Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (02): 78-85.doi: 10.13475/j.fzxb.20240907501

• Textile Engineering • Previous Articles     Next Articles

Performance analysis of embedded low-torque composite yarns based on self-twisting spinning

ZHANG Ruicheng1,2, ZHANG Wenqing1,2, LÜ Zhe1,2, XU Duo2, LIU Keshuai1,2(), XU Weilin2   

  1. 1. College of Textile Science and Engineering, Wuhan Textile University, Wuhan, Hubei 430200, China
    2. State Key Laboratory of New Textile Materials and Advanced Processing, Wuhan Textile University, Wuhan, Hubei 430200, China
  • Received:2024-09-29 Revised:2024-10-21 Online:2025-02-15 Published:2025-03-04
  • Contact: LIU Keshuai E-mail:liukeshuai89@163.com

RichHTML

27

PDF (PC)

28

Abstract:

Objective The yarn quality produced from a single component often faces limitations imposed by the material itself. These limitations can be addressed by utilizing a combination of multiple materials to enhance the performance. Composite yarns are typically manufactured using methods such as ring spinning, which results in high twist rates and substantial residual torque. These factors contribute to an increased number of kinks which necessitates additional processes to reduce residual torque, thereby incurring higher time and resource costs. In contrast, self-twisting spinning leverages the principle of de-twisting during yarn formation, naturally reducing residual torque and offering significant research potential.

Method This study utilized a composite filament approach to investigate the properties of self-twisted yarns, aiming to control the yarn structure and produce low-torque, high-quality composite yarns. Wool fiber and nylon filament served as the raw materials, the improved S300 self-twist spinning system was used for large-scale manufacture of embedded in-phase self-twisted yarns and heterogeneous self-twisted yarns. A stress analysis was conducted on the in-phase self-twisted yarns to examine the influence of the angle and spacing of the embedded filaments on the self-twist torque of the composite yarns. Additionally, the effects of filament and roving spacing on the yarn formation performance of both types of self-twisted yarns were analyzed.

Results Eight groups of spun yarns were rigorously tested using 3-D microscope, evenness tester, hairiness tester, strength tester, and hanging kink test. When the spacing between the filament and the roving was set at 0 mm, the resulting yarns formed a core structure, exhibiting poor quality due to uncontrolled hairiness. At a spacing of 2 mm, the yarns became wrapped yarns, in which the filament exerted inward pressure on the fibers to control the surface fibers and enhance internal strength. This configuration provided optimal strength and evenness properties, validating the effectiveness of the compound twisting followed by retwisting yarn formation scheme. As the spacing between the filament and roving increased, the orientation of the filament was decreased, leading to improvement of the wrapping effect on the fibers and enhancement of the surface hairiness control. However, the filament struggled to maintain internal tensile resistance, resulting in a gradual decline in strength. Furthermore, an increase in the self-twisting torque of the embedded composite self-twisted yarns led to non-uniform twisting distribution, adversely affecting the yarn evenness. When the spacing became excessively large, the filament and roving could not effectively compound under the grip of the twisting roller. On the contrary, they converged at the hook, resulting in a unique yarn formation structure characterized by an initial twist followed by a retwist. In this specific configuration, referred to as Scheme D, both filaments periodically migrated toward the same side. During half a twist cycle, the left filament moved away from the fibers while the right filament remained close, causing the right single yarn to wrap around the yarn body and form a composite single yarn. The left single yarn twisted with the composite yarn, but the filament could not regulate the internal and external transfer of fibers effectively.

Conclusion The embedded self-twisted yarns significantly reduced the residual torque to below one kink in composite yarns. The optimal configuration for achieving superior tensile properties and yarn structure was identified at a filament-roving spacing of 2 mm. In comparison, heterogeneous self-twisted yarns exhibited better evenness and tensile properties than the homogeneous self-twisted yarns. Therefore, the heterogeneous self-twisting spinning method is preferred in practical production. When the spacing between filament and roving exceeded 6 mm, achieving a tensile homophase self-twisted yarns displayed a unique structure with both core and wrapped characteristics, achieving a strength of 7.39 cN/tex, surpassing that of close heterogeneous self-twisted yarns.

