基于质量分布法的棉集合体中纤维弯钩研究

doi:10.13475/j.fzxb.20240402001

Abstract

Abstract:

Objective In textile production, 80% of fibers in card sliver are hooked fibers. However, the hooked fiber is easy to twist into nep in the later process, which has a significant negative impact on the yarn strength, uniformity and fabric appearance. The number and directions of hooked fibers determine the fiber straightness and yarn evenness. Therefore, the measurement and characterization of hooked fiber is of great significance for optimizing process parameters, regulating spinning processes and improving semi-finished products and yarn quality. At present, most methods to characterize hooked fibers by measuring fiber straightness have the disadvantages of heavy workload and long testing time. The rapid batch detection of hooked fibers is of great significance for adjusting process parameters in time and improving yarn quality.

Method In order to quickly detect the hooked fiber state in each process, this paper puts forward a new method to quickly obtain the hooked index in cotton yarn to characterize the hooked state with the instrument USTER^®LVI 930. The proportion of hooked fiber in spinning process measured by the tracer fiber method is based on data. Then the instrument USTER^®LVI 930 was adopted to characterize the proportion of hooked fibers. Combined with the quality test, the feasibility of this method was explored by comparing the data of the two.

Results Based on the tracer fiber method, viscose fiber with similar properties to raw cotton was used as tracer fiber. In this study, one thousandth tracer fiber is mixed into the cotton fiber. The processed cotton yarn, including card sliver, semi-drawn sliver, drawn sliver, roving and yarn, were tested by tracer fiber method first. The leading hooked fiber, the trailing hooked fiber and the both ends hooked fibers are counted as the hooked fiber ratio in the cotton yarn, that is, the hook index N_TF. Then, the above-mentioned cotton yarn was tested by the instrument USTER^®LVI 930, and the fiber length distribution at the front and back ends intervals of 3.175 mm was obtained. The length difference between the front and back ends was believed to be caused by hooked fibers. Therefore, the fiber length distribution was transformed into the fiber mass distribution. Then, according to the difference between the fiber mass distribution of the front and back ends, the proportion of hooked fibers in cotton yarn, that is, the hook index N_MD, was calculated. By comparing the hook index N_MD of fiber mass distribution method and the hook index N_TF of tracer fiber method, it was that with the progress of spinning process, the fiber straightness increases and the hooked fiber decreases, and the hook index N_MD is closer to N_TF. Finally, the cotton yarn was tested for quality, which showed that the change trend of quality index and hook index was basically the same in the spinning process. Among them, a big gap is found in the hook index in the first drawing. This may be due to the fact that the length of the hook was related to the length of the fiber, and the longer fiber was easy to form a longer hook. The average length of tracer fiber was higher than the weighted half average length of raw cotton. In the process of sliver and drawing with low fiber straightness, the hook index N_TF of tracer fiber method was higher than that of fiber mass distribution method N_MD.

Conclusion By comparing the hook index and quality test in the two testing methods, the hook index of fiber weight distribution method can quickly characterize the hook in cotton yarn to some extent. For slivers, the hooks index calculated by the fiber mass distribution method proposed in the paper is generally within 6% error compared with the tracer fiber method. For roving and spun yarn, the difference is within 2%. The rapid batch acquisition of hook index N_MD is expected to optimize process parameters and improve carding effect in time, thus improving economic benefits and promoting the new development of high-quality textiles.

Key words: hooked fiber, fiber weight distribution, cotton fiber assembly, hook index, fiber length distribution, yarn quality

CLC Number:

TS102

CHU Xiangting, GAO Jian, ZHANG Hongdou, LU Huiwen, LIU Xinjin, SU Xuzhong. Study on fiber hooking in cotton fiber assembly based on fiber mass distribution method[J].Journal of Textile Research, 2025, 46(07): 69-77.

