棉/生物基弹性聚酯纤维混纺针织物的服用性能

doi:10.13475/j.fzxb.20211202501

纺织学报 ›› 2023, Vol. 44 ›› Issue (05): 119-124.doi: 10.13475/j.fzxb.20211202501

棉/生物基弹性聚酯纤维混纺针织物的服用性能

苏旭中¹(), 梁巧敏¹, 王汇锋², 张娣³, 崔益怀⁴

1.江南大学纺织科学与工程学院, 江苏无锡 214122
2.必维申优质量技术服务江苏有限公司, 江苏江阴 214400
3.无锡市金茂对外贸易有限公司, 江苏无锡 214122
4.南通双弘纺织有限公司, 江苏南通 226661

收稿日期:2021-12-13 修回日期:2022-07-15 出版日期:2023-05-15 发布日期:2023-06-09
作者简介:苏旭中(1982—),男,副研究员,博士。主要研究方向为纱线成形理论、纺纱新技术、新型纺纱装备等。E-mail:mfgucv@163.com。
基金资助:
江苏省先进纺织工程技术中心协同创新基金项目(XJFZ/2021/17);江苏省自然科学基金青年基金项目(BK20170169);国家重点研发计划项目(2017YFB0309200)

Wearability of knitted fabrics produced from cotton/bio-based elastic polyester fiber

SU Xuzhong¹(), LIANG Qiaomin¹, WANG Huifeng², ZHANG Di³, CUI Yihuai⁴

1. College of Textile and Apparel, Jiangnan University, Wuxi, Jiangsu 214122, China
2. BV Shenyou Quality and Technical Service Jiangsu Co., Ltd., Jiangyin, Jiangsu 214400, China
3. Wuxi Jinmao Foreign Trade Co., Ltd., Wuxi, Jiangsu 214122, China
4. Nantong Shuanghong Textile Co., Ltd., Nantong, Jiangsu 226661, China

Received:2021-12-13 Revised:2022-07-15 Published:2023-05-15 Online:2023-06-09

摘要/Abstract

摘要：

针对生物基弹性聚酯(PTT)纤维因自身特性难以单独成条纺纱的问题,设计在清花工序运用3种不同形态棉纤维辅助PTT纤维成卷成条,并采用赛络纺方式制成线密度为14.7 tex的棉/PTT纤维(60/40)混纺纱,然后织成纬平针织物比较分析其顶破性、起毛起球性、耐磨性、透气性、透湿性及悬垂性能,最后用模糊综合评判模型对织物性能进行综合评判。结果表明:棉纤维的伸直程度高,可加大与PTT纤维间的摩擦力,提高了混纺针织物的顶破性、抗起毛起球性、透气性;织物表面PTT纤维含量多,则耐磨性较佳;而透湿性与悬垂性能与棉纤维形态基本无关。基于模糊评价模型判定,选用精梳棉条辅助PTT纤维成卷的混纺针织物的综合服用性能较佳。

关键词: 生物基弹性聚酯纤维, 棉纤维, 混纺纱, 针织物, 服用性能, 赛络纺

Abstract:

Objective Bio-based elastic polyester (PTT) fiber is the only biomass elastic staple fiber that can be commercially produced at present in line with the promotion of environmental protection. PTT fiber has a good development prospect, but is unable to spin yarns from pure PTT fibers at this stage. This paper reports a new spinning scheme for producing cotton/PTT fiber blended yarns and reports on the analysis and comparison of the properties of knitted fabrics from this blended yarn.

Method Three different forms of cotton fibers were adopted to assist PTT fibers in the blowing process to form cotton rolls and slivers. Cotton/PTT fiber (60/40) blended yarn with a linear density of 14.7 tex was produced by siro spinning, which was used for producing a weft knitted fabric. The properties of bursting, pilling, abrasion resistance, air permeability, moisture permeability and drape of the fabric were measured and analyzed. Then the fabric properties were comprehensively evaluated by using fuzzy evaluation method. The forms of cotton fibers blended with the PTT fiber were carded sliver, carded net and combed sliver respectively, and the corresponding yarns were named as a, b and c.

