浆纱烘燥过程改善毛羽贴伏的方法及其效果

doi:10.13475/j.fzxb.20220702101

摘要/Abstract

摘要：

针对降低经纱毛羽这一重要浆纱工艺目标,分析浆纱过程中毛羽贴伏的基本要素,提出一种在烘燥过程中改善浆纱毛羽贴伏的方法。该方法利用浆纱所携带浆液的黏附力随着烘燥过程而变化的规律,提出构建毛羽贴伏辊对纱线表面施加刮贴作用,实现浆纱毛羽贴伏效果的显著增强。实验结果表明:随着施加贴伏作用时浆纱的回潮率从40%降低到10%,浆纱有害毛羽量先降低后增加,毛羽贴伏的最佳回潮率为20%;以摩擦长度为贴伏装置运行参数的综合表示,得出浆纱有害毛羽量随摩擦长度的增加呈现先减少后增加的趋势;通过上述参数的最优组合,可实现有害毛羽根数降低36.3%,表明所提出方法有效。该方法可在不影响浆纱工艺的前提下,便捷、高效、稳定地增强浆纱毛羽贴伏,具有良好的实际生产应用价值。

关键词: 浆纱, 有害毛羽, 毛羽贴伏辊, 浆纱回潮率, 摩擦长度, 烘燥

Abstract:

Objective In modern textile industry, the reduction of yarn hairiness has become more critical than improving yarn strength and abrasion resistance in the sizing process. In order to further reduce warp hairiness, this paper reports a method for enhancing the hairiness reduction during the drying process in warp sizing based on the analysis of hairiness attaching mechanism.
Method A laboratory scale XSY617-700 sizing machine was used for research. The sizing guide roller between the pre-drying drum and the combined drying drum was transformed into an actively rotating hairiness attaching roller to build a hairiness attaching device. According to the rule that the adhesion force of the size liquid carried by the yarn changes with the drying process, the effect of scraping action on the surface of the yarn by the hairiness attaching roller was studied. The values for two system parameters, the liquid content of the yarn when it is scraped by the roller and the friction length applied by the roller were optimized to achieve the beset hairiness reduction effect.
Results Based on the above device and method and under the same scraping action, the moisture regain of the yarn was controlled from 40% to 10% and the hairiness performance index was measured when adjusting the temperature of the pre-drying drum. The number of unwanted hairiness showed a trend of increasing first and decreasing afterwards (Fig. 3). The possible reason for this phenomenon was that after pre-drying, the moisture regain of sized yarn was reduced and the concentration of liquor in the yarn was increased, which improved the adhesion of the hairs to the yarn body. While after the moisture regain of sized yarn was reduced to a certain level, the yarn and the hairs was drying out thus the adhesion of them was reduced, more hairs could not be adhered to the yarn surface. It showed that 20% moisture regain of sized yarn was more beneficial in reducing harmful hairiness in the proposed system. The friction length was a comprehensive representation of the operating parameters of the hairiness attaching device, and it was used as a control variable influencing the hairiness reduction effect. When the moisture regain of sized yarn was set as 20% as optimized above, and the friction length was controlled to vary the extent of the applied scraping action. As the friction length increased the scraping action increases and the number of harmful hairiness showed a decrease followed by an increase (Fig. 4). The possible reasons were considered as follows. Firstly, a higher friction length indicated a longer actuation duration of the adhesion effect leading to more hairs being adhered, which would approach a maximum as the friction length increases, while a higher friction length also indicated a higher possibility of adhered hairs to be scraped from the yarn surface. Under the combined effect of them, the unwanted hairiness decreased as the friction length increased at first and increases after the friction length reached a certain point. Finally, under the experimental conditions of this research, when the proposed hairiness attaching device was established and applied, a friction length controlled around 81.6 mm would be more beneficial to the harmful hairiness reduction.
Conclusion With the optimal combination of the parameters and under the experimental conditions in this research, the proposed hairiness attaching device has been proved to be able to reduce the unwanted hairiness by 36.3%. The best reduction of hairiness is achieved when the system parameters are set to 20% moisture regain and 81.6 mm of friction length of the roller attachment effect. The hairiness attaching method and the parameter optimization method proposed in this research can be applied to the production process, considering analysis of the variation of moisture regain of yarn on the target sizing machine, selection of appropriate device forms, device installation position, and the adoption of process parameters for achieve convenient, efficient and stable hairiness attaching.