Key words: self-twisting spinning, embedded composite yarn, low torque, yarn structure model, yarn property

CLC Number: 

  • TS104.7

Tab.1

Preparation scheme of 30.5 tex embedded composite self-twisting yarn"

方案编号 成纱方案 长丝与粗纱间距/mm
A 复合搓捻-退捻同相自捻纱 0
B 复合搓捻-退捻同相自捻纱 2
C 复合搓捻-退捻同相自捻纱 4
D 独立搓捻-退捻同相自捻纱 6
E 复合搓捻-退捻异相自捻纱 0
F 复合搓捻-退捻异相自捻纱 2
G 复合搓捻-退捻异相自捻纱 4
H 独立搓捻-退捻异相自捻纱 6

Fig.1

Models of embedded composite self-twisting yarns with different yarn formation methods"

Fig.2

Schematic of self-twisting yarn production process"

Fig.3

Stress schematic of embedded homophase composite self-twisting yarns"

Fig.4

Apparent morphology images of embedded composite self-twisting yarns. (a) Micrographs of self-twisting yarns with different yarn formation methods; (b) Enlarged image of yarn YD micrograph; (c) Micrographs of homophase self-twisting yarn and heterophase self-twisting yarn in untwisted zone"

Tab.2

Tensile properties of different embedded composite self-twisting yarns"

纱线
编号		 断裂强度/
(cN·tex-1)		 断裂强度
CV值/%		 断裂伸
长率/%		 断裂伸长率
CV值/%
YA 6.54 4.39 10.42 12.24
YB 6.63 6.01 9.03 17.81
YC 6.44 7.48 7.63 15.45
YD 7.39 6.14 8.31 14.42
YE 8.89 8.57 11.31 12.55
YF 9.79 7.32 14.82 10.26
YG 7.53 5.05 8.38 13.32
YH 7.38 7.22 7.32 10.12

Tab.3

Evenness of different embedded composite self-twisting yarns"

纱线
编号		 条干CV
值/%		 细节(-50%)/
(个·km-1)		 粗节(+50%)/
(个·km-1)		 毛结(+200%)/
(个·km-1)
YA 24.61 1 070 480 10
YB 20.93 280 270 20
YC 21.10 260 240 30
YD 22.50 400 220 70
YE 22.36 540 220 10
YF 19.16 150 120 30
YG 20.87 310 240 70
YH 21.63 350 170 30

Tab.4

Hairiness number of different embedded composite self-twisting yarns"

纱线
编号		 不同长度的毛羽数量/(根·10 m)-1)
1 mm 2 mm 3 mm 4 mm 5 mm 6 mm 8 mm 10 mm ≥3 mm
YA 1 555 448 173 93 54 37 33 5 394
YB 996 280 102 57 35 17 6 2 220
YC 567 121 47 20 10 9 8 2 96
YD 555 124 43 20 10 5 9 0 86
YE 1 198 314 140 76 48 32 37 4 338
YF 1 122 295 119 55 35 13 3 0 225
YG 701 186 76 26 14 13 8 1 139
YH 577 79 32 18 7 3 5 1 66

Fig.5

Comparison of snarlings for embedded composite self-twisting yarns"

[1] ERBIL Y, ISLAM R, BABAARSLAN O, et al. Effect of structural changes on the cotton composite yarn properties[J]. Journal of Natural Fibers, 2022, 19(5): 1899-1907.
[2] 贾冰凡, 敖利民, 唐雯, 等. 毛纱/锦纶长丝包覆纱的纺制及其性能与应用[J]. 纺织学报, 2023, 44(12): 58-66.
doi: 10.13475/j.fzxb.20220504601
JIA Bingfan, AO Limin, TANG Wen, et al. Spinning, proper-ties and application of woolen/nylon filament covered yarn[J]. Journal of Textile Research, 2023, 44(12): 58-66.
doi: 10.13475/j.fzxb.20220504601
[3] 胡铖烨, 缪润伍, 韩潇, 等. 聚乙烯醇对芳纶复合纱聚苯胺导电层耐久性影响[J]. 纺织学报, 2020, 41(4): 91-97.
HU Chengye, MIAO Runwu, HAN Xiao, et al. Effect of polyvinyl alcohol on the durability of polyaniline conduc-tive layer of aramide composite yarn[J]. Journal of Textile Research, 2019, 41(4): 91-97.
[4] 吕立斌, 杜梅. 涤棉丝Sirofil复合纱的结构与性能[J]. 棉纺织技术, 2009, 37(12): 17-20.
LV Libin, DU Mei. Structure and properties of poly-cotton silk Sirofil composite yarn[J]. Cotton Textile Technology, 2009, 37 (12): 17-20.
[5] 付驰宇, 王灿灿, 何满堂, 等. 接触式简易嵌入纺技术及其苎麻纱性能[J]. 纺织学报, 2019, 40(1): 40-45.
FU Chiyu, WANG Cancan, HE Mantang, et al. Contact simple embedded spinning technology and properties of ramie yarn[J]. Journal of Textile Research, 2019, 40(1): 40-45.
[6] PHILLIPS D G. Torque due to ap-plied tension in ring-spun yarns[J]. Textile Research Journal, 2008, 78(8): 671-681.
[7] 朱明娟, 高亚英, 吴丽莉, 等. Tencel纱线的扭转定形研究[J]. 东华大学学报(自然科学版), 2004(5): 115-119.
ZHU Mingjuan, GAO Yaying, WU Lili, et al. Study on torsion setting of tencel yarn[J]. Journal of Donghua University (Natural Science Edition), 2004 (5): 115-119.
[8] 王玲玲, 杨昆, 蒋跃东. 纱线残余扭矩对纬平针织物线圈歪斜的影响[J]. 针织工业, 2012(11): 22-23.
WANG Lingling, YANG Kun, JIANG Yuedong. Effect of yarn residual torque on coil skew of weft plain knitted fabric[J]. Knitting Industries, 2012(11): 22-23.
[9] 邹专勇, 虞美雅, 陈建勇, 等. 低扭矩环锭柔软纱加工现状与假捻技术的应用[J]. 现代纺织技术, 2018, 26(3): 89-92.
ZOU Zhuanyong, YU Meiya, CHEN Jianyong, et al. Processing status of soft yarn with low torque ring spindle and application of false twist technology[J]. Advanced Textile Technology, 2018, 26(3): 89-92.
[10] TAO X M, LO W K, LAU Y M. Torque-balanced singles knitting yarns spun by unconventional systems:1: cotton rotor spun[J]. Textile Research Journal, 1997, 67(10): 739-746.
[11] 宋伟, 程隆棣. 强捻棉纱蒸纱实践[J]. 纺织科技进展, 2010(1): 52-54.
SONG Wei, CHENG Longdi. Steaming practice of strongly twisted cotton yarn[J]. Progress in Textile Science & Technology, 2010(1): 52-54.
[12] 陈桂亮, 王建坤, 胡艳丽, 等. 纯棉股线定形工艺优选[J]. 棉纺织技术, 2019, 47(1):72-74.
CHEN Guiliang, WANG Jiankun, HU Yanli, et al. Preferred shaping process for cotton stranded yarn[J]. Cotton Textile Technology, 2019, 47(1): 72-74.
[13] 贾伟, 陈南梁, 傅婷. 金属钼丝并线过程中残余扭矩的研究[J]. 产业用纺织品, 2011, 29(6): 22-25.
JIA Wei, CHEN Nanliang, FU Ting. Research on residual torque of molybdenum wire during wire mer-ging[J]. Technical Textiles, 2011, 29 (6): 22-25.
[14] 陶肖明, 郭滢, 冯杰, 等. 低扭矩环锭纺纱原理及其单纱的结构和性能[J]. 纺织学报, 2013, 34(6): 120-125.
TAO Xiaoming, GUO Ying, FENG Jie, et al. Spinning principle of low torque ring spindle and structure and properties of single yarn[J]. Journal of Textile Research, 2013, 34(6): 120-125.
[15] 任纪忠, 贾云辉, 张庆法. 环锭纺加捻三角区对成纱品质的影响探讨[J]. 纺织导报, 2022(5): 67-70.
REN Jizhong, JIA Yunhui, ZHANG Qingfa. Influence of twist triangle on yarn quality in ring spinning[J]. China Textile Leader, 2022(5):67-70.
[16] 崔红, 肖志永, 郁崇文. 自捻纱纺纱速度对自捻捻度的影响[J]. 毛纺科技, 2011, 39(4): 29-32.
CUI Hong, XIAO Zhiyong, YU Chongwen. Effect of spinning speed on twist of self-twist yarn[J]. Wool Textile Journal, 2011, 39(4): 29-32.
[17] 宣金彦. 自捻纺成纱机理研究[D]. 上海: 东华大学, 2014:12-42.
XUAN Jinyan. Research on mechanism of self-twist spinning yarn[D]. Shanghai: Donghua University, 2014:12-42.
[18] 崔红. 自捻纺纱纱线结构及其力学性能研究[D]. 上海: 东华大学, 2012:20-31.
CUI Hong. Research on structure and mechanical properties of self-twist spun yarns[D]. Shanghai: Donghua University, 2012:20-31.
[19] 崔红, 高秀丽, 高大伟, 等. 不同汇合方式自捻纱的捻度分布[J]. 河南工程学院学报(自然科学版), 2016, 28(2): 1-5.
CUI Hong, GAO Xiuli, GAO Dawei, et al. Twist distribution of self-twisted yarn with different confluence methods[J]. Journal of Henan University of Engineering (Natural Science Edition), 2016, 28(2): 1-5.
[20] 北京纺织科学研究所. 自捻纺纱技术知识问答:四[J]. 棉纺织技术, 1977(9): 51-53.
Beijing Textile Research Institute. Questions and answers on self-twist spinning technology: IV[J]. Cotton Textile Technology, 1977(9): 51-53.
[21] 王兟, 张知佑. 自捻捻度与纤维条捻度之间理论关系的论证[J]. 纺织学报, 1987, 8(11): 691-694.
WANG Shen, ZHANG Zhiyou. Demonstration of the theoretical relationship between self-twist twist and fiber twist[J]. Journal of Textile Research, 1987, 8(11): 691-694.
[1] SHI Jingjing, YANG Enlong. Effect of advance-feeding on structure and performance of cotton/wool segment colored yarns [J]. Journal of Textile Research, 2024, 45(12): 67-73.
[2] JIA Bingfan, AO Limin, TANG Wen, ZHENG Yuansheng, SHANG Shanshan. Processing of wool yarn/polyamide filament covered yarns and their properties and applications [J]. Journal of Textile Research, 2023, 44(12): 58-66.
[3] MIAO Lulu, DONG Zhengmei, ZHU Fanqiang, RONG Hui, HE Linwei, ZHENG Guoquan, ZOU Zhuanyong. Influence of core filament type and delivery speed on performance of air-jet vortex spun core-spun yarns [J]. Journal of Textile Research, 2023, 44(12): 50-57.
[4] SHI Jingjing, YANG Enlong. Analysis of structure and properties of cotton/wool siro segment colored yarns [J]. Journal of Textile Research, 2023, 44(03): 55-59.
[5] MIAO Ying, XIONG Shiman, ZHENG Minbo, TANG Jiandong, ZHANG Huixia, DING Cailing, XIA Zhigang. Effect of high smooth treatment on polyimide staple yarns and its fabric properties [J]. Journal of Textile Research, 2023, 44(02): 118-127.
[6] LÜ Jindan, CHENG Longdi. Influence of groove shape on flow field and yarn properties of compact spinning [J]. Journal of Textile Research, 2023, 44(01): 188-193.
[7] ZOU Zhuanyong, MIAO Lulu, DONG Zhengmei, ZHENG Guoquan, FU Na. Effect of air-jet vortex spinning process on properties of viscose/polyester core-spun yarns [J]. Journal of Textile Research, 2022, 43(08): 27-33.
[8] XU Duo, WEI Jiang, MEI Jianxiang, ZHANG Xinling, ZHANG Youqing, XU Weilin, LIU Keshuai. Properties of soft-spun viscose hard-twist yarn and fabric thereof [J]. Journal of Textile Research, 2019, 40(10): 48-55.
[9] AO Limin, TANG Wen, WANG Ailin. Appearance and performance of linen/colored polyester wrapping composite yarn [J]. Journal of Textile Research, 2019, 40(08): 40-47.
[10] FU Chiyu, WANG Cancan, HE Mantang, XIA Zhigang. Contact spinning based on simplified embeddable and locatable system and properties of spun ramie yarn [J]. Journal of Textile Research, 2019, 40(01): 40-45.
[11] . Structure and performances of double channel digital ring spinning melange yarn [J]. Journal of Textile Research, 2018, 39(11): 27-32.
[12] . Influence of filament distribution pattern on properties of composite yarns [J]. JOURNAL OF TEXTILE RESEARCH, 2017, 38(09): 32-39.
[13] .  Spinning principle, structure and properties of low torque ring spun yarns [J]. JOURNAL OF TEXTILE RESEARCH, 2013, 34(6): 120-125.
[14] FU Jiang. Analysis of three basic parameters of the false-twist compact spinning method [J]. JOURNAL OF TEXTILE RESEARCH, 2011, 32(5): 38-42.
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