转轮集聚纺纱装置与工艺设计

doi:10.13475/j.fzxb.20220806907

摘要/Abstract

摘要：

针对目前负压式集聚纺能耗大的问题,设计了转轮集聚纺纱装置。选用粗纱定量为6.33 g/(10 m)的普梳棉粗纱为原料,采用转轮集聚纺纱装置与传统环锭纺,设计纺纱线密度分别为32.4、24.3、19.4 tex纺制纱线,并对其单纱线密度、断裂强度、毛羽、条干均匀度和捻度进行测试对比,客观评价该转轮集聚纺纱装置的应用效果。结果表明:与环锭纱相比,转轮集聚纱4 mm以上有害毛羽减少量达40%~80%,单纱断裂强度下降1%~3%,断裂强力不匀率下降25%~50%,24.3和19.4 tex的单纱条干均匀度有3%~6%的轻微恶化,捻度基本无影响,说明使用转轮集聚纺纱装置可显著减少纱线的有害毛羽;转轮集聚纺纱装置安装在前罗拉下方,可在环锭细纱机上快速安装与拆卸,实现传统环锭纺与集聚纺的便捷切换,同时该装置具有构造简单、能耗低等优点。

关键词: 集聚纺, 转轮集聚纺纱装置, 棉纱, 毛羽测试, 断裂强度, 条干均匀度

Abstract:

Objective At present, most spinning mills use negative pressure concentrated spinning. However, this spinning method relates to high the spinning cost due to high energy consumption. Thus a runner accumulating device was designed which does not depend on the use air pressure energy for yarn spinning. Specific experimental tasks in the research include spinning experiments by the device and yarn performance evaluation. The research is to be carried out to reduce yarn hairiness reduction, and it is envisaged that the high quality yarn production will reduce the reliance on negative pressure spinning.
Method Carded cotton roving was used as raw material to make yarns of 32.4, 24.3, and 19.4 tex. Spinning experiment included producing original yarn by traditional spinning machine and runner yarn by rotary transformation of ring spinning. These experiments were operated in spinning experiment machine DHU-X01. Two types of single yarn performance experiments were completed under the conditions of temperature about (20±2) ℃ and humidity of about (65±3)%, on hairiness testing, single yarn strength, yarn evenness, twist and 100 m weight test. The experiment required data analysis and collation to make comparison of two single yarn properties to verify the feasibility of the device.
Results The accumulating device has a good hair reduction effect on the 32.4, 24.3 and 19.4 tex cotton single yarns, with hairiness reduction effect above 4 mm. However, the strength of the runner yarn is weaker than the original yarn, and the breaking strength was decreased by approximately 1%-3%. This may be because of the lack of proper tension stretching between the front jaws and the runner jaws as the rotary wheel is driven by the front roller, causing low orientation of fibers in the yarn. When yarns were stretched by external forces, fiber utilization was reduced and yarn strength decrease, leading to slight worsening of yarn evenness. Experiment also showed that after the whiskers left the front jaws, they were not subjected to stable control immediately, causing increased CV value on yarn evenness. The twist test results show that runner device has no influence on yarn twist. 100 m weight was measured by yarn length gauge to investigate the difference in actual linear density. Compared with the experimental data, 100 m weight of runner yarn is 3% lighter than original yarn. There were two reasons for this phenomenon. On the one hand, the runner device moved the twist point forward to the place closer to the pipette and sucked air away together with some fiber. On the other hand, the device's clamping force between the two wheels was small and the wheel caused more friction on the whiskers, causing some fiber lost. Two experiments were carried out to analyze and verify the reasons. Through the data analysis, it is concluded that the friction between the runner and the fibers is the main reason for the decrease of 100 g weight. Subsequent experiments will solve this problem by increasing the clamping force of the runner.
Conclusion In summary, runner device has a noted improvement on cotton yarn hairiness reduction, and the spinning cost of the device is lower than that of the negative pressure compact spinning. Though runner yarn strength and yarn evenness are not as good as the original yarn, the deterioration of indicators is quite small within a reasonable range and it basically does not affect the use of single yarn. If the rotor wheel size is further reduced, for which the runner accumulating device is closer to the front jaw, it is expected to better results could be achieved. For producing yarns in a certain fineness range, it is promising that the low-cost runner accumulating device could replace RoCoS and negative pressure compact devices.

