Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (07): 103-110.doi: 10.13475/j.fzxb.20240705501

• Textile Engineering • Previous Articles     Next Articles

Damage analysis and finite element simulation of wool yarn in warping

HAN Zhihui1, WAN Ailan1(), HONG Liang2, GAO Lizhong3, XIA Fenglin1   

  1. 1 College of Textile Science and Engineering, Jiangnan University, Wuxi, Jiangsu 214122, China
    2 Jiangyin Fubo Textile Co., Ltd., Wuxi, Jiangsu 214122, China
    3 Ordos Resources Co., Ltd., Ordos, Inner Mongolia 017099, China
  • Received:2024-07-23 Revised:2025-04-22 Online:2025-07-15 Published:2025-08-14
  • Contact: WAN Ailan E-mail:ailan.wan@jiangnan.edu.cn

RichHTML

6

PDF (PC)

58

Abstract:

Objective In order to study the damage of wool yarn in the process of warping for warp knitted fabrics, the study focused on the warping tension and the influence of machine parts on the hairiness index and mechanical properties of wool yarn, using the yarn leasing reed as an example, aiming to understand the damage of wool yarn during warping and provide insights for the utilization of wool yarn.

Methods Three types of compact Siro-spun yarns prepared from wool, cashmere, and nylon staple fibers were selected. The warping machine served as the experimental platform for sampling, testing, and analysis. The mechanical properties and hairiness index of the three types of yarns were tested before and after warping. A mathematical model was developed to analyze and predict the influence of warping tension on yarn performance based on the relationship between tension, yarn strength loss, and mass loss. The damage to wool yarn caused by warping tension, reed, and KFD yarn tension compensation brake was simulated and validated using finite element modeling.

Results Three types of wool yarn were tested after warping on the warping machine. These included yarn A (70% wool and 30% polyamide, 16.7 tex), yarn B (60% wool, 30% polyamide and 10% cashmere, 16.7 tex), and yarn C (60% wool, 30% polyamide and 10% cashmere, 12.5 tex) which were subjected to tight Siro spinning. The study revealed that the mechanical properties and hairiness index of the yarn were influenced by the friction between the reed of the warping machine and the yarn. Yarns A, B, and C experienced a decrease in strength by 12.0%, 10.7% and 8.2%, respectively. Additionally, due to shedding and the generation of new hairiness during continuous friction with the reed, the hairiness index fluctuated, leading to an overall weight decrease. During the warping process, if the yarn warping tension exceeded 30 cN and the elongation surpassed 0.8%, warping failure could occur due to hairiness aggregation, yarn entanglement and other factors. At the same time, the relationship between yarn strength, mass, and warping tension adhered to asymptotic, Boltzmann, and other mathematical models. Based on the model curve, it was deduced that when the warping tension was 20 cN and the warping speed was 300 m/min, the tension roller hole selection should be the second hole position; or when the warping speed was 400 m/min, the tension roller hole selection should be the first hole position. Under these conditions of warping tension and speed, both warping efficiency and quality could be guaranteed. By establishing the equivalent model of wool yarn, the finite element method was utilized to simulate the warping process and further investigate the damage of wool yarn. The simulation results were compared with the actual scenario to replicate the morphological changes of the yarn during warping and confirm the warping of the yarn under various tension and elongation conditions. This study provided a valuable experimental and theoretical foundation for examining short fiber yarn for warp knitting and exploring yarn damage during the warping process.

Conclusion The relationship between mechanical properties and hairiness index was established. According to the mathematical model, when the warping tension was 20 cN and the warping speed was 300 m/min, the tension roller hole selection was the second hole position, or when the warping speed was 400 m/min, the tension roller hole selection was the first hole position. Under these conditions, the weight loss and strength loss were kept minimal. By comparing the finite element modeling with test data, it was deduced that warping would be hindered when the warping tension exceeded 30 cN and the elongation surpassed 0.8% due to hairiness aggregation, yarn entanglement and the like. the like This method allowed for the preliminary screening of warping yarn, offering a theoretical foundation for the warping process.

