纺织学报 ›› 2023, Vol. 44 ›› Issue (12): 96-105.doi: 10.13475/j.fzxb.20221002001

• 染整与化学品 • 上一篇    下一篇

莱赛尔机织物防原纤化前处理工艺优化

石路健1,2, 宋亚伟1,2, 谢汝义1,2, 高志超3, 房宽峻1,2()   

  1. 1.青岛大学 纺织服装学院, 山东 青岛 266071
    2.青岛大学 生态纺织省部共建协同创新中心,山东 青岛 266071
    3.愉悦家纺有限公司, 山东 滨州 256600
  • 收稿日期:2022-10-17 修回日期:2023-09-09 出版日期:2023-12-15 发布日期:2024-01-22
  • 通讯作者: 房宽峻(1963—),男,教授,博士。主要研究方向为生态纺织技术。E-mail:13808980221@163.com
  • 作者简介:石路健(1996—),男,硕士生。主要研究方向为绿色化学与清洁印染。
  • 基金资助:
    山东省重大科技创新工程项目(2023CXGC010612);省部共建生物多糖纤维成形与生态纺织国家重点实验室基金项目(ZDKT202103)

Anti-fibrillation pretreatment technology for Lyocell woven fabrics

SHI Lujian1,2, SONG Yawei1,2, XIE Ruyi1,2, GAO Zhichao3, FANG Kuanjun1,2()   

  1. 1. College of Textiles & Clothing, Qingdao University, Qingdao, Shandong 266071, China
    2. Collaborative Innovation Center for Eco-Textiles of Shandong Province and the Ministry of Education, Qingdao University, Qingdao, Shandong 266071, China
    3. Yuyue Home Textile Co., Ltd., Binzhou, Shandong 256600, China
  • Received:2022-10-17 Revised:2023-09-09 Published:2023-12-15 Online:2024-01-22

摘要:

针对前处理中莱赛尔织物在浓碱、湿热和摩擦作用下的原纤化问题,分别探究了冷轧堆碱退浆精练、汽蒸碱退浆精练、酶退浆、漂白和丝光等工艺对原纤化现象的影响,分析了NaOH、H2O2等化学品及时间、温度等条件与原纤分裂过程的关系,优化莱赛尔机织物前处理条件和加工流程。结果表明:虽然NaOH可有效提升织物毛效,但当其质量浓度在20 g/L以上时,莱赛尔纤维开始原纤化,并且随着质量浓度的增加,原纤化逐渐增强;采用淀粉酶退浆工艺不仅能够获得满意的白度和毛效,而且防原纤化效果较好;H2O2漂白能够进一步提升织物的白度,但H2O2质量浓度较高时,织物表面出现原纤化;使用浓碱丝光会使莱赛尔剧烈溶胀,织物发生严重的原纤化;采用酶退浆和轻漂白的短流程工艺可有效防止原纤化的发生。

关键词: 莱赛尔机织物, 原纤化, 退浆, 漂白, 丝光

Abstract:

Objective Lyocell fibers are prone to high fibrillation owing to the friction under alkaline condition. In order to reduce the fibrillation behavior, herein, the effects of pretreatment process, like cold pad-batch desizing, hot-alkali desizing, enzyme desizing, bleaching, and mercerizing on the fibrillation phenomenon were investigated. The relationship between chemicals such as NaOH, H2O2, as well as treatment conditions like time and temperature, and fibrillation generation process was analyzed. Then, the pretreatment conditions and process of Lyocell woven fabric were optimized.
Method In this paper, in order to investigate the effect of desizing process on fibrillation phenomenon, cold pad-batch desizing, hot-alkali desizing, and enzyme desizing were conducted, respectively. Then, the desized Lyocell woven fabric was bleached and mercerized. The treatment conditions like time, pH value, temperature and the chemical concentration were determined. The capillary effect and whiteness were measured. The fibrillation behavior was determined using Martindale abrasion machine and observed with scanning electron microscope. From the comparison of the fabrics after the treatment of deszing, bleaching and mercerizing, the pretreatment process and conditions were optimized.
Results The effects of desizing processes on the properties of capillary effect, whiteness, and fibrillation behavior were investigated. In the cold pad-batch desizing of Lyocell fabrics, capillary effect and whiteness increased as the NaOH concentration increased from 10 to 30 g/L (Fig. 1 and Fig. 2). However, when the concentration of NaOH was above 25 g/L, the pilling grade decreased and fibrillation appeared. Comparatively, the pilling grade of the Lyocell fabric decreased from significantly when the concentration of NaOH is above 20 g/L using hot-alkali desizing (Fig. 5). It means that low temperature desizing could avoid the generation of fibrillation phenomenon to a certain extent. In enzyme desizing, the fabric obtained satisfactory capillary effect and whiteness at the enzyme concentration of 8 g/L with a batching time of 12 h. Moreover, the pilling grade maintained at 4 and no obvious fibrillation phenomenon appeared when the enzyme desizing condition varied. It was indicated that enzyme desizing was a good choice for good capillary effect and whiteness with lower fibrillation behavior. The influence of bleaching treatment on fibrillation behavior was presented (Fig. 13 and Tab. 3). In can be seen that, increasing the H2O2 concentration could significantly increase the whiteness, but fibrillation appeared when the H2O2 concentration was above 3 g/L and the treatment time was above 30 min. The effect of mercerizing on fibrillation was also investigated (Fig. 15 and Fig. 16). The result shows that, when the concentration of NaOH was above 125 g/L and the treatment time was above 1 min, serious fibrillation appeared on Lyocell fabric surface. The reason is that alkali treatment could cause obvious fiber swelling, then Na+ carried a large number of water molecules into the amorphous region of the fiber, resulting in the decrease of fiber lateral force.
Conclusion In the pretreatment process of Lyocell fabrics, obvious swelling and fibrillation could be caused by NaOH. From the comparison of cold pad-batch desizing, hot-alkali desizing and enzyme desizing, the last method could effectively reduce the fibrillation behavior of the Lyocell fabrics because there is no alkali consumed. H2O2 bleaching can further improve the whiteness of the fabric, but when the concentration is higher, the fabric of Lyocell will be slightly fibrillated. In addition, because Lyocell fabrics have less impurities than cotton, light bleaching process can be used to obtain higher whiteness. In addition, alkali mercerization can cause serious fibrillation, so mercerization was not suggested to be conducted in the pretreatment process. Therefore, in order to reduce the fibrillation tendency in Lyocell woven fabric pretreatment, low temperature, low alkali consumption or enzyme treatment was suggested.

