纺织学报 ›› 2024, Vol. 45 ›› Issue (04): 76-82.doi: 10.13475/j.fzxb.20220805101

• 纺织工程 • 上一篇    下一篇

粗纱物理特性对环锭纺细纱机后区牵伸效果影响

吴佳庆1, 郝新敏2, 王美慧2, 郭亚飞2, 王迎1()   

  1. 1.大连工业大学 纺织与材料工程学院, 辽宁 大连 116034
    2.军事科学院 系统工程研究院, 北京 100084
  • 收稿日期:2022-08-16 修回日期:2022-11-10 出版日期:2024-04-15 发布日期:2024-05-13
  • 通讯作者: 王迎(1976—),女,教授,博士。主要研究方向为纺纱技术。E-mail:wangying@dlpu.edu.cn。
  • 作者简介:吴佳庆(1994—),男,硕士生。主要研究方向为新型纺织技术。
  • 基金资助:
    国家自然科学基金项目(U1808211);辽宁省重大科技专项项目(2019JH1/10100010)

Influence of roving performance on back drafting of ring spinning frame

WU Jiaqing1, HAO Xinmin2, WANG Meihui2, GUO Yafei2, WANG Ying1()   

  1. 1. School of Textile and Material Engineering, Dalian Polytechnic University, Dalian, Liaoning 116034, China
    2. Systems Engineering Research Institute, Academy of Military Science, Beijing 100084, China
  • Received:2022-08-16 Revised:2022-11-10 Published:2024-04-15 Online:2024-05-13

摘要:

为探究粗纱在细纱后区的形态变化和粗纱物理特性能对细纱后区牵伸效果的影响,以不同粗纱定量、捻度和纤维长度的粗纱为例,分析粗纱截面纤维分布、粗纱定量和捻度等物理特性对粗纱拉伸强力影响、粗纱须条在牵伸区的变化以及基于等长切断称重法分析牵伸效果。结果表明:在牵伸过程中粗纱须条截面从圆形变成扁平带状后又恢复成一定紧密度的类圆形;粗纱定量为450 g/(10 m),捻度为4.01和4.48捻/m的粗纱力学性能好,利用粗纱捻回产生的附加摩擦力界能有效控制纤维的运动,牵伸区内纤维变速点集中,牵伸效果好;大定量粗纱受罗拉胶辊差速影响易发生纤维分层,纤维变速点分散,需加大罗拉钳口压力予以改善;后区牵伸倍数在1.10~1.36倍以内,有利于牵伸稳定。

关键词: 后区牵伸, 粗纱须条运动, 粗纱强力, 纤维变速点分布, 等长切断称重法

Abstract:

Objective The purpose of this paper is to explore the shape change of roving whisker in the back drafting area of spinning frame and the influence of roving performance on the drawing effect of the back drafting area of spinning frame. It has certain beneficial effect for producers to set the roving production process and optimize the spinning production parameters.

Method In this research, polyester fiber (1.67 dtex×38 mm) and viscose fiber (1.67 dtex×51 mm) were used as raw materials to prepare roving samples with different roving weights, roving twist and fiber length. The roving section was observed by resin embedding method, and the roving mechanical properties were measured by stretching method. The drawing experiment was carried out on the digital spinning machine SSP-01 to observe the shape change of the roving whisker and cut off the drawing sample. The drawing effect of the back area of the spinning yarns was analyzed, based on the isometric cutting and weighing method.

Results The section of roving whiskers in the rear drafting area was round at first, became a flat ribbon after extrusion by roller pliers, and then gradually shirked and recovered to a circular shape with a certain tightness. Roving (450 tex, 4.01 twist/m or 4.48 twist/m) had better mechanical properties than another samples. The additional friction boundary generated by roving twist back was found to control effectively the movement of fibers, so that the fiber accelerated points was concentrated and close to the clamp mouth of the middle roller, and the drafting effect was stable. The variation of roving strength indirectly proved that the roving strength was better at the twist of 4.01 twist/m and 4.48 twist/m, indicating that the additional friction boundary generated by roving twist back could effectively control the fiber movement. The drafting effect of 350 tex roving whisker met the draft requirement of concentration of the fiber accelerated point and as close as possible to the jaws of the middle roller when the draft multiple of the back area was 1.1 times and the draft spacing was 50 mm. However, under the same drafting conditions, the fiber accelerated points of 600 tex roving fiber was in region Ⅰ, even earlier, which seriously affect yarn quality. Furthermore, without increasing the pressure of the roller, the high weight of the roving was not conducive to the drafting of the roving, while the speed difference between fast fiber and slow fiber leads to more and more obvious delamination behavior with the increase of roving weight. At small drafting multiples (1.10 times and 1.22 times), the fiber weight ratio of each block in the whole post-drafting area changed slightly, indicating that only a small relative displacement occurred between fibers. When the draft ratio was 1.36 times, the fiber weight ratio of each block decreased greatly, indicating that the fiber accelerating points occurred earlier. Even at large draft multiples (1.50 and 1.65 times), the proportion of fiber weight was decreased sharply between zone Ⅲ and zone Ⅳ, indicating that the relative displacement between fibers was too large, resulting in draft instability.

Conclusion The shape of the roving whisker section was constantly changing during the drafting process in the back area, which was accompanied by a slight twist redistribution. The additional friction boundary created by roving twist can effectively control the movement of the fiber, so that the fiber accelerated points were concentrated and closed to the jaws of the middle roller, which was beneficial to the stable drafting. In addition, the small weight of roving facilitated stable drafting. As for heavy roving, it was recommended to increase the roller pressure and roving twist to control fiber movement. The draft factor of the back area should be small, within 1.10 to 1.36 times was appropriate.

Key words: back draft, roving whisker movement, roving strength, distribution of fiber accelerated point, isometric cutting and weighing method

中图分类号: 

  • TS104.1

表1

粗纱样品参数"

原料 样品
编号
定量/
(g·(10 m)-1)
捻度/
(捻·m-1)
涤纶粗纱 T1 3.50 3.06
T2 4.00 3.06
T3 4.50 3.06
T4 5.20 3.06
T5 6.00 3.06
T6 4.50 3.54
T7 4.50 4.01
T8 4.50 4.48
粘胶纤维粗纱 R 4.50 3.06
粘胶/涤纶(80/20)混纺粗纱 R/T 4.50 3.06

图1

后区牵伸样品切断区域分布"

图2

不同放大倍数下T3粗纱截面SEM照片"

图3

不同定量的粗纱强力变化"

图4

不同纤维长度粗纱在不同夹持长度下的强力变化"

图5

细纱后区牵伸中粗纱须条T3运动"

图6

不同定量粗纱在细纱后区牵伸效果"

图7

不同捻度粗纱在细纱后区牵伸效果"

图8

不同纤维长度粗纱在细纱后区牵伸效果"

图9

不同细纱后区牵伸倍数的牵伸效果"

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