Key words: sizing process, unwanted hairiness, hairiness attaching roller, moisture regain of sized yarn, friction length, drying

中图分类号:

TS103.12

高波, 吴菊明, 朱博, 王静安, 高卫东. 浆纱烘燥过程改善毛羽贴伏的方法及其效果[J]. 纺织学报, 2023, 44(12): 67-72.

GAO Bo, WU Juming, ZHU Bo, WANG Jing'an, GAO Weidong. A method for sizing hairiness reduction during drying and effect analysis[J]. Journal of Textile Research, 2023, 44(12): 67-72.

图/表 5

图1

图2

表1

图3

图4

参考文献 13

[1]	朱苏康, 高卫东. 机织学[M]. 北京: 中国纺织出版社, 2008: 72-73.
	ZHU Sukang, GAO Weidong. Weaving[M]. Beijing: China Textile & Apparel Press, 2008: 72-73.
[2]	杨红英, 朱苏康. 纱线毛羽[J]. 纺织学报, 2000, 21(6): 11-14.
	YANG Hongying, ZHU Sukang. Yarn hairiness[J]. Journal of Textile Research, 2000(6): 11-14.
[3]	高卫东, 王鸿博. 纱线毛羽危害程度的探讨[J]. 纺织学报, 1998, 19(6): 347-348,3.
	GAO Weidong, WANG Hongbo. Discussion on the harm degree of yarn hairiness[J]. Journal of Textile Research, 1998, 19(6): 347-348,3.
[4]	HALEEM Noman, WANG Xungai. Recent research and developments on yarn hairiness[J]. Textile Research Journal, 2015, 85(2): 211-224.
[5]	黄柏龄, 沈艳琴. 减少纱线毛羽新途径及贴伏浆纱毛羽工艺研究[J]. 棉纺织技术, 2006(5): 5-10.
	HUANG Bailing, SHEN Yanqin. A new way to reduce yarn hairiness and study on the technology of covering sizing hairiness[J]. Cotton Textile Technology, 2006(5): 5-10.
[6]	张朝辉. 减少浆纱毛羽的研究[J]. 纺织学报, 2004, 25(5): 94-95.
	ZHANG Chaohui. Study on reducing hairiness in sizing[J]. Journal of Textile, 2004, 25(5): 94-95.
[7]	SMYKALO Kateryna, ZAKORA Oksana. Effect of hairiness on fabric colour characteristics[J] Tekstilec, 2020, 63(4): 276-286.
[8]	周建才. 棉亚麻混纺纱上浆工艺研讨[J]. 棉纺织技术, 2021, 49(9): 68-70.
	ZHOU Jiancai. Discussion on sizing technology of cotton-flax blended yarn[J]. Cotton Textile Technology, 2021, 49(9): 68-70.
[9]	冯丽娟, 赵洪, 翟秀清, 等. 特细号色纺纱浆纱工艺研究[J]. 棉纺织技术, 2020, 48(1): 9-11.
	FENG Lijuan, ZHAO Hong, ZHAI Xiuqing, et al. Study on sizing technology of extra-fine yarn[J]. Cotton Textile Technology, 2020, 48(1): 9-11.
[10]	赵双军, 曹红梅. 降低纯涤纶纱毛羽的浆纱工艺实践[J]. 纺织科技进展, 2017(6): 12-14.
	ZHAO Shuangjun, CAO Hongmei. Sizing process practice of reducing hairiness of pure polyester yarn[J]. Textile Science and Technology Progress, 2017(6): 12-14.
[11]	吴明. 浅谈预湿上浆技术的应用[J]. 棉纺织技术, 2008(1): 61-64.
	WU Ming. On the application of pre-wetting sizing technology[J]. Cotton Textile Technology, 2008(1): 61-64.
[12]	吴雪芳. 浆纱湿回潮率与上浆率关系的分析[J]. 纺织学报, 1982(11): 36-39,3.
	WU Xuefang. Analysis of the relationship between sizing moisture regain and sizing rate[J]. Journal of Textile Research, 1982(11):36-39,3.
[13]	范雪荣, 荣瑞萍, 纪惠军. 纺织浆料检测技术[M]. 北京: 中国纺织出版社, 2007: 210-211.
	FAN Xuerong, RONG Ruiping, JI Huijun. Textile Size Testing Technology[M]. Beijing: China Textile & Apparel Press, 2007: 210-211.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

车速/ (m·min^-1)	上浆率/ %	压浆力/ kN	摩擦长度/mm	预烘烘筒温度/℃	实测浆纱回潮率/%
10	3.2	8	65.3	25	39.76
				38	29.71
				50	20.13
				62	15.41
				75	10.26

[1]	陆浩杰, 李曼丽, 金恩琪, 张宏伟, 周赳. 基于弧形电容器的浆纱回潮率在线测量[J]. 纺织学报, 2023, 44(01): 201-208.
[2]	郭敏, 王静安, 郭明瑞, 高卫东. 基于毛羽图像检测的浆纱抗起毛性能评价[J]. 纺织学报, 2022, 43(03): 78-82.
[3]	郭敏, 高卫东, 朱博, 刘建立, 郭明瑞. 模拟织造状态下的浆纱耐磨性能测试方法[J]. 纺织学报, 2021, 42(11): 46-50.
[4]	吕汉明, 王翔宇, 刘凤坤. 基于介电谱的醋酸酯水刺非织造布含水率估算[J]. 纺织学报, 2020, 41(06): 55-60.
[5]	汪风波, 王加毅, 孙正, 马颜雪, 吕迎智, 张魏峰, 吕艳, 吕明明, 陈思雨, 李毓陵, 陈小光. 聚丙烯酸酯浆料废水处理中试研究[J]. 纺织学报, 2019, 40(01): 108-113.
[6]	张希文武海良沈艳琴毛宁涛. 温湿度对涤/棉浆纱力学性能的影响[J]. 纺织学报, 2018, 39(06): 70-74.
[7]	李曼丽金恩琪连瑶瑶. 羽毛蛋白接枝共聚物对涤/棉经纱的上浆性能[J]. 纺织学报, 2017, 38(05): 75-79.
[8]	陈思邱夷平施楣梧蒋秋冉. 用于天然纤维素纤维纱线的无浆料浆纱技术[J]. 纺织学报, 2016, 37(2): 85-91.
[9]	金恩琪李曼丽张玲玲. 脂肪族单体结构对水溶性聚酯浆纱性能的影响[J]. 纺织学报, 2016, 37(06): 66-71.
[10]	张鲁燕李曼丽金恩琪. 接枝改性对羽毛蛋白浆料浆纱性能的影响[J]. 纺织学报, 2015, 36(08): 68-73.
[11]	向忠汝晶炜吴学进胡旭东. 电阻式织物回潮率测量装置的设计与应用[J]. 纺织学报, 2014, 35(6): 130-0.
[12]	田慧欣贾玉凤. 基于集成多支持向量回归融合的上浆率在线软测量方法[J]. 纺织学报, 2014, 35(1): 62-0.
[13]	葛璐金啸施勤崔建伟 . 细乳液聚合制备纳米SiO₂PSt及其对丙烯酸类浆料改性[J]. 纺织学报, 2012, 33(11): 66-71.
[14]	仲岑然;金春奎. 基于Gaussian拟合的浆纱横截面切片图像分析[J]. 纺织学报, 2011, 32(3): 57-60.
[15]	金恩琪;祝志峰;仇国际;李永虎. 水溶性聚酯浆料酯基结构对上浆性能的影响[J]. 纺织学报, 2008, 29(9): 72-74.