混纺比对生物基锦纶56短纤/棉混纺纱力学性能的影响

doi:10.13475/j.fzxb.20211100306

纺织学报 ›› 2023, Vol. 44 ›› Issue (03): 49-54.doi: 10.13475/j.fzxb.20211100306

混纺比对生物基锦纶56短纤/棉混纺纱力学性能的影响

吴佳庆¹, 王怡婷², 何欣欣³, 郭亚飞⁴, 郝新敏⁴, 王迎¹(), 宫玉梅¹

1.大连工业大学纺织与材料工程学院, 辽宁大连 116034
2.国家先进功能纤维创新中心, 江苏苏州 215228
3.优纤科技(丹东)有限公司, 辽宁丹东 118303
4.军事科学院系统工程研究院, 北京 100082

收稿日期:2021-11-01 修回日期:2022-12-20 出版日期:2023-03-15 发布日期:2023-04-14
通讯作者: 王迎(1976—),女,教授,博士。主要研究方向为纺纱技术。E-mail:wangying@dlpu.edu.cn。
作者简介:吴佳庆(1994—),男,硕士生。主要研究方向为生物基锦纶纤维的开发与应用。
基金资助:
辽宁省重大科技专项项目(2019JH1/10100010);国家自然科学基金项目(U1808211)

Influence of blending ratio on mechanical properties of bio-polyamide 56 staple fiber/cotton blended yarn

WU Jiaqing¹, WANG Yiting², HE Xinxin³, GUO Yafei⁴, HAO Xinmin⁴, WANG Ying¹(), GONG Yumei¹

1. School of Textile and Material Engineering, Dalian Polytechnic University, Dalian, Liaoning 116034, China
2. National Advanced Functional Fiber Innovation Center, Suzhou, Jiangsu 215228, China
3. Youxian Technology(Dandong)Co., Ltd., Dandong, Liaoning 118303, China
4. Systems Engineering Institute, Academy of Military Sciences, Beijing 100082, China

Received:2021-11-01 Revised:2022-12-20 Published:2023-03-15 Online:2023-04-14

摘要/Abstract

摘要：

针对新型生物基锦纶56的基础纺纱数据不足问题,制备了锦纶56短纤纯纺纱、纯棉纱及多种混纺比的锦纶56短纤/棉混纺纱,并分别测试了纤维、纯纺纱和混纺纱的拉伸力学性能,通过建立纤维模型和纯纺纱强度模型对混纺纱强度进行预测。结果表明:纯纺纱预测曲线上混纺纱最小强度点及整体趋势与试纺数据拟合度较好,通过纯纺纱模型可预测锦纶56短纤/棉混纺纱强度。以纤维模型为基础,利用纱线中纤维强度利用率对纤维模型进行修正,修正的纤维模型与纯纺纱模型预测结果相近,可省去纯纺纱试纺流程,快速完成混纺纱强度预测。

关键词: 生物基锦纶56, 锦纶/棉混纺纱, 混纺纱强度预测模型, 最小断裂强度点, 纤维强度利用率

Abstract:

Objective Bio-polyamide 56 (PA56) is a new type of bio-based fiber with insufficient basic spinning data. The content ratio (blending ratio) of each component fiber of blended yarn is an important factor that affects its mechanical properties and yarn function. By means of theoretical models, the relationship between yarn strength and blending ratio can be predicted, thereby speeding up production process design and shortening production lead time. This research aims to study the influence of fiber content on the mechanical properties of PA56 staple fiber/cotton blended yarn and establish its strength prediction model.

Method Cotton fiber and PA56 staple fiber were mixed to produce various blended yarns. Pure PA56 staple fiber yarn, pure cotton yarn and PA56 staple fiber/cotton blended yarn with various blending ratios were prepared on the ring spinning machine. In addition, the mechanical properties of the PA56 staple fiber and cotton fiber, and all pure yarns and blended yarns were evaluated. Prediction models for breaking strength of blended yarn were established by using pure yarn (model 1) and fiber (model 2), respectively.