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

URL: http://www.fzxb.org.cn/EN/10.13475/j.fzxb.20240402001

http://www.fzxb.org.cn/EN/Y2025/V46/I07/69

Figures/Tables 14

Tab.1

Fig.1

Fig.2

Fig.3

Fig.4

Fig.5

Tab.2

Tab.3

Tab.4

Tab.5

Fig.6

Tab.6

Tab.7

Tab.8

References 14

[1]	MALAKANE P B, KADOLE P V, 史雅楠. 梳理工艺参数对纤维取向与纱条质量的影响[J]. 国际纺织导报, 2022, 50(2): 13-15,25.
	MALAKANE P B, KADOLE P V, SHI Yanan. Effect of carding variables on fiber orientation and sliver quality[J]. Melliand China, 2022, 50(2): 13-15,25.
[2]	棉纺教研组译. 梳毛和针梳过程中的弯钩问题[J]. 国外纺织技术, 1975(Z1): 115-118.
	Translation of Cotton Textile Teaching and Research Group. The problem of bending hooks in carding and needle carding[J]. Textile Technology Overseas, 1975(Z1): 115-118.
[3]	SIMPSON J. Relation between "minority" hooks and neps in the card web[J]. Textile Research Journal, 1972, 42(10): 590-591.
[4]	SHEN Y, YU C, YANG J. A study on fiber motion in the drafting zone and hook removal[J]. Textile Research Journal, 2019, 90(11/12): 1277-1290.
[5]	申元颖. 牵伸区内纤维运动的研究[D]. 上海: 东华大学, 2023:72-89.
	SHEN Yuanying. Study on fiber movement in drafting zone[D]. Shanghai: Donghua University, 2023: 72-89.
[6]	王青, 梁高翔, 殷俊清, 等. 新型气流牵伸通道结构模型的构建与性能分析[J]. 纺织学报, 2023, 44(11): 52-60. doi: 10.13475/j.fzxb.20220701701
	WANG Qing, LIANG Gaoxiang, YIN Junqinng, et al. Establishment of novel model and performance analysis of airflow drafting channel[J]. Journal of Textile Research, 2023, 44(11): 52-60. doi: 10.13475/j.fzxb.20220701701
[7]	唐文辉, 李鸿儒. 条粗半制品内在结构的研究[J]. 纺织学报, 1979(3): 12-19,46.
	TANG Wenhui, LI Hongru. A study on the intrinsic structure of strip rough semi-products[J]. Journal of Textile Research, 1979(3): 12-19,46.
[8]	YANG J, SHEN Y, ZHANG H. A study of fiber configuration in sliver fiber arrangement and its influence on sliver limit irregularity[J]. Textile Research Journal, 2019, 89(23/24): 4799-4807.
[9]	费青. 弯钩方向性和纤维伸直度研究[J]. 纺织科技进展, 2009(2): 20-23,29.
	FEI Qing. Study on directionality of bending hook and fiber straightness[J]. Progress in Textile Science & Technology, 2009(2): 20-23,29.
[10]	费青. 纤维伸直度的测定方法及影响因素分析[J]. 棉纺织技术, 2005(4): 1-5.
	FEI Qing. Analyses on influence factors and determine methods of fiber straightness[J]. Cotton Textile Technology, 2005(4): 1-5.
[11]	张亚秋, 陈霞, 江慧, 等. 基于图像处理技术的弯钩纤维表征[J]. 纺织器材, 2014, 41(5): 32-36.
	ZHANG Yaqiu, CHEN Xia, JIANG Hui, et al. The characterization of the hooked fiber based on image processing technology[J]. Textile Accessories, 2014, 41(5): 32-36.
[12]	张弘强. 纱条中纤维形态及排列对条干不匀的影响[D]. 上海: 东华大学, 2016:18-23.
	ZHANG Hongqiang. Effect of fiber shape and arrangement on yarn or sliver irregularity[D]. Shanghai: Donghua University, 2016: 18-23.
[13]	IYER I K P, 胡齐咏. 去除纤维弯钩的纺纱短流程[J]. 国外纺织技术(纺织分册), 1987(12): 7-10.
	IYER I K P, HU Qiyong. A short spinning process for removing fiber bends[J]. Textile Technology Overseas (Textile Division), 1987(12): 7-10.
[14]	SENGUPTA A K, 贺福敏. 梳棉机上纤维由锡林向道夫转移时构形的变化[J]. 国外纺织技术(纺织分册), 1983(7): 4-6.
	SENGUPTA A K, HE Fumin. Conformational changes in fiber transfer from seline to doff on a card[J]. Textile Technology Overseas (Textile Division), 1983(7): 4-6.

