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Abstract

To address the critical challenge of simultaneously achieving low hairiness and high strength in composite yarns with high fiber utilization, this study pioneered the integration of fiber-spreading and external-feeding devices onto a ring spinning frame. Firstly, by precisely controlling cotton short fiber contents (7.73%, 8.40%, 14.75%) and filament feeding paths, three composite yarn structures were engineered: a traditional polyester/cotton composite structural yarn (T-CSY); an internally fed filament spreading composite structural yarn (IFS-CSY), in which spread filaments form a web structure enhancing fiber-filament friction; and an externally fed filament spreading composite yarn (EFS-CSY), featuring spread filaments encapsulating short fibers to optimize surface coverage. Then, the properties of the composite yarns prepared with different structures were tested. Results demonstrate that, at 8.40% cotton short fiber content, the IFS-CSY had significantly enhanced tensile properties, exhibiting 2% and 20% higher strength than T-CSY and EFS-CSY, respectively, and elongation at break improvements of 32.81% and 46%. Conversely, EFS-CSY effectively encapsulated fiber ends through continuous outer wrapping, reducing total hairiness by 89.25% and 63.49% versus T-CSY and IFS-CSY while improving yarn evenness. This breakthrough in the encapsulation mechanism successfully overcomes the long-standing trade-off between surface quality (hairiness control) and mechanical robustness in high-utilization composite yarns, leading to substantially upgraded overall performance.

Keywords

Multi-axial spinning optimized shaft system staple fiber content composite structural yarn composite yarn properties

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High-fiber utilization,low-hairiness composite structural yarns based on novel spreading–feeding strategy

Abstract

Keywords

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References