环锭纺棉/涤短纤皮芯纱的皮芯层捻度分布

doi:10.13475/j.fzxb.20230705801

摘要/Abstract

摘要：

为发挥两组分短纤维复合结构纱的性能优势,开发了一种基于环锭细纱机的新型短纤皮芯纱纺制方法。该方法的核心在于采用同轴异径前罗拉替换传统前罗拉,从而实现在环锭细纱机上一步法纺制短纤皮芯纱。通过理论分析根据纺纱三角区几何形状,计算出皮芯纱的皮层捻度。同时,通过长丝模拟示踪法和图像技术,测量了皮芯纱的皮层和芯层捻度,并分别构建了皮层和芯层捻度与设定捻度的关系模型。此外,还研究了皮芯比例和捻度对纱线性能的影响。结果表明:芯层捻度与细纱机设定捻度呈线性正相关;皮层捻度与设定捻度呈二次函数关系,同时皮层捻度的改变会影响纱线紧密度;在相同捻度下,棉/涤短纤皮芯纱的强伸性优于纯棉环锭纱,且皮芯纱的断裂强度和断裂伸长率随着捻度和芯纤维占比的增加而增加;增加捻度和芯纤维占比有利于皮芯纱条干的改善;皮芯纱的有害毛羽随着捻度的增加而减少。

关键词: 短纤皮芯纱, 异速输出, 纺纱技术, 皮层捻度, 芯层捻度, 复合结构纱

Abstract:

Objective To benefit from the performance advantages of two-component composite staple yarns, a new spinning method for sheath-core staple yarns based on ring spinning machine was developed. The twist distribution in the sheath and core layers of sheath-core staple yarn is studied because it has a significant impact on the settings of spinning process parameters and the yarn properties.

Method The conventional front roller was replaced with the coaxial front roller with different diameters. Two fiber slivers were output with different speeds at the front roller nip. The slow fiber sliver was twisted around its axis, while the fast fiber sliver was spirally wrapped around the outside of the slow counterpart, thus forming a sheath-core structure. Based on the geometry of spinning triangle, the twist in sheath layer was calculated theoretically, and the twist in sheath and core layers of sheath-core yarn were measured by the filament simulated tracer method and image technology.

Results Through the fitting analysis of the twist in sheath and core layers, it is found that the twist in sheath layer is a quadratic function of the setting twist. Additionally, the twist in sheath layer is inversely proportional to the yarn diameter, which is consistent with theoretical analysis. Furthermore, the twist in core layer exhibits a linear relationship with the setting twist. The R² values for all fitted curves exceed 0.95, indicating that the fitting results are highly reliable. The breaking strength and elongation of sheath-core yarn are superior to those of ring-spun cotton yarn. At a twist of 550 twist/m, the breaking strength and elongation of sheath-core yarn with a sheath-core proportion of 65/35 are 68.0% and 85.5% higher than those of ring-spun cotton yarn, respectively. As the setting twist and core proportion increase, the breaking strength and elongation of sheath-core staple yarn increase. This is because as the setting twist increases, the twist in sheath and core layers increase, thereby enhancing the breaking strength and elongation of sheath-core staple yarn. Additionally, it is well known that polyester fibers have superior tensile properties compared to cotton fibers. Therefore, as the core proportion increases, the tensile properties of sheath-core staple yarn improve. The CVm of sheath-core staple yarn decreases as the core proportion increases. At a twist of 550 twist/m, the CVm decreases by 7.2% when the core proportion increases from 25% to 35%. This is because, as the core proportion increases, the width of sheath fiber bundle decreases, enhancing the control over the edge fibers and reducing the loss of edge fibers. The CVm decreases as the setting twist increases. When the sheath-core proportion is 65/35, the CVm decreases by 6.0% as the twist increases from 490 to 550 twist/m. The twist of sheath and core fiber bundles in the spinning triangle increase with setting twist increases. This enhances the cohesion of fibers, reduces the loss of fibers, and thus improves the evenness of sheath-core staple yarn. The harmful hairiness of sheath-core staple yarn decreases with increasing setting twist. When the sheath-core proportion is 65/35, the harmful hairiness decreases by 8.8% as the twist increases from 490 to 550 twist/m. This is because as the setting twist increases, more fibers are involved in the yarn, resulting in reduced hairiness.

Conclusion A method of one-step spinning sheath-core staple yarn based on ring spinning machine was developed. The spinning efficiency of this method is high, and the yarn spun by this method has good properties. In addition, the relationship between twist in sheath and core layer and setting twist was established by combining theoretical modeling with experiment. The results show that the twist in sheath layer has a quadratic function relationship with setting twist, and the twist in core layer is positively linearly correlated with setting twist. The breaking strength and breaking elongation of cotton/polyester sheath-core staple yarn are better than those of cotton ring yarn at the same linear density and twist.

Key words: staple sheath-core yarn, output with different speed, spinning technique, twist in sheath layer, twist in core layer, composite structure yarn

中图分类号:

TS104.1

江文杰, 郭明瑞, 高卫东. 环锭纺棉/涤短纤皮芯纱的皮芯层捻度分布[J]. 纺织学报, 2024, 45(12): 58-66.

JIANG Wenjie, GUO Mingrui, GAO Weidong. Twist distribution in cotton/polyester sheath-core staple yarns based on ring spinning[J]. Journal of Textile Research, 2024, 45(12): 58-66.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20230705801

http://www.fzxb.org.cn/CN/Y2024/V45/I12/58

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编号	皮芯比例	纱线线密度/tex	设定捻度/(捻·m^-1)
A1	75∶25	58.3	430
A2			460
A3			490
A4			520
A5			550

编号	纱线种类	皮芯比例	粗纱定量/ (g·(10 m)^-1)		设定捻度/ (捻·m^-1)
编号	纱线种类	皮芯比例	皮层	芯层	设定捻度/ (捻·m^-1)
B1	短纤皮芯纱	75/25	12.0	3.7	490
B2					520
B3					550
B4	短纤皮芯纱	70/30	9.3	3.7	490
B5					520
B6					550
B7	短纤皮芯纱	65/35	7.4	3.7	490
B8					520
B9					550
B10	纯棉环锭纱	—	9.3		490
B11					520
B12					550

设定捻度/ (捻·m^-1)	皮层捻度/ (捻·m^-1)	皮芯纱直径/mm
430	341	0.58
460	358	0.56
490	385	0.53
520	394	0.51
550	413	0.49