Related Articles 15

[1]	YANG Tianqi, REN Jiazhi, WANG Xuzhen, CHEN Yuheng. Mathematical modeling and application of feeding ratios for multi-fiber combed fiber rolls [J]. Journal of Textile Research, 2025, 46(07): 62-68.
[2]	ZHANG Dingtiao, WANG Qianru, QIU Fang, LI Fengyan. Simulation of flow field and fiber straightening in reconstructed fiber transport channel in rotor spinning [J]. Journal of Textile Research, 2025, 46(02): 100-105.
[3]	SONG Kaili, GUO Mingrui, GAO Weidong. Numerical simulation and experimental investigation of lattice-apron compact spinning with airflow-guiding device [J]. Journal of Textile Research, 2025, 46(01): 34-41.
[4]	ZHANG Hongdou, CHEN Fang, CHU Xiangting, LU Huiwen, LIU Xinjin, SU Xuzhong. Study on fiber hooking in chemical fiber sliver based on fiber tracing method [J]. Journal of Textile Research, 2024, 45(12): 74-79.
[5]	ZHU Lei, LI Yong, CHEN Xiaochuan, WANG Jun. Finite element modeling and simulation of cotton fiber assembly carding process based on 3-D braided and fractal theory [J]. Journal of Textile Research, 2024, 45(11): 65-72.
[6]	FU Caizhi, CAO Hongyan, LIAO Wenhao, LI Zhongjian, HUANG Qixiang, PU Sancheng. Yarn unevenness measurement method based on multi-view images [J]. Journal of Textile Research, 2024, 45(03): 49-57.
[7]	LI Xinrong, HAN Penghui, LI Ruifen, JIA Kun, LU Yuanjiang, KANG Xuefeng. Review and analysis on key technology of digital twin in spinning field [J]. Journal of Textile Research, 2023, 44(10): 214-222.
[8]	WANG Menglei, WANG Jing'an, GAO Weidong. Research progress in computer aided cotton blending technology [J]. Journal of Textile Research, 2023, 44(08): 225-233.
[9]	YANG Yun, SUN Tong, LIANG Zhenyu, PENG Guang, BAO Jinsong. Quantitative analysis method of cotton yarn defects based on heterogeneous ensemble learning [J]. Journal of Textile Research, 2023, 44(05): 93-101.
[10]	WU Fan, LI Yong, CHEN Xiaochuan, WANG Jun, XU Minjun. Finite element modeling and simulation of cotton fiber assembly compression based on three-dimensional braided model [J]. Journal of Textile Research, 2022, 43(09): 89-94.
[11]	SHAO Jingfeng, DONG Mengyuan. Influence of performance degradation of spinning frames on yarn quality under dependent competition failure [J]. Journal of Textile Research, 2022, 43(06): 171-179.
[12]	SHAO Jingfeng, SHI Xiaomin. Multi-objective optimization of spinning process parameters based on nondominated sorting genetic algorithm II [J]. Journal of Textile Research, 2022, 43(01): 80-88.
[13]	GUO Minghua, LIU Xinjin. Investigation on distribution of fiber accelerated points in drafting zone of ring spinner based on cut-weighing method [J]. Journal of Textile Research, 2021, 42(08): 71-75.
[14]	WU Jiaqing, WANG Ying, HAO Xinmin, GONG Yumei, GUO Yafei. Effect of filament feeding positions on structure and properties of siro-spinning core-spun yarns [J]. Journal of Textile Research, 2021, 42(08): 64-70.
[15]	ZHANG Huanhuan, ZHAO Yan, JING Junfeng, LI Pengfei. Yarn evenness measurement based on sub-pixel edge detection [J]. Journal of Textile Research, 2020, 41(05): 45-49.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

工序
生条	1 027	572	2 830	905	80.75
一并条	2 320	2 288	202	192	53.62
二并条	4 000	528	886	111	27.60
二并粗纱	445	54	10	0	12.57
二并细纱	103	3	2	0	4.63
三并条	1 413	312	52	16	21.19
三并粗纱	466	16	16	1	6.61
三并细纱	113	4	2	1	5.83

纤维长度区间 n/mm	生条		一并条		二并条		三并条
纤维长度区间 n/mm	η_B/%	η_F/%	η_B/%	η_F/%	η_B/%	η_F/%	η_B/%	η_F/%
0.000~3.175	0.763	1.675	1.032	3.639	0.480	1.607	0.852	2.834
3.176~6.350	2.633	5.605	0.583	1.946	0.799	2.716	0.584	1.972
6.351~9.525	3.898	7.812	1.032	3.639	0.480	1.607	0.852	2.834
9.526~12.700	3.929	9.928	0.583	1.946	0.799	2.716	0.584	1.972
12.701~15.875	3.711	12.325	1.032	3.639	0.480	1.607	0.852	2.834
15.876~19.050	7.949	14.647	0.583	1.946	0.799	2.716	0.584	1.972
19.051~22.225	15.279	15.509	1.032	3.639	0.480	1.607	0.852	2.834
22.256~25.400	20.790	14.590	0.583	1.946	0.799	2.716	0.584	1.972
25.401~28.575	21.122	11.197	1.032	3.639	0.480	1.607	0.852	2.834
28.576~31.750	14.093	5.509	0.583	1.946	0.799	2.716	0.584	1.972
31.751~34.925	5.127	1.197	1.032	3.639	0.480	1.607	0.852	2.834
34.926~38.100	0.703	0.006	0.583	1.946	0.799	2.716	0.584	1.972
38.101~41.275	0.001	0.000	1.032	3.639	0.480	1.607	0.852	2.834
41.276~44.450	0.000	0.000	0.583	1.946	0.799	2.716	0.584	1.972