Results By combining with the tensile breaking strength curves of the PA56 staple fiber pure yarn and cotton pure yarn (Fig.2) the pure yarn breaking strength predicted blended yarn strength curve (model 1) was drawn, and the predicted breaking strength expression of blended yarn was established as shown in equation 3. It could be seen that the predicted breaking strength of blended yarn decreased first and then increased with the increase of cotton content. Using model 1, the breaking strength of blended yarn was found to be the smallest when the cotton content was 52.8% (Fig.3). On the other hand, the breaking strength curve of the fiber predicted blended yarn (model 2) could be built by the tensile breaking strength curve of the PA56 staple fiber and cotton fiber (Fig.4 and the equation 3). The trend of model 2 resembled that of model 1, but the predicted minimum blended yarn breaking strength was associated to cotton content 47.9% (Fig.5). In order to verify the accuracy of the prediction model, the consistency between the measured value and the predicted value was obtained by testing the breaking strength of the PA56 staple fiber/cotton blended yarns with different cotton content (Tab.3, Fig.6). The results showed that model 1 was closer to the measured value, while model 2 was smaller than the latter. In order to modify model 2, it was proposed to use the utilization rate of fiber strength in pure yarn. The utilization rate of cotton fiber strength in pure cotton yarn was 45%, and the utilization rate of PA56 staple fiber strength in PA56 pure yarn was 40%. Furthermore, the modified fiber model of the prediction breaking strength of blended yarn (Fig.7) was obtained by combining model 2 and equation 4. The trend of the modified model 2 and the predicted minimum breaking strength cotton content of 50.9% were very close to model 1.

Conclusion The minimum breaking strength point and overall trend of blended yarn on the prediction curve of the pure yarn were well fitted with the trial spinning data, so that the model 1 can predict the breaking strength of the PA56 staple fiber/ cotton blended yarn. The model 2 needed to be modified by using the utilization rate of the fiber strength in pure yarn. The results of the modified model 2 were similar to those of the model 1. Therefor, the modified fiber model could quickly complete the prediction of blended yarn strength without the pure spinning processing flow, and it was very suitable for blending ratio design and product development of blended yarn, especially PA56 staple fiber blended yarn.

Key words: bio-polyamide 56, polyamide/cotton blended yarn, prediction model of blended yarn strength, minimum strength point, utilization rate of fiber strength

中图分类号:

TS104.1

吴佳庆, 王怡婷, 何欣欣, 郭亚飞, 郝新敏, 王迎, 宫玉梅. 混纺比对生物基锦纶56短纤/棉混纺纱力学性能的影响[J]. 纺织学报, 2023, 44(03): 49-54.

WU Jiaqing, WANG Yiting, HE Xinxin, GUO Yafei, HAO Xinmin, WANG Ying, GONG Yumei. Influence of blending ratio on mechanical properties of bio-polyamide 56 staple fiber/cotton blended yarn[J]. Journal of Textile Research, 2023, 44(03): 49-54.

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样品	断裂强力/ cN	断裂强度/ (cN·tex^-1)	断裂伸长/ mm	断裂伸长率/ %
棉纱	353.28	11.04	17.33	6.9
PA56短纤纱	475.52	14.86	72.25	28.9

样品	断裂强力/ cN	断裂强度/ (cN·dtex^-1)	断裂伸长/ mm	断裂伸长率/ %
棉纤维	3.74	3.09	1.15	11.5
PA56短纤	6.60	3.57	8.14	81.4

含棉量/%	断裂强度/(cN·tex^-1)
含棉量/%	实测值	模型1预测值
10	15.80	13.37
20	14.50	11.89
30	10.50	10.40
40	8.60	8.92
50	8.80	7.43
60	7.34	7.63
80	10.81	9.33
90	9.99	10.19

混纺比对生物基锦纶56短纤/棉混纺纱力学性能的影响

Influence of blending ratio on mechanical properties of bio-polyamide 56 staple fiber/cotton blended yarn

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