香蕉茎秆纤维/抗菌纤维混纺纱的制备及其性能

doi:10.13475/j.fzxb.20230805701

Abstract

Abstract:

Objective With the proposal of the "double carbon economy" policy, green environmental protection and sustainable development become the direction of future textile development, and Xitu it is of great significance to develop new natural plant fibers and promote the application of natural banana stem fibers in the field of textile