纤维长度区间n/mm	二并粗纱		二并细纱		三并粗纱		三并细纱
纤维长度区间n/mm	η_B/%	η_F/%	η_B/%	η_F/%	η_B/%	η_F/%	η_B/%	η_F/%
0.000~3.175	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
3.176~6.350	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370
6.351~9.525	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
9.52612.700	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370
12.701~15.875	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
15.876~19.050	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370
19.051~22.225	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
22.256~25.400	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370
25.401~28.575	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
28.576~31.750	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370
31.751~34.925	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
34.926~38.100	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370
38.101~41.275	0.700	2.335	1.270	4.340	0.515	1.735	1.060	3.600
41.276~44.450	0.480	1.685	1.270	4.335	0.520	1.800	1.305	4.370

纤维长度区间n/mm	生条		一并条		二并条		三并条
纤维长度区间n/mm	ε_B/%	ε_F/%	ε_B/%	ε_F/%	ε_B/%	ε_F/%	ε_B/%	ε_F/%
0.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000
0.000~3.175	0.992	0.983	0.990	0.994	0.995	0.992	0.991	0.994
3.176~6.350	0.966	0.927	0.953	0.975	0.979	0.965	0.963	0.974
6.351~9.525	0.927	0.849	0.903	0.942	0.950	0.924	0.921	0.942
9.526~12.700	0.888	0.750	0.852	0.910	0.922	0.882	0.871	0.903
12.701~15.875	0.851	0.627	0.789	0.895	0.914	0.843	0.823	0.876
15.876~19.050	0.771	0.480	0.682	0.837	0.878	0.764	0.752	0.832
19.051~22.225	0.618	0.325	0.526	0.685	0.752	0.616	0.633	0.734
22.256~25.400	0.411	0.179	0.344	0.462	0.542	0.415	0.471	0.570
25.401~28.575	0.199	0.067	0.170	0.230	0.298	0.210	0.286	0.358
28.576~31.750	0.058	0.012	0.053	0.072	0.110	0.069	0.126	0.162
31.751~34.925	0.007	0.000	0.007	0.010	0.021	0.011	0.032	0.044
34.926~38.100	0.000	0.000	0.000	0.000	0.001	0.000	0.003	0.005
38.101~41.275	0.000	0.000	0.000	0.000	0.000	0.000	0.000	0.000
41.276~44.450	0.000	0.000	0.000	0.000	0.000	0.000	0.000	0.000

纤维长度区间n/mm	二并粗纱		二并细纱		三并粗纱		三并细纱
纤维长度区间n/mm	ε_B/%	ε_F/%	ε_B/%	ε_F/%	ε_B/%	ε_F/%	ε_B/%	ε_F/%
0.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000	1.000
0.000~3.175	0.993	0.995	0.987	0.987	0.995	0.995	0.989	0.987
3.176~6.350	0.970	0.978	0.944	0.944	0.978	0.977	0.953	0.943
6.351~9.525	0.933	0.949	0.885	0.885	0.949	0.946	0.902	0.883
9.526~12.700	0.892	0.913	0.816	0.814	0.913	0.908	0.843	0.806
12.701~15.875	0.859	0.887	0.724	0.720	0.889	0.884	0.774	0.711
15.876~19.050	0.803	0.850	0.604	0.601	0.855	0.843	0.674	0.595
19.051~22.225	0.693	0.757	0.462	0.466	0.765	0.741	0.534	0.462
22.256~25.400	0.527	0.587	0.302	0.317	0.599	0.572	0.359	0.313
25.401~28.575	0.324	0.363	0.146	0.164	0.379	0.360	0.184	0.159
28.576~31.750	0.144	0.162	0.039	0.050	0.174	0.165	0.062	0.047
31.751~34.925	0.038	0.044	0.003	0.006	0.049	0.046	0.010	0.006
34.926~38.100	0.003	0.005	0.000	0.000	0.006	0.005	0.000	0.000
38.101~41.275	0.000	0.000	0.000	0.000	0.000	0.000	0.000	0.000
41.276~44.450	0.000	0.000	0.000	0.000	0.000	0.000	0.000	0.000

Study on fiber hooking in cotton fiber assembly based on fiber mass distribution method

RichHTML

PDF (PC)