Key words: compact spinning, runner accumulating device, cotton yarn, hairiness test, breaking strength, yarn evenness

中图分类号:

TS111.8

张青青, 倪远, 汪军, 张玉泽, 江慧. 转轮集聚纺纱装置与工艺设计[J]. 纺织学报, 2023, 44(02): 83-89.

ZHANG Qingqing, NI Yuan, WANG Jun, ZHANG Yuze, JIANG Hui. Process design of spinning device based on runner fiber accumulation[J]. Journal of Textile Research, 2023, 44(02): 83-89.

图/表 13

图1

图2

图3

图4

表1

表2

表3

表4

图5

表5

图6

表6

表7

参考文献 18

[1]	贺伟娜, 权延娟, 詹树改. 绪森倚丽特集聚纺装置的应用效果分析[J]. 棉纺织技术, 2018, 46(8): 55-58.
	HE Weina, QUAN Yanjuan, ZHAN Shugai. Analysis of the application effect of the suessen elite compact spinning device[J]. Cotton Textile Technology, 2018, 46(8): 55-58.
[2]	严瑛, 董爱仙. 环锭纺与RoCoS紧密纺的对比分析[J]. 现代纺织技术, 2014, 22(3): 29-31.
	YAN Ying, DONG Aixian. Comparative analysis of ring spinning and rocos compact spinning[J]. Advanced Textile Technology, 2014, 22(3): 29-31.
[3]	STEFAN Urmetze, 倪远. 捷丽纺装置:满足集聚需求的全新机械集聚解决方案[J]. 纺织器材, 2022, 49(3): 62-64.
	STEFAN Urmetze, NI Yuan. Jieli spinning device: a new mechanical agglomeration solution to meet agglomeration needs[J]. Textile Accessories, 2022, 49(3): 62-64.
[4]	钱成, 刘燕卿, 刘新金, 等. 全聚纺与四罗拉网格圈紧密纺集聚区三维流场模拟与对比分析[J]. 丝绸, 2020, 57(7): 50-54.
	QIAN Cheng, LIU Yanqing, LIU Xinjin, et al. Three-dimensional flow field simulation and comparative analysis of all-polyspinning and four-roller mesh circle tight spinning agglomeration area[J]. Journal of Silk, 2020, 57(7): 50-54.
[5]	郝可可, 张玉泽, 汪军, 等. 脉动集聚纺装置特点与成纱质量分析[J]. 上海纺织科技, 2021, 49(4): 49-51.
	HAO Keke, ZHANG Yuze, WANG Jun, et al. Characteristics and yarn quality analysis of pulsating agglomeration spinning device[J]. Shanghai Textile Science & Technology, 2021, 49(4): 49-51.
[6]	程登木. 聚纤纺牵伸系统的研究与实践[J]. 纺织学报, 2013, 34(6): 142-146.
	CHENG Dengmu. Research and practice of polyfiber spinning draft system[J]. Journal of Textile Research, 2013, 34(6): 142-146.
[7]	倪远. 环锭集聚纺纱技术的发展[J]. 纺织导报, 2011(6): 35-36.
	NI Yuan. Development of ring spinning technology[J]. China Textile Leader, 2011(6): 35-36.
[8]	袁祖纯. 基于优化三角区的纺纱方法的研究与实践[D]. 武汉: 武汉纺织大学, 2016: 1-4.
	YUAN Zuchun. Research and practice of spinning method based on optimized triangle area[D]. Wuhan: Wuhan Textile University, 2016: 1-4.
[9]	贠秋霞, 杨雯静. 集聚纺纱技术的应用浅析[J]. 棉纺织技术, 2016, 44(2): 80-84.
	YUN Qiuxia, YANG Wenjing. Analysis on the application of agglomeration spinning technology[J]. Cotton Textile Technology, 2016, 44(2): 80-84.
[10]	白洋, 孔聪. 不同形式紧密纺系统对比[J]. 上海纺织科技, 2014, 42(7): 6-10.
	BAI Yang, KONG Cong. Comparison of different compact spinning systems[J]. Shanghai Textile Science & Technology, 2014, 42(7): 6-10.
[11]	傅培花. 集聚纺纱的凝聚机理和成纱结构性能的研究[D]. 上海: 东华大学, 2005: 37-38.
	FU Peihua. Research on the agglomeration mechanism of agglomerated spinning and the structural properties of the yarn[D]. Shanghai: Donghua University, 2005: 37-38.
[12]	薛少林, 周秀玲, 马文祥, 等. 单纱强力CV%值的试验研究[J]. 棉纺织技术, 2000, 28(3): 10-13.
	XUE Shaolin, ZHOU Xiuling, MA Wenxiang, et al. Experimental research on CV% value of single yarn strength[J]. Cotton Textile Technology, 2000, 28(3): 10-13.
[13]	姜展. 纱条中纤维排列的模拟及其对成纱质量的影响[D]. 上海: 东华大学, 2017: 6-8.
	JIANG Zhan. Simulation of fiber arrangement in yarn sliver and its influence on yarn quality[D]. Shanghai: Donghua University, 2017: 6-8.
[14]	钱祥煦, 朱红青. 加捻三角区形态与纺纱毛羽[J]. 棉纺织技术, 2009, 37(10): 1-4.
	QIAN Xiangxu, ZHU Hongqing. Twisting triangle shape and spinning hairiness[J]. Cotton Textile Technology, 2009, 37(10): 1-4.
[15]	薛元, 曹艳. 环锭纺加捻三角区纤维转移机理及其运动规律分析[J]. 纺织学报, 2005, 26(5): 31-33.
	XUE Yuan, CAO Yan. Analysis of fiber transfer mechanism and motion law in twisting triangle area of ring spinning[J]. Journal of Textile Research, 2005, 26(5): 31-33.
[16]	FENG Jie, XU Bingang, TAO Xiaoming, et al. Theoretical study of a spinning triangle with its application in a modified ring spinning system[J]. Textile Research Journal, 2010, 80(14): 1456-1464. doi: 10.1177/0040517510361803
[17]	余豪, 张建建, 刘可帅, 等. 导纱钩运动引起的纺纱三角区变化对成纱性能的影响[J]. 纺织学报, 2016, 37(10): 19-25.
	YU Hao, ZHANG Jianjian, LIU Keshuai, et al. Influence of spinning triangle changes caused by yarn guide hook movement on yarn properties[J]. Journal of Textile Research, 2016, 37(10): 19-25.
[18]	武建周, 李世平. 紧密纺纱线条干不匀的研究以及管理措施[J]. 轻纺工业与技术, 2017, 46(6): 7-10.
	WU Jianzhou, LI Shiping. Research on unevenness of compact spinning yarn and management measures[J]. Textile Industry and Technology, 2017, 46(6): 7-10.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