Key words: Lyocell woven fabric, fibrillation, desizing, bleaching, mercerizing

中图分类号: 

  • TS190.5

图1

NaOH质量浓度对织物毛效和抗起毛起球等级的影响(堆置时间 20 h)"

图2

冷轧堆碱退浆中不同质量浓度NaOH处理后织物的SEM照片(×3 000)"

图3

堆置时间对织物毛效和抗起毛起球等级的影响(NaOH质量浓度20 g/L)"

图4

冷轧堆碱退浆中不同堆置时间后织物的SEM照片(×3 000)"

图5

NaOH质量浓度对织物毛效和抗起毛起球性能的影响(汽蒸时间 50 min)"

图6

汽蒸碱退浆中不同质量浓度NaOH处理后织物SEM照片(×3 000)"

图7

汽蒸时间对织物毛效和抗起毛起球性能的影响(NaOH 15 g/L)"

图8

汽蒸碱退浆中不同汽蒸时间下织物SEM照片 (×1 000)"

图9

酶质量浓度对织物毛效和抗起毛起球性能的影响(堆置时间 12 h)"

图10

不同质量浓度酶处理后织物SEM照片(×3 000)"

图11

堆置时间对织物毛效和起毛起球性能的影响(酶质量浓度8 g/L)"

图12

酶退浆中不同堆置时间处理后织物的SEM照片(×3 000)"

表1

3种退浆工艺对比"

工艺 毛效/cm 白度/% 抗起毛起球等级/级
冷轧堆碱退浆精练 11.4 84 3~4
汽蒸碱退浆精练 12.9 84 3~4
酶退浆 11.5 91 4

表2

H2O2质量浓度对织物性能影响"

H2O2质量浓度/(g·L-1) 毛效/cm 白度/% 抗起毛起球等级/级
0 12.1 90 4
1 16.2 91 4
2 16.5 93 4
3 16.1 94 4
4 16.6 94 4
5 16.7 94 4
6 15.8 94 3~4

图13

不同质量浓度H2O2处理后织物SEM照片(×1 000)"

表3

汽蒸时间对织物性能的影响"

汽蒸时间/min 毛效/cm 白度/% 抗起毛起球等级/级
0 11.5 91 4
10 16.7 95 4
20 17.0 95 4
30 16.2 95 4
40 16.8 95 4
50 16.2 95 3~4
60 16.3 94 3~4

图14

不同汽蒸时间处理后的织物SEM照片(×1 000)"

表4

NaOH质量浓度对织物性能的影响"

NaOH质量浓度/(g·L-1) 毛效/cm 白度/% 抗起毛起球等级/级
0 16.5 94 4
125 25.3 91 3~4
150 25.8 90 3~4
175 25.5 88 3
200 26.7 86 3
225 24.6 90 3
250 21.2 90 3

图15

不同质量浓度NaOH处理后的织物SEM照片(×3 000)"

表5

丝光时间对织物性能的影响"

丝光时间/min 毛效/cm 白度/% 抗起毛起球等级/级
0 16.3 94 4
1 21.6 94 4
2 24.9 94 4
3 23.7 93 3~4
4 23.3 94 3~4
5 25.6 91 3~4
6 26.1 90 3

图16

不同丝光时间莱赛尔机织物的SEM照片(×1 000)"

图17

前处理过程中碱对莱赛尔纤维原纤化的影响机制"

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