全棉水刺非织造布的等离子体冷堆脱脂漂白工艺响应面法优化

doi:10.13475/j.fzxb.20220709501

纺织学报 ›› 2023, Vol. 44 ›› Issue (11): 132-141.doi: 10.13475/j.fzxb.20220709501

全棉水刺非织造布的等离子体冷堆脱脂漂白工艺响应面法优化

刘骏韬¹, 孙婷¹^,², 涂虎¹^,³, 胡敏¹^,³, 张如全¹^,³(), 孙雷⁴, 罗霞⁴, 纪华²

1.武汉纺织大学纺织科学与工程学院, 湖北武汉 430200
2.稳健医疗(武汉)有限公司, 湖北武汉 430415
3.武汉纺织大学省部共建纺织新材料与先进加工技术国家重点实验室, 湖北武汉 430200
4.稳健医疗(黄冈)有限公司, 湖北黄冈 438021

收稿日期:2022-07-27 修回日期:2023-08-18 出版日期:2023-11-15 发布日期:2023-12-25
通讯作者: 张如全(1966—),男,教授,博士。主要研究方向为智能纺织品和功能非织造材料。E-mail:zhangruquan@wtu.edu.cn。
作者简介:刘骏韬(1998—),男,硕士生。主要研究方向为产业用纺织品。
基金资助:
湖北省重点研发计划项目(2022BAD031)

Optimization of plasma cold pad-batch degreasing/bleaching process for cotton spunlace nonwoven by response surface method

LIU Juntao¹, SUN Ting¹^,², TU Hu¹^,³, HU Min¹^,³, ZHANG Ruquan¹^,³(), SUN Lei⁴, LUO Xia⁴, JI Hua²

1. School of Textile Science and Engineering, Wuhan Textile University, Wuhan, Hubei 430200, China
2. Winner Medical (Wuhan) Co., Ltd., Wuhan, Hubei 430415, China
3. State Key Laboratory of New Textile Materials and Advanced Processing Technologies, Wuhan Textile University, Wuhan, Hubei 430200, China
4. Winner Medical (Huanggang) Co., Ltd., Huanggang, Hubei 438021, China

Received:2022-07-27 Revised:2023-08-18 Published:2023-11-15 Online:2023-12-25

摘要/Abstract

摘要：

为解决全棉水刺非织造布冷堆脱脂漂白处理时间长的问题,采用等离子体冷堆脱脂漂白工艺对其进行处理,借助扫描电子显微镜和红外光谱仪分析材料的微观形貌和化学结构,设计单因素实验探究等离子体处理功率、等离子体处理时间、冷堆时间对材料白度、断裂强力、吸水率的影响,并在此基础上设计响应面法优化实验,确定最佳工艺参数。结果表明:等离子体处理可去除非织造布表面棉籽壳等异物杂质并在布面留下孔洞,经冷堆处理后孔洞得到一定消除;等离子体处理可减少棉纤维表面脂类物质,增加羟基含量,提高棉纤维的亲水性;经响应面法优化后得到最佳优化工艺条件为等离子体处理功率2 kW、等离子体处理时间11 s、冷堆时间6.5 h,经过此条件处理的全棉水刺非织造布的白度可达到75.883 6%。

关键词: 响应面法, 等离子体技术, 冷堆, 全棉水刺非织造布, 脱脂漂白工艺, 水刺法加固

Abstract:

Objective Cotton fiber is a natural cellulose fiber with a wide range of applications. Cotton spunlace nonwovens as a cotton fiber product are widely used in medical textile and personal protection. However, for degreasing and bleaching of cotton spunlace nonwovens, the conventional cold pad-batch process faces the problems of long processing time and low production efficiency. Therefore, novel technologies need to be developed to reduce cold pad-batch time and improve production efficiency.

Method The cotton spunlace nonwovens were plasma treated using PG-10000F plasma equipment, and the treatment solution prepared from 4 g/L NaOH, 6 g/L H₂O₂, 2 g/L tetraacetylethylenediamine(TAED), and 2 g/L fatty alcohol polyoxyethylene ether was stirred evenly by magnetic stirring. After plasma treatment, the cotton spunlace nonwoven was immediately put into a self-sealing bag containing hydrogen peroxide activation solution with a bath ratio of 1∶20, then reacted within a certain time from 0 to 24 h at 30 ℃. The cotton spunlace nonwoven was then soaked in warm water at 60 ℃, and washed with water twice for removing impurities. Finally, the degreased/bleached cotton nonwoven fabric was obtained after drying in an oven at 40 ℃ for 4 h.

Results The pores formed by plasma treatment were properly eliminated in the bleaching process (Fig. 3). Plasma treatment and hydrogen peroxide activation treatment were adopted to smooth the fiber surface (Fig. 4), while the plasma treatment removed lipid substances from the surface of cotton fibers and improve the hydrophilicity of cotton fibers (Fig. 5). Plasma treatment time and cold pad-batch time were unchanged for all samples, and the material whiteness was the highest when the plasma treatment power was at 2 kW (Fig. 6(a)) and the plasma treatment time was 10 s (Fig. 6(b)). Plasma treatment power and plasma treatment time remained unchanged, and there was no significant change in whiteness after 6 h of cold pad-batch time (Fig. 6(c)). As the plasma treatment power increased, the water absorption showed an upward trend, and gradually flattened after the power reached 2 kW (Fig. 7(a)). The plasma treatment time had little influence on the water absorption of the material (Fig. 7(b)). The water absorption showed an upward trend with the increased cold pad-batch time, and the first 2 h increased the fastest (Fig. 7(c)). The plasma treatment power displayed no significant influence on the material strength (Fig. 8(a)). With the prolongation of plasma treatment time, the strength showed a decreasing trend, and had no significant change after 15 s (Fig. 8(b)). With the prolongation of cold pad-batch time, the material strength decreased rapidly within 4 h, and then gradually flattened (Fig. 8(c)). According to response surface analysis, plasma treatment power and plasma treatment time showed no significant influence on the whiteness of cotton spunlace nonwovens (Fig. 9). The cold pad-batch time had the greatest influence on the whiteness of nonwovens, and the whiteness increased rapidly at first and then decreased slowly with the increase of the cold pad-batch time (Fig. 10). The whiteness increases first and then decreased with the plasma treatment time, and the increased and decreased proportion of whiteness was almost the same (Fig. 11). When the whiteness of the response value was set to the maximum (76%), the optimal condition from the response surface optimization implied the plasma treatment power was 1.828 kW, and the plasma treatment time was 10.804 s. When the cold reactor time was 6.454 h, the whiteness was 75.872%, R²=0.923 5, indicating an accurate model.

Conclusion In summary, plasma treatment could moderately remove the cotton seed shell and other foreign impurities on the surface of cotton spunlace grey nonwoven fabrics. At the same time, lipid substances were removed from the surface of cotton fiber after plasma treatment, the number of hydrophilic groups such as hydroxyl increased, and the water absorption of cotton spunlace nonwovens were improved. Plasma treatment could promote the degreasing and bleaching process. Although the plasma cold pad-batch treatment process could hardly increase the treated cotton spunlace nonwovens whiteness, the cold pad-batch time were shorted from 8 h to 6.5 h compared with the conventional cold pad-batch process, which could improve the production efficiency.

Key words: response surface method, plasma technology, cold pad-batch, cotton spunlace nonwoven, degreasing and bleaching process, spun reinforcement

中图分类号:

TS174.8

刘骏韬, 孙婷, 涂虎, 胡敏, 张如全, 孙雷, 罗霞, 纪华. 全棉水刺非织造布的等离子体冷堆脱脂漂白工艺响应面法优化[J]. 纺织学报, 2023, 44(11): 132-141.

LIU Juntao, SUN Ting, TU Hu, HU Min, ZHANG Ruquan, SUN Lei, LUO Xia, JI Hua. Optimization of plasma cold pad-batch degreasing/bleaching process for cotton spunlace nonwoven by response surface method[J]. Journal of Textile Research, 2023, 44(11): 132-141.

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水平	等离子体处理功率/kW	等离子体处理时间/s	冷堆时间/h
-1	1	5	4
0	2	10	6
1	3	15	8

实验编号	等离子体处理功率/ kW	等离子体处理时间/ s	冷堆时间/h	白度/ %
1	3	10	4	72.726
2	2	10	6	75.615
3	1	5	6	75.020
4	2	10	6	75.850
5	2	10	6	75.925
6	3	10	8	74.274
7	2	15	8	74.610
8	2	10	6	75.760
9	2	15	4	73.075
10	3	15	6	75.064
11	2	10	6	75.690
12	3	5	6	75.047
13	1	10	8	74.589
14	2	5	8	74.630
15	1	10	4	73.037
16	1	15	6	75.442
17	2	5	4	73.019

方差来源	平方和SS	自由度DF	均方MS	F值	P	显著性
模型	18.90	9	2.100	161.61	< 0.000 1	显著
等离子体处理功率A	0.119 3	1	0.119 3	9.180	0.019 1
等离子体处理时间B	0.028 2	1	0.028 2	2.17	0.184 2
冷堆时间C	4.880	1	4.880	375.33	< 0.000 1
AB	0.041 0	1	0.041 0	3.16	0.118 9
AC	4×10^-6	1	4×10^-6	0.000 3	0.986 5
BC	0.001 4	1	0.001 4	0.111 1	0.748 6
A²	0.676 6	1	0.676 6	52.08	0.000 2
B²	0.211 0	1	0.211 0	16.24	0.005 0
C²	12.320	1	12.320	948.30	< 0.000 1
残差	0.090 9	7	0.013 0
失拟项	0.030 0	3	0.010 0	0.656 9	0.619 8	不显著
纯误差	0.060 9	4	0.015 2
总和	18.990	16
变异系数/%	0.152 7

全棉水刺非织造布的等离子体冷堆脱脂漂白工艺响应面法优化

Optimization of plasma cold pad-batch degreasing/bleaching process for cotton spunlace nonwoven by response surface method

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