Results The longitudinal shape of the PTT fiber is similar to the curl of a spring (Fig.1). The performance parameters of the selected fiber materials were shown that the linear density of cotton fiber was smaller and the average length was shorter than that of the PTT fiber, but the breaking strength and moisture regain are larger (Tab.1). Elongation at break of PTT fiber was high. According to the performance test results of three sets of 14.7 tex cotton/PTT fiber (60/40) blended siro yarns, blended yarns with combed sliver assisted with PTT showed smaller evenness coefficient, less hairiness, and larger breaking strength and elongation(Tab.2). The basic parameters of the Rnitted fabric can be seen that the course and wale densities showed little difference from the uniform set value (Tab.3). By comparing the test data of the Rnitted fabrics, it was concluded that fabric C had higher bursting strength, better anti-pilling effect and better air permeability, and fabric B had good wear resistance, and fabric A illustrated good moisture permeability. The fuzzy comprehensive evaluation model was established to evaluate the fabric comprehensively, and the evaluation function of fabric C was greater than that of fabrics A and B. Fabric C showed high bursting strength and high anti-pilling grade, indicating good durability and breathability of the fabric. The static drape coefficient was found small, suggesting that the fabric had good softness and was suitable for casual wear.

Conclusion The cotton fiber in the blended yarn has a highly straightened, which can increase the friction between the cotton and PTT fibers to improve the bursting property, anti-pilling and air permeability of blended yarn knitted fabric. It is also revealed that the amount of PTT fiber on the surface in the fabric leads to better wear resistance, however the moisture permeability and drapability of the fabrics have little influence on cotton fiber morphology. Based on the fuzzy evaluation model, the combed sliver of cotton fiber is effective to assist the PTT fiber to form a cotton roll, and the comprehensive wearing performance of its blended yarn fabric is better.

Key words: bio-based elastic polyester fiber, cotton fiber, blended yarn, knitted fabric, wearability, siro spinning

中图分类号:

TS102.5

苏旭中, 梁巧敏, 王汇锋, 张娣, 崔益怀. 棉/生物基弹性聚酯纤维混纺针织物的服用性能[J]. 纺织学报, 2023, 44(05): 119-124.

SU Xuzhong, LIANG Qiaomin, WANG Huifeng, ZHANG Di, CUI Yihuai. Wearability of knitted fabrics produced from cotton/bio-based elastic polyester fiber[J]. Journal of Textile Research, 2023, 44(05): 119-124.

图/表 6

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图2

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纤维种类	线密度/ dtex	平均长度/ mm	断裂强度/ (cN·dtex^-1)	断裂伸长率/%	回潮率/ %
棉纤维	1.83	27.89	3.02	6.10	8.70
PTT纤维	2.00	37.30	2.55	18.64	0.69

试样编号	条干不匀系数/%	毛羽 H值	断裂强度/ (cN·tex^-1)	单强变异系数/%	断裂伸长率/%
a	14.21	4.11	15.16	3.6	6.16
b	13.69	4.17	15.50	7.3	6.10
c	12.66	4.09	16.31	5.9	6.68

织物编号	厚度/ mm	面密度/ (g·m^-2)	横密/(纵行· (5 cm)^-1)	纵密/(横列· (5 cm)^-1)
A	0.431 0	102.8	66	120
B	0.421 2	103.2	64	112
C	0.419 8	103.6	64	120

试样编号	顶破强力/N	抗起毛起球等级	织物质量减少率/%	透气率/ (mm·s^-1)	透湿率/(g·m^-2·d^-1)	静态悬垂系数
A	363.9	3.5	0.39	2 347.7	6 606.4	27.98
B	399.1	4.0	0.48	2 353.6	6 091.9	26.06
C	424.3	4.5	0.43	2 675.3	6 063.6	24.64

棉/生物基弹性聚酯纤维混纺针织物的服用性能

Wearability of knitted fabrics produced from cotton/bio-based elastic polyester fiber

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