纺织学报 ›› 2023, Vol. 44 ›› Issue (12): 58-66.doi: 10.13475/j.fzxb.20220504601

• 纺织工程 • 上一篇    下一篇

毛纱/锦纶长丝包覆纱的纺制及其性能与应用

贾冰凡1, 敖利民1,2(), 唐雯3, 郑元生4, 尚珊珊4   

  1. 1.嘉兴学院 材料与纺织工程学院, 浙江 嘉兴 314001
    2.浙江省纱线材料成形与复合加工技术研究重点实验室, 浙江 嘉兴 314001
    3.嘉兴学院 商学院, 浙江 嘉兴 314001
    4.上海工程技术大学 纺织服装学院, 上海 201620
  • 收稿日期:2022-05-16 修回日期:2022-08-05 出版日期:2023-12-15 发布日期:2024-01-22
  • 通讯作者: 敖利民(1969—),男,教授,博士。主要研究方向为纺织新工艺、新技术与新产品。E-mail:aolimin@126.com
  • 作者简介:贾冰凡(2000—),女。主要研究方向为纱线复合加工技术。
  • 基金资助:
    浙江省重点实验室开放基金项目(MTC-2022-01)

Processing of wool yarn/polyamide filament covered yarns and their properties and applications

JIA Bingfan1, AO Limin1,2(), TANG Wen3, ZHENG Yuansheng4, SHANG Shanshan4   

  1. 1. College of Materials and Textile Engineering, Jiaxing University, Jiaxing, Zhejiang 314001, China
    2. Zhejiang Key Laboratory of Yarn Material Forming and Composite Processing Technology Research, Jiaxing, Zhejiang 314001, China
    3. College of Business, Jiaxing University, Jiaxing, Zhejiang 314001, China
    4. School of Textiles and Fashion, Shanghai University of Engineering Science, Shanghai 201620, China
  • Received:2022-05-16 Revised:2022-08-05 Published:2023-12-15 Online:2024-01-22

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摘要:

为改善毛纱结构蓬松、毛羽多等问题,探讨包缠复合对其性能的影响,以开发毛纱包覆纱及其面料产品。以26.3 tex黑色毛纱为芯纱,44.4 dtex(34 f)锦纶6白色全拉伸长丝纱外包缠纱,纺制了4种捻度的单包包覆纱和交叉包缠双包包覆纱;对2类包覆纱的外观和结构进行了分析,并对其拉伸性能、毛羽、条干与纱疵进行了测试与比较,对毛纱包覆加工的应用进行了探讨。结果表明:包覆纱呈芯纱和外包缠纱颜色的混色外观;单包包覆纱捻度分布不匀,粗节处捻度小,细节处捻度大;单包包覆纱存在2次断裂特征,包缠捻度越大,2次断裂的频次越少;包覆纱的断裂强度大于毛纱,且双包包覆纱的断裂伸长率大于单包包覆纱;包覆纱的断裂伸长率相较毛纱有显著提高,且双包包覆纱优于单包包覆纱;包缠复合可显著降低毛纱的毛羽,改善毛纱条干,减少纱疵。

关键词: 毛纱, 包覆纱, 包覆工艺, 单包, 双包, 复合结构, 纱线性能, 锦纶长丝

Abstract:

Objective There are some performance defects in wool yarn itself, such as low breaking strength and excessive yarn hairiness, which affect its processability and fabric wearability, for example, low strength makes it unable to withstand larger weaving tension, and excessive hairiness leads to yarn entanglement during weaving and fabric pilling. This article explores the feasibility of using filament yarn to wrap wool yarn by hollow spindle covering to improve its processability and fabric wearability, as well as the impact of the main wrapping process on the technical effect, aiming at providing reference for the development of covered wool yarn and its fabric products.
Method Four twist levels of single-covered and cross-wrapped double-covered composite yarns were applied to the yarns using the hollow spindle covering machine, where 26.3 tex black wool worsted yarn was used as the core yarn, and 44.4 dtex(34 f) polyamide white Fully-Drawn-Yarn(FDY)filament yarn was used as the outer wrapping yarn. The structure of the two types of composite yarns were observed by magnification, the tensile properties, hairiness, evenness and yarn defects were tested according to corresponding standards and comparatively analyzed, and the application of wool yarn covering processing was discussed.
Results The spinning principle of single-covered and double-covered yarn were shown (Fig. 1), and the structure models of the two types of covered yarn were given correspondingly (Fig. 2), as well as the partial enlarged views of the two types of composite yarns(Fig. 3), so as to observe and compare their composite structures. The package appearance (Fig. 4) and the photos of the yarn card (Fig. 5) of the two types of composite yarns were presented respectively to show the appearance characteristics. A partial enlarged picture of 750 twists/m single covered yarn was provided (Fig. 6) for presenting the obvious twist irregularity of single covered composite yarn. In order to compare and analyze the influence of covering processing and its parameters on the tensile performance of the wool yarns, the total tensile fracture curves of 50 times of polyamide wrapped yarn(Fig. 7(a)), wool core yarn (Fig. 7(b)), four twist levels were applied to the single-wrapped composite yarn (Fig. 8) and the typical double-wrapped composite yarn (Fig. 9), and the tensile strength of all raw yarns, single-covered yarns and double-covered yarns were listed (Tab. 1), including breaking strengths/tenacities and their CV value, break elongations and their CV value, and the failure of the core and cover yarns. The hairiness test results of the wool yarn and two type of composite yarn were exhibited (Tab. 2), and the test results for evenness and yarn defects were provided (Tab. 3). The performance changes of composite yarn compared with the wool yarn and the influence of different twist configurations were compared and analyzed, and based on this, the industrial application and requirements of wool yarn covering processing were discussed.
Conclusion The composite yarn has a mixed color appearance of the color of core yarn and outer wrapping yarn. The single-covered composite yarn has the characteristics of uneven distribution of twist, the twist on the thick place is smaller, and the twist on the thin place is larger. The breaking strength of the composite yarn is greater than that of the wool yarn, and the double-covered yarn is greater than the single-covered yarn. The elongation at break of the composite yarn is significantly higher than that of the wool yarn, and the double-covered yarn is greater than that of the single-covered yarn. The covering composite yarns can significantly reduce the hairiness of wool yarn and improve wool yarn evenness and reduce yarn defects. Taking wool yarn as the core yarn, reasonably selecting the type and specification of wrapping yarn and the covering process can improve the processability of wool yarn and change the style and performance of fabric products.

