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Abstract

The fiber arrangement in a sliver plays a significant role in determining the sliver evenness. In this research, an innovative method was proposed to simulate the fiber arrangement, based on the variation in linear density, relative to the mean values along the sliver axis, acquired from the measured distribution of the sliver linear density. The simulated results for three polymer carding slivers and three cotton carding slivers show that the fiber arrangement in the sliver can be concretely and graphically expressed by the variation of the linear density of each sliver subsection, relative to the mean sliver linear density. Moreover, the simulated sliver irregularities and frequency distributions of the carding sliver linear density in the sliver, based on the actual variation curve of the sliver linear density and the actual frequency of the sliver linear density, all conformed better to the actual slivers, compared with the simulated slivers with the method based on a random fiber arrangement. However, a comparison of the simulation results for these two methods demonstrates that the method based on the actual variation curve of the sliver linear density can only simulate the fiber arrangement of the test section. Conversely, the method based on the actual frequency distribution of the sliver linear density can simulate the fiber arrangement in the whole carding sliver, so that it is more applicable for use in further post-spinning processes with the accurate simulation results.

Keywords

Fiber arrangement distribution of sliver linear density variation curve frequency distribution sliver irregularity

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References

Brown

NG.

Statistics for the number of fiber ends in a segment of a random assembly of aligned fibers. Text Res J 1985; 55: 206–210.

Cherkassky

Neural network meta‐model of fibrous materials based on discrete‐event simulation. Part 1: Discrete‐event simulation model of one‐dimensional fibrous material. J Text Inst 2011; 102: 442–454.

Cherkassky

Neural network meta‐model of fibrous materials based on discrete‐event simulation. Part 2: Neural network meta‐model. J Text Inst 2011; 102: 475–482.

Huang

Zhang

Zhong

, et al. The behavior between fluid and structure from coupling system of bile, bile duct, and polydioxanone biliary stent: A numerical method. Med Eng Phys 2023; 113: 103966.

Jiang

Kuang

, et al. Simulation on fiber random arrangement in the yarn. J Text Inst 2014; 105: 1312–1318.

Jiang

Kuang

Yang

, et al. Simulation on fiber random arrangement in the yarn. Part II: Joint effect of fiber length and fineness distribution. J Text Inst 2017; 108: 347–352.

Liu

Dong

Chen

, et al. Biodegradable and cytocompatible hydrogel coating with antibacterial activity for the prevention of implant-associated infection. ACS Appl Mater Interfaces 2023; 15: 11507–11519.

Martindale

JG.

A new method of measuring the irregularity of yarns with some observations on the origin of irregularities in worsted slivers and yarns. J Text Inst Trans 1945; 36: 35–47.

Rao

JS.

A mathematical model for the ideal sliver and its applications to the theory of roller drafting. J Text Inst Trans 1961; 52: 571–601.

10.

Yan

Zhu

, and Yu

A new approach to theoretical yarn unevenness: A binomial distribution model. J Text Inst 2010; 101: 753–757.

11.

Yang

Shen

, and Zhang

A study of fiber configuration in sliver fiber arrangement and its influence on sliver limit irregularity. Text Res J 2019; 89: 4799–4807.

12.

Zhang

Effect of fiber shape and arrangement on yarn or sliver irregularity. M.S. Thesis, Donghua University, China, 2016.

13.

Cao

Qian

, et al. Simulation of sliver blending and evaluation of blending irregularity. Text Res J 2022; 92: 2895–2908.

14.

Qian

, et al. Simulation study on effect of drafting on sliver unevenness. J Text Res 2021; 42: 85–90.

15.

Liu

Zhu

Zhong

, et al. Study of sliver irregularity caused by fiber acceleration motion during the drafting process. Text Res J 2024; 94: 704–712.

16.

Sun

Simulation of drawing process based on fiber arrangement in the sliver with straightness and separation degree. Text Res J 2022; 92: 242–252.

17.

Sun

Simulation on the fiber arrangement and distribution in the drafting zone. Text Res J 2022; 92: 1113–1125.

18.

Sun

Simulation on roller drafting based on hook fiber arrangement in the sliver. Fibers Polym 2021; 22: 1170–1179.

19.

Gao

Study on the fiber separation degree by weight method. J Text Res 1989; 10: 9–11.

20.

Sun

Wang

Liu

, et al. Simulation of fiber configuration in the sliver with the straightness and separation degree. Text Res J 2023; 93: 5475–5484.

21.

Sun

Simulation of fiber arrangement in the sliver with fiber separation degree. J Nat Fibers 2022; 19: 1419–1427.

22.

Zhang

Yan

Study on evaluating the carding quality of carding roller. J Text Res 1987; 8: 517–522.

23.

Zhao

Shen

Study on evaluating the carding quality by measuring fiber separation degree. Cotton Text Technol 1989; 17: 516–520.

Simulation of the fiber arrangement in a sliver based on the distribution of the sliver linear density

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