设计单纱线密度/tex	锭速/ (r·min^-1)	总牵伸倍数	捻度/ (捻·m^-1)
32.4	6 000	19.8	630
24.3	6 907	26.4	727
19.4	7 725	33.0	814

设定线密度	原纱实际线密度	转轮纱实际线密度
32.4	34.5	33.5
24.3	24.9	24.1
19.4	19.7	19.1

测试次数	线密度/tex
测试次数	关吸风无转轮	关吸风有转轮	开吸风有转轮
1	34.5	34.0	33.7
2	35.6	34.2	34.0
3	34.4	33.7	33.5
平均值	34.8	34.0	33.7

试样	断裂强力/ cN	断裂强力 CV值/%	断裂强度/ (cN·tex^-1)	断裂伸长/ mm	断裂功/ (cN·mm)	断裂时间/ s
32.4 tex原纱	607.50	7.24	17.61	27.51	8 511.20	3.30
32.4 tex转轮纱	583.20	5.47	17.41	29.56	8 555.93	3.55
24.3 tex原纱	468.15	7.83	18.80	32.20	7 261.00	3.86
24.3 tex转轮纱	439.50	4.06	18.24	29.67	6 247.68	3.56
19.4 tex原纱	354.35	5.55	17.99	23.12	4 575.82	2.77
19.4 tex转轮纱	337.25	3.86	17.66	23.93	4 368.47	2.87

试样线密度/tex	变化百分比/%
试样线密度/tex	1 mm	2 mm	3 mm	4 mm	5 mm	6 mm	7 mm	8 mm	9 mm
32.4	27.40	25.00	9.80	5.10	-3.00	-38.50	-68.75	-62.50	-60.00
24.3	16.60	11.10	-5.60	-25.00	-34.00	-29.40	-14.30	-80.00	-50.00
19.4	18.00	24.30	24.60	12.20	-18.90	-46.20	-85.70	-50.00	0.00