Key words: warping damage, wool yarn, strength, hairiness, mathematical model, finite element simulation

CLC Number: 

  • TS184.3

Fig.1

Schematic diagram of yarn taking. (a) Schematic diagram of warping machine; (b) Yarn taker sampling; (c) Tension roll hole position"

Tab.1

Experimental design of wool yarn"

水平 纱线种类 张力辊孔位 整经速度/(m·min-1)
1 A 1 20
2 B 2 200
3 C 300
4 400

Tab.2

Setting of fiber length"

纤维种类 纤维直径/μm 纤维长度/mm
羊绒 15 30、40
羊毛 15 60、40
锦纶 15 60、80

Fig.2

Schematic of finite element simulation"

Fig.3

Effect of yarn reed on yarn strength"

Fig.4

Effect of yarn reed on three yarns hairiness. (a) Yarn A; (b) Yarn B; (c)Yarn C"

Tab.3

Effect of yarn reed on yarn mass g/km"

纱线
种类		 第1道
分纱筘		 第2道
分纱筘		 第3道
分纱筘		 第4道
分纱筘
纱线A 16.58 16.17 16.04 15.88
纱线B 16.49 16.39 16.31 15.47
纱线C 11.89 11.81 11.63 11.45

Tab.4

Effect of warping speed and tensionroll holeposition on warping tension"

整经速度/(m·min-1) 第1孔位张力/cN 第2孔位张力/cN
20 7 11
200 13 16
300 17 20
400 20 24

Fig.5

Relationship between warping tension and yarn strength and data fitting"

Fig.6

Relationship between warping tension and yarn mass and data fitting"

Tab.5

Material parameters"

纤维
种类		 密度/
(g·cm-3)		 断裂
伸长率/%		 弹性
模量/MPa		 泊松比
羊毛 1.34 10.0 2 300 0.24
羊绒 1.36 9.8 2 400 0.23
锦纶 1.39 4.0 3 500 0.37

Fig.7

Relationship between warping tension and yarn elongation"

Tab.6

Relationship between breaking strength and yarn elongation"

伸长率/% 断裂强力/cN
纱线A 纱线B 纱线C
0.00 11.71 12.47 12.73
0.10 13.99 14.37 14.37
0.20 16.26 16.45 16.72
0.30 18.63 18.68 18.98
0.40 21.05 20.90 21.10
0.50 23.45 23.16 23.46
0.60 25.88 25.42 25.72
0.70 28.33 27.66 27.96
0.80 30.75 29.91 29.99
0.90 33.16 32.17 32.37
1.00 35.57 34.43 34.58

Fig.8

Simulation of yarn warping at different tensions"