Key words: wool yarn, covered yarn, covering process, single-covered, double-covered, composite structure, yarn property, polyamide filament

中图分类号: 

  • TS104.1

图1

包覆纺纱工艺原理 1—芯纱卷装; 2—导纱钩; 3—张力器; 4—空心锭; 5—锭管;6—外包缠纱; 7—汇合导纱钩; 8—引纱辊; 9—导纱杆;10—横动导纱器; 11—卷绕辊; 12—成纱筒子。"

图2

包覆纱的结构模型"

图3

包覆纱的结构"

图4

包覆纱的筒纱外观"

图5

包覆纱的纱卡照片"

图6

捻度为750 捻/m单包包覆纱的局部放大照片"

图7

2种原料纱的50次拉伸全曲线"

图8

不同捻度单包包覆纱的50次拉伸全曲线"

图9

双包包覆纱的50次拉伸全曲线"

表1

拉伸断裂指标测试结果"

纱线种类 捻度/
(捻·m-1)		 捻度比 断裂强
力/cN		 断裂强力
CV值/%		 断裂强度/
(cN·tex-1)		 强力利
用率/%		 断裂伸
长率/%		 伸长率
CV值/%		 2次断裂
次数
毛纱原纱 272.14 5.93 10.34 10.14 8.41
锦纶6长丝 205.98 2.36 46.35 35.86 4.70
单包包覆纱 375 436.70 6.47 14.20 0.91 12.82 10.87 32
500 443.22 6.83 14.41 0.93 13.19 9.64 15
600 435.80 5.80 14.17 0.91 12.99 8.86 11
750 431.62 6.11 14.03 0.90 13.60 10.35 2
双包包覆纱 375:300 605.28 3.93 17.19 0.88 15.31 6.81
500:400 606.24 3.92 17.22 0.89 16.40 6.87
600:480 595.42 4.14 16.91 0.87 16.44 7.85
750:600 583.94 4.28 16.59 0.85 17.24 7.05

表2

毛羽测试结果"

纱线种类 捻度/
(捻·m-1)		 捻度比 不同长度毛羽数/(根·m-1)
1 mm 2 mm 3 mm 4 mm 5 mm 6 mm 7 mm 8 mm
毛纱原纱 218.98 77.24 29.88 12.5 5.92 2.87 1.34 0.71
单包包覆纱 375 129.65 25.56 6.27 1.97 0.67 0.34 0.11 0.07
500 103.44 17.13 3.55 0.85 0.23 0.07 0.07 0.05
600 89.18 12.96 2.53 0.83 0.21 0.05 0.00 0.00
750 71.72 10.23 1.98 0.52 0.05 0.05 0.03 0.02
双包包覆纱 375:300 80.08 11.42 2.18 0.43 0.15 0.02 0.00 0.01
500:400 56.82 6.13 1.12 0.17 0.03 0.00 0.01 0.03
600:480 46.10 5.50 0.87 0.18 0.03 0.01 0.01 0.01
750:600 41.65 5.15 0.88 0.17 0.01 0.02 0.00 0.02

表3

条干与纱疵测试结果"

纱线种类 捻度/
(捻·m-1)		 捻度比 CV值/% 细节(-50%)/
(个·km-1)		 粗节(+50%)/
(个·km-1)		 毛粒(+200%)/
(个·km-1)
毛纱原纱 21.27 47 52 48
单包包覆纱 375 17.11 9 17 20
500 17.49 11 25 18
600 18.41 9 25 26
750 18.46 5 38 27
双包包覆纱 375:300 16.15 4 11 10
500:400 14.99 0 8 8
600:480 15.20 0 7 5
750:600 15.27 0 6 5
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