Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (06): 46-52.doi: 10.13475/j.fzxb.20230701401

• Textile Engineering • Previous Articles     Next Articles

Structural control and spinning technology of highly wrapped core-spun yarn with thin sheath

LI Wenya(), ZHOU Jian, LIAO Tanqian, DONG Zhenzhen   

  1. School of Textile Science and Engineering, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
  • Received:2023-07-07 Revised:2024-01-09 Online:2024-06-15 Published:2024-06-15

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Abstract:

Objective The wrapped effect has always been the core indicator in the market to judge the quality of the core spun yarns. In the market, the number of the wrapped fiber is always more than 80% to achieve the core filament being wrapped. The difficulty in achieving good wrapping effect lies in controlling the center position of the core wire. It is of great theoretical significance and application value to achieve high wrapping effect of yarn based on low outer fiber ratio and stable control of yarn structure, thereby improving the multi-component advantage of core yarn.

Method To achieve high yarn wrapping effect and structural stability, this research proposed a solution by installing a filament control device to adjust the spinning process and parameters. Low-elastic polyester filament with a linear density of 7.78 tex as the core yarn, cotton roving with different quantities of as wrapping fibers were used to spin cotton/polyester core-spun yarn by ring spinning. The critical wrapping ratio of core-spun yarn was explored. The relationship between the structure of core-spun yarn and the wrapping rate was analyzed. The concept of yarn section eccentricity was introduced, and the structure stability of yarn was characterized by combining yarn coverage rate and longitudinal appearance morphology.

Results The relative position of the polyester filament and cotton roving was controlled by the installed a filament positioning device. The component ratios of polyester filament and cotton roving in 8 sets of core-spun yarns are 75/25, 70/30, 65/35, 60/40, 55/45, 53/47, 52/48, 50/50; The density of core-spun yarn is 31.8, 25.5, 21.6, 19, 17.4, 16.5, 16, and 15.7 tex, respectively. 50 images were collected for each group of yarn with 100 times magnification, and the obtained image was binary-processed by Ostu algorithm to calculate the yarn coating rate. Compared with other binary processing methods, the Ostu algorithm had the smallest error probability and higher accuracy. When the component ratio of cotton roving was 53%, the coverage rate of core-spun yarns remained at 87.5%. When the component ratio of cotton roving was less than 53%, the coverage rate of core-spun yarns was lower than 85% and a large area of core polyester was exposed. It is concluded that critical coverage ratio of core-spun yarn was when the component ratios of polyester filament and cotton roving was 53/47. The average variation range of eccentricity of core yarn section under different polyester-cotton ratios was 8.8%~11.2%. The characterization of section eccentricity, yarn coverage, and longitudinal appearance morphology verified the effectiveness of the spinning process adopted in this laboratory.

Conclusion The experiment provides data support and characterization for the discussion of the critical coverage rate during spinning cotton/polyester core-spun yarn by ring spinning. The computer image processing method for calculating the core-spun yarn coverage rate was obtained, which is convenient to operate and accurate. In addition, the factors affecting the stability of core yarn structure are analyzed from the perspective of theory and spinning practice, and the stable control of core-sheath structure is achieved by adjusting the spinning process.

Key words: polyester/cotton core-spun yarn, coverage rate, yarn structural, spinning technology, eccentricity, blending ratio

CLC Number: 

  • TS104.7

Fig.1

Schematic diagram of spinning path design"

Fig.2

Longitudinal Ostu binarization of core spun yarn with polyester to cotton ratio of 60 to 40(×100). (a) Appearance drawing; (b) Binarization diagram"

Fig.3

Cross-section eccentricity calculation"

Tab.1

Data table of core yarn coating ratio with differentcotton and polyester ratios"

组数 涤纶与棉
含量比		 外露面积/
μm2		 总面积/
μm2		 外露比/
%		 包覆率/
%
1# 75/25 5 184 954 681 0.54 99.46
2# 70/30 7 077 680 448 1.04 98.96
3# 65/35 9 576 839 928 1.14 98.86
4# 60/40 30 966 689 857 4.49 95.51
5# 55/45 63 805 733 815 8.69 91.31
6# 53/47 59 371 473 768 12.48 87.52
7# 52/45 139 099 670 761 20.74 79.26
8# 50/50 113 278 493 819 22.94 77.06

Fig.4

Yarn appearance(a) and binary treatment drawings(b) of spinning core yarn with different proportions of polyester and cotton components (×100)"

Fig.5

Section slice drawing of spinning core yarn with different proportions of polyester and cotton components (×200)"

Tab.2

Average eccentricity of yarns of different proportions"

组编
 涤纶与棉的
含量比		 纱线直径
R1/μm		 芯纱直径
R0/μm		 偏心度
γ/%
1# 75/25 365.75 20.50 11.207 50
2# 70/30 292.25 21.13 8.124 38
3# 65/35 282.38 13.88 9.753 75
4# 60/40 286.38 13.88 9.723 75
5# 53/47 294.25 11.75 8.008 75

Fig.6

Eccentricity of each cross-sectional of spinning core yarn with different proportions of polyester and cotton components"

[1] 李文雅. 基于环锭细纱机的彩色纺纱及其产品创新[J]. 纺织导报, 2021(4): 60-62.
LI Wenya. Color spinning and product innovation based on ring spinning machine[J]. Textile Herald, 2021(4): 60-62.
[2] 祝庆利, 曲翠平. 赛络纺棉/氨纶包芯纱纱疵成因及其预防措施[J]. 毛纺科技, 2020, 48(9): 25-29.
ZHU Qingli, QU Cuiping. Causes of Cello spun cotton/spandex core yarn defects and their preventive mea-sures[J]. Wool Textile Journal, 2020, 48(9): 25-29.
[3] 吴佳庆, 王迎, 郝新敏, 等. 长丝喂入位置对赛络纺包芯纱结构与性能影响[J]. 纺织学报, 2021, 42(8): 64-70.
WU Jiaqing, WANG Ying, HAO Xinmin, et al. Influence of filament feeding position on structure and performance of Cellon spinning core yarn[J]. Journal of Textile Research, 2021, 42(8): 64-70.
[4] 刘佳明, 李竹君, 宋业达, 等. 聚酰亚胺/间位芳纶短纤包芯纱工艺设计及性能测试[J]. 上海纺织科技, 2022, 50(2): 22-24.
LIU Jiaming, LI Zhujun, SONG Yeda, et al. Polyimide/metaaramid steven fiber core yarn process design and performance test[J]. Shanghai Textile Science and Technology, 2022, 50(2): 22-24.
[5] 丁明, 张申, 肖婷婷. 包芯纱最小包覆量计算及实例分析[J]. 天津纺织科技, 2019, (5): 45-48.
DING Ming, ZHANG Shen, XIAO Tingting. Calculation and case study of minimum cladding amount of core yarn[J]. Tianjin Textile Science and Technology, 2019(5): 45-48.
[6] 张海焕, 张毅, 童胜昊, 等. 牛仔布用多芯包芯纱强伸性能研究[J]. 棉纺织技术, 2023, 51(4): 53-56.
ZHANG Haihuan, ZHANG Yi, TONG Shenghao, et al. Study on the tensile properties of multi-core core yarn for denim[J]. Cotton Textile Technology, 2023, 51(4): 53-56.
[7] 孟召强, 冯建永. 环锭纺包芯纱包覆程度的研究[J]. 现代丝绸科学与技术, 2010, 25(3): 10-11, 14.
MENG Zhaoqiang, FENG Jianyong. Modern Silk Science and Technology, 2010, 25(3): 10-11, 14.
[8] 梁蓉, 林建华. 影响锦纶丝包芯纱包覆效果的主要因素[J]. 上海纺织科技, 2006(2): 15-17.
LIANG Rong, LIN Jianhua. The main factors affecting the coating effect of nylon silk core yarn[J]. Shanghai Textile Science and Technology, 2006(2): 15-17.
[9] OTSU N. A threshold selection method from gray-level histograms[J]. IEEE Transactions on Systems, Man, and Cybernetics, 1979, 9(1): 62-66.
[10] 芶小珊. 基于数字图像处理技术的条码图像二值化处理[J]. 无线互联科技, 2022, 19(23): 97-99.
QI Xiaoshan. Binarization of barcode image based on digital image processing technology[J]. Wireless Internet Science and Technology, 2022, 19(23): 97-99.
[11] ELRYS SAMAH M E, FAHEEM El Habiby Fawkia, ABD ELKHALEK Rehab, et al. Investigation into the effects of yarn structure and yarn count on different types of core-spun yarns[J]. Textile Research Journal, 2022, 92(13-14):2285-2297.
[12] 欧阳微微, 李艳清, 田伟, 等. 喷气涡流纺羊绒/涤纶混纺纱纤维径向分布[J]. 现代纺织技术, 2020, 28(1): 31-35.
OUYANG Weiwei, LI Yanqing, TIAN Wei, et al. Radial distribution of air-jet vortex cashmere/polyester blended yarn[J]. Modern Textile Technology, 2020, 28(1): 31-35.
[13] 李瑶, 陈超, 李杰, 等. 基于粗纱工序短纤皮芯结构纱的性能研究[J]. 棉纺织技术, 2022, 50(8):36-41.
LI Yao, CHEN Chao, LI Jie, et al. Study on the performance of staple fiber leather core structure yarn based on roving process[J]. Cotton Textile Technology, 2022, 50(8):36-41.
[14] 邹专勇, 缪璐璐, 董正梅, 等. 喷气涡流纺工艺对粘胶/涤纶包芯纱性能的影响[J]. 纺织学报, 2022, 43(8): 27-33.
ZOU Zhuanyong, MIAO Lulu, DONG Zhengmei, et al. Effect of jet vortex spinning process on the performance of viscose/polyester core yarn[J]. Journal of Textile Research, 2022, 43(8): 27-33.
[15] 张媛. 几种短粗节纱疵的成因及控制实例解析[J]. 棉纺织技术, 2022, 50(3): 68-71.
ZHANG Yuan. Analysis of the causes and control examples of several short roving yarn defects[J]. Cotton Textile Technology, 2022, 50(3): 68-71.
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