[1] 蒋高明, 程碧莲, 万爱兰, 等. 短纤纱经编织物生产关键技术研究进展[J]. 纺织学报, 2022, 43(5):7-11,31.
JIANG Gaoming, CHENG Bilian, WAN Ailan, et al. Research progress in key technologies of spun yarn warp knitting production[J]. Journal of Textile Research, 2022, 43(5):7-11,31.
[2] 许期颐, 陈英群. 为适应高机号经编机改造整经机的方法[J]. 针织工业, 2009(2):15-18.
XU Qiyi, CHEN Yingqun. In order to adapt to the method of reforming warping machine of high-grade warp knitting machine[J]. Knitting Industries, 2009(2):15-18.
[3] HAO G, WAN A. Evaluation of warp knitting and mechanical damage of staple fiber composite yarn[J]. Fibers and Polymers, 2023, 24(10): 3743-3751.
[4] MCGREGOR B A, POSTLE R. Worsted cashmere top and yarns blended with low or high curvature superfine merino wool[J]. Textile Research Journal, 2016, 77(10): 792-803.
[5] LIU X, MIAO X. Analysis of yarn tension based on yarn demand variation on a tricot knitting machine[J]. Textile Research Journal, 2016, 87(4): 487-497.
[6] 王卫, 张佩华, 杨淳, 等. 改善经编用羊毛纱线毛羽的途径[J]. 针织工业, 2009(3):20-22.
WANG Wei, ZHANG Peihua, YANG Chun, et al. Ways to improve wool yarn hairiness for warp knitting[J]. Knitting Industries, 2009(3): 20-22.
[7] MEENA H C, SHAKYAWAR D B, VARSHNEY R K. Low-stress mechanical properties of wool-cotton blended fabrics[J]. Journal of Natural Fibers, 2020, 19(1): 63-77.
[8] MEI D, XIA F, WAN A, et al. Damage characteristics of cotton yarn in high-speed warp-knitting processing from finite element simulation[J]. Fibers and Polymers, 2022, 23(10): 2952-2959.
[9] 谢春萍, 杨丽丽, 苏旭中, 等. 紧密赛络纺集聚效果及纱线结构分析[J]. 纺织学报, 2007, 28(3):9-12.
XIE Chunping, YANG Lili, SU Xuzhong, et al. Analysis of compact Siro spinning agglomeration effect and yarn structure[J]. Journal of Textile Research, 2007, 28(3):9-12.
[10] LU Y, WANG Y, GAO W. Strength distribution superiority of compact-Siro spun yarn[J]. Journal of Engineered Fibers and Fabrics, 2019.DOI:10.1177/1558925019827448.
[11] SRIPRATEEP K, BOHEZ E L J. A new computer geometric modelling approach of yarn structures for the conventional ring spinning process[J]. Journal of The Textile Institute, 2009, 100(3): 223-36.
[12] CYBULSKA M, GOSWAMI B C. Tensile behaviour of staple yarns[J]. Journal of The Textile Institute, 2001, 92(3): 26-37.
[13] MEI D, XIA F, WAN A, et al. Damage characteristics of cotton yarn in high-speed warp-knitting processing from finite element simulation fibers and polymers[J]. 2022, 23: 2952-2959.
[14] ZUBAIR M, NECKÁ$\stackrel{ˇ}{R}$ B, DAS D. Tensile behavior of staple fiber yarns: part II: model validation[J]. The Journal of The Textile Institute, 2016, 108(6): 931-934.
[1] YANG Tianqi, REN Jiazhi, WANG Xuzhen, CHEN Yuheng. Mathematical modeling and application of feeding ratios for multi-fiber combed fiber rolls [J]. Journal of Textile Research, 2025, 46(07): 62-68.
[2] GU Wenmin, JIANG Gaoming, ZHAO Junjie, LI Bingxian. Digital design and three-dimensional simulation of warp and weft knitted combined fabrics [J]. Journal of Textile Research, 2025, 46(07): 119-127.
[3] QIN Jianfeng, SHI Shuwei, MENG Yongfa, LI Menghui, XIA Bin. Influence of seed cotton humidification before ginning on cotton processing quality of machine harvested upland cotton in northern Xinjiang [J]. Journal of Textile Research, 2025, 46(06): 96-102.
[4] ZHANG Yi, SHEN Yin, GAO Jinxia, YU Chongwen. Aging properties of acoustic-absorbing composites from palm fiber [J]. Journal of Textile Research, 2025, 46(06): 127-134.
[5] CHEN Xinwei, GU Bingfei, TIAN Jiali, ZHOU Sifan, LIU Yuxi, LIU Jinling, YICK Kit-lun, SUN Yue. Optimization design method for sports bra using CAD/CAE technology [J]. Journal of Textile Research, 2025, 46(04): 162-170.
[6] YAO Yiting, AO Limin, ZHANG Zhanwang, SU Youpeng. Testing method of pile face properties for felting knitted wool fabrics [J]. Journal of Textile Research, 2025, 46(03): 100-108.
[7] SONG Wanmeng, WANG Baohong, SUN Yu, YANG Jiaxiang, LIU Yun, WANG Yuzhong. Preparation and performance of flame-retardant viscose fabrics with both mechanical and efficient flame-retardant properties [J]. Journal of Textile Research, 2025, 46(02): 188-196.
[8] WU Hao, ZHOU Chang'e, GAO Zhenqing, FENG Jiahe. Color stripping performance of cotton fabrics dyed with reactive dyes based on reduction-oxidation system [J]. Journal of Textile Research, 2024, 45(12): 128-136.
[9] XIAO Ningning, CHEN Zhijie, OUYANG Yufu, MENG Jingui, SUN Yangyi, QI Dongming. Preparation and characterization of waterborne flame retardant polyurethane for microfiber synthetic leather [J]. Journal of Textile Research, 2024, 45(09): 113-120.
[10] GUAN Songsong, JIANG Gaoming, YANG Meiling, LI Bingxian. Three-dimensional simulation of warp knitted pile fabrics with double needle bar based on loop structure [J]. Journal of Textile Research, 2024, 45(09): 84-90.
[11] CHEN Xiaoming, WU Kaijie, ZHENG Hongwei, ZHANG Jingyi, SU Xingzhao, XIN Shiji, GUO Dongsheng, CHEN Li. Mode I interlaminar mechanical behavior of needled/stitched multi-scale interlocking composites [J]. Journal of Textile Research, 2024, 45(08): 173-182.
[12] XU Jiahui, GUO Xiaoqing, WANG Wei, WANG Huaifang, ZHANG Chuanjie, GONG Zhaoqing. Preparation of alginate nano montmorillonite modified fiber and its strengthening and toughening mechanisms [J]. Journal of Textile Research, 2024, 45(06): 16-22.
[13] HE Fang, GUO Yan, HAN Chaoxu, LIU Mingshen, YANG Ruirui. Composite technology and properties of fabrics for automotive seat [J]. Journal of Textile Research, 2024, 45(05): 79-84.
[14] XIANG Zhong, ZHAO Wei, HE Shiwei, WANG Yuhang, QIAN Miao. Moisture content measurement technology of two-component fabrics by microwave resonant cavity method [J]. Journal of Textile Research, 2024, 45(04): 221-228.
[15] WU Jiaqing, HAO Xinmin, WANG Meihui, GUO Yafei, WANG Ying. Influence of roving performance on back drafting of ring spinning frame [J]. Journal of Textile Research, 2024, 45(04): 76-82.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd