factor experiments. The mechanism of action was investigated through surface tension measurements, wetting performance characterization, and comprehensive stability analysis. This approach revealed that the ternary system forms mixed micelles, leading to a synergistic effect that lowers the critical micelle concentration (CMC) and enhances surface activity. The optimal one-bath low-temperature scouring and bleaching process parameters were determined, where the scouring agent 1.4 g/L (based on active content), NaOH 3.5 g/L, Na₂SiO₃ 2 g/L, 30% H₂O₂ 6-14 g/L, process temperature of 85 ℃, and treatment time of 55 min.

Results The prepared low-temperature high efficiency scouring agent demonstrated excellent performance. It exhibited superior surface activity, with a remarkably low CMC of 0.01% and a surface tension at CMC (γ_cmc) of 25.33 mN/m, indicating high efficiency at low usage levels. The wetting time was significantly short, measured at just 4.43 s, which is crucial for rapid and uniform treatment. Furthermore, the agent showed outstanding stability, including good alkali resistance, oxidation resistane, and high-temperature stability, ensuring its robustness under the intended application conditions.

When cotton fabrics were treated using the optimized one-bath low-temperature scouring and bleaching process established in this study, the results met key textile performance benchmarks. The capillary effect, which indicates wettability and absorbency, reached an excellent 14.0 cm, demonstrating effective removal of hydrophobic impurities like waxes. The whiteness of the fabric was measured at 81.23%, confirming successful bleaching and removal of natural pigments. Importantly, the fabric's mechanical strength was well-preserved despite the chemical treatment; and the breaking strength retention rate was 82.12%. This high retention value is a direct benefit of the milder low-temperature process compared to conventional harsh treatments, highlighting the agent's effectiveness in minimizing fiber damage. The synergistic effect within the ternary surfactant system was key to these results. The formation of mixed micelles enhanced the overall surface activity, allowing for effective contaminant removal and wetting at lower concentrations and temperatures than typically required.

Conclusion In conclusion, this study successfully developed a novel ternary composite scouring agent that is both low-temperature efficient and highly effective. The synergistic interaction between the anionic, nonionic, and amphoteric surfactants was identified as the core mechanism, leading to excellent surface activity, wetting power, and stability. The concurrently established optimized one-bath low-temperature scouring and bleaching process, operating at 85 ℃, demonstrates a viable and superior alternative to conventional energy-intensive and fiber-damaging methods. This new process significantly reduces alkali dosage, energy consumption, and water footprint while maintaining high fabric quality, as evidenced by the excellent capillary effect, good whiteness, and, most notably, high strength retention of over 82%. The findings strongly suggest that this approach has significant potential for industrial application, promoting a more sustainable and eco-friendlier pathway for cotton fabric pre-treatment without compromising on performance. Future work could focus on the long-term durability testing of treated fabrics and scaling up the process for industrial evaluation.

Key words: cotton fabric, low temperature, pretreatment, compounding, surfactant, scouring agent

中图分类号:

TS192.2

冯品淇, 张丽宁, 王娜娜, 吕仲, 周存. 低温高效精练剂的制备及其应用性能[J]. 纺织学报, 2026, 47(1): 159-167.

FENG Pinqi, ZHANG Lining, WANG Nana, LÜ Zhong, ZHOU Cun. Preparation and application of low-temperature high-efficiency scouring agent[J]. Journal of Textile Research, 2026, 47(1): 159-167.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250704601

http://www.fzxb.org.cn/CN/Y2026/V47/I1/159

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表面活性剂组合	耐酸稳定性	耐碱稳定性	抗氧化性	耐高温稳定性	离心稳定性
AOS/OXO-1309(3∶7)	轻微浑浊	澄清,无沉淀	澄清,无沉淀	稳定	稳定,不分层
AOS/OXO-1309/GS-A6(3∶7∶1)	轻微浑浊	澄清,无沉淀	澄清,无沉淀	破乳	稳定,不分层
AOS/OXO-1309/OA-14(3∶7∶1)	浑浊	澄清,无沉淀	澄清,无沉淀	稳定	稳定,不分层
AOS	轻微浑浊	澄清,无沉淀	澄清,无沉淀	稳定	稳定,不分层
OXO-1309	澄清无沉淀	澄清,无沉淀	澄清,无沉淀	达到浊点后浑浊	稳定,不分层

不同复配组合精练剂	工艺方法	毛效/cm	白度/%	强力保留率/%
精练剂TBX86	一浴法前处理工艺	14.0	81.23	82.12
AOS/OXO-1309/GS-A6(3∶7∶1)		13.5	81.27	79.05
AOS/OXO-1309(3∶7)		13.5	80.22	80.75
市售精练剂CF-4J		12.5	77.13	82.02
精练剂TBX86	常规前处理工艺	13.1	78.40	61.40
市售精练剂CF-4J	常规前处理工艺	12.9	77.46	63.60