纺织学报 ›› 2024, Vol. 45 ›› Issue (03): 209-218.doi: 10.13475/j.fzxb.20220906602

• 综合述评 • 上一篇    下一篇

喷气涡流纺纱机及其关键技术的应用与研究进展

邵英海1, 赵业平1, 韩贤国1, 曹继鹏1(), 张明光1, 陈文2   

  1. 1.辽东学院, 辽宁 丹东 118003
    2.福建新华源科技集团有限公司, 福建 福州 350200
  • 收稿日期:2022-09-26 修回日期:2023-04-25 出版日期:2024-03-15 发布日期:2024-04-15
  • 通讯作者: 曹继鹏
  • 作者简介:邵英海(1969—),男,高级实验师。主要研究方向为纺纱工艺技术及纺纱机机构改进。
  • 基金资助:
    辽宁省科技厅科研项目(2022JH2/101300010);辽宁省教育厅科研项目(JYTZD2023058)

Progress of research and application in air-jet vortex spinning machine and key technologies

SHAO Yinghai1, ZHAO Yeping1, HAN Xianguo1, CAO Jipeng1(), ZHANG Mingguang1, CHEN Wen2   

  1. 1. Liaodong University, Dandong, Liaoning 118003, China
    2. Fujian Xinhuayuan Technology Group Co., Ltd., Fuzhou, Fujian 350200, China
  • Received:2022-09-26 Revised:2023-04-25 Published:2024-03-15 Online:2024-04-15
  • Contact: CAO Jipeng

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摘要:

针对国内外纺纱企业在喷气涡流纺纱机的应用与相关技术的研发情况及其所存在的问题,综述了喷气涡流纺纱机及其关键技术的研究进展,介绍了喷气涡流纺纱机的历史发展及其纺纱系统关键技术,详细分析了喷气涡流纺纱机的导棉喂入、牵伸和输送机构,成纱器,纱线卷绕(横动)、卷装机构等零部件的特征与发展趋势。分析认为:喷气涡流纺纱技术的研究多集中在对现有规模化生产机器的喷气涡流成纱器的结构改进、工作机制探讨上,成果较多且较为成熟,但创新技术不突出;在构建新型成纱器的内部型腔结构和产生更理想的涡流形态上有望进一步突破,以提高喷气涡流纺纱的性能,满足多功能纱线的生产和扩大纺纱应用范围;同时科技进步也使更多智能控制系统的电子清纱器、异纤控制、短线诊断、可视化等技术在纺纱工序中有了应用和发展。

关键词: 喷气涡流纺, 成纱器, 涡流管, 导棉机构, 卷绕机构

Abstract:

Significance Air-jet vortex spinning machine (AVSM) is an spinning equipment with high spinning speed and efficiency in achieving high quality of multi-variety yarns, which is developed on the basis of jet spinning technology. AVSM is employed by more textile enterprises and has a profound scope for spinning of medium and long lengths staple cotton and blended yarns. But the technology of AVSM has its disadvantages and limitations of significant fiber loss, 100% short fiber loss for cotton yarn spinning. The limitation of the spinning range can be expected to overcome by the market leading enterprises of AVSM. Thus, in order to understand the current application, research development and present problems in AVSM by domestic and foreign spinning enterprises, a comprehensive analysis of the results of research and patent design achieved in AVSM is presented.

Progress Modern air-jet vortex spinning (AVS) technology is basically a new spinning technology developed on the base of the Murata AVSM. The key technologies and principle related to the AVS process include cotton guiding and feeding, sliver drafting, conveying, AVS device, yarn winding, and yarn packaging. The AVS device is the core device of AVSM, and the earliest version was manufactured by Murata. Later Gernot from Rieter proposed another AVS device, which is with different designs for the spindle, needle guider, and nozzle block. The research on in two types of AVS device have been made in the aspects of structure optimization, CFD simulation of three-dimensional air flow field inside of AVS device. Some improved structures of AVS device were proposed for reducing rate of short fiber falling, and for increasing the spinning rate. Huayan in Shaanxi designed two-split structure of AVS device controlled by pneumatic cylinder for opening and closing of the upper and the lower branches. The double AVS devices composed of the upper and lower branches was design to prevent fibers to be taken away from the airflow for improving the spinning rate. There are a few designs of the needle block with special features, i.e., the movable needle with adjustable axial position, or adjustable angle between guide hole and needle, the more guide holes and heating function. In nozzle block, some improved designs were made such as four adjacent spiral vortex grooves on chamber wall, three-stage structure, the surrounding spiral pipe on the outer surface for further improving the spinning effect.

Conclusion and Prospect For understanding the main application and research status of AVS technology, the relevant patents and research papers are reviewed. The research shows that the main research content of AVSM and its key technology are developed by some Chinese spinning enterprises and textile research institutes such as Huayan in Shanxi, Jiangyin Huafang New Science and Technology Ltd. Co. and so on with many related patents mainly focusing on the improved structural design of the AVS device and its related components. Overseas large-scale production of AVSM is mainly made from Murata and Rieter. Global research is also focused on the content of AVS of Murata, and more researches carry out simulation analysis on AVS device and on the spinning performance. In comparison with the early development of AVSM from Murata and Rieter, the relevant achievements of application and research progress of AVS technology are not noticeable. At present, the nozzle chamber of AVSM is often designed as the conical frustum model, in which the working principles of setting multiple air-jet vents in tangential direction of the chamber surface for producing the swirling air flow to make fiber false twisting has not changed. Looking forward to the future, CFD analysis and experimental research of AVS device will be needed aiming at the design of chamber structures, the production of higher strength yarn and the optimization of twisted vortex for improving the performance of AVS, meeting the production of multifunctional yarns and manufacturing yarns from short cotton fiber. In addition, with the progress of science and technology, more and more automation and intelligence control systems will be developed and applied in the AVSM such as electronic yarn cleaner, detection and control of foreign fibers, short fibers diagnosis, visualization, and others.

Key words: air-jet vortex spinning, spinning device, nozzle block, conveying mechanism, winding mechanism

中图分类号: 

  • TS112

图1

喷气涡流纺纱过程及装置"

图2

A、B纱线的纺纱系统 1—导条架;2—导条器;3—给棉罗拉;4—后罗拉; 5—中罗拉;6—前罗拉;7—成纱器;8—输出罗拉; 9—电子清纱器;10—卷绕纱筒;A—须条A;B—须条B。"

图3

日本村田公司生产的成纱器 1—导针座;2—导纱针;3—进气口;4—涡流管; 5—空心锭;6—出气口;7—导纱通道; 8—半圆形凹槽;9—喷气孔。"

图4

瑞士立达公司生产的成纱器 1—输送辊;2—喂棉通道;3—喷气孔;4—导纱面;5—引纱入孔; 6—气道;7—环形道;8—锭顶端件;9—活塞结构;10—涡流室; 11—疏散道;12—空心锭体;13—喷射道;14—出纱通道; 15—气道;16—限位活塞;17—加载弹簧; C—进气孔;D—中断进气孔;Δy—隔距。"

图5

陕西华燕设计的成纱器"

图6

导引体结构"

图7

改进的涡流管"

图8

改进结构的空心锭"

图9

卷绕机构 1—供袋组件;2—出料板;3—下料传送带;4—安装板; 5—挡板;6—收集箱;7—滑槽;8—取袋组件; 9—下料孔;10—引导板;11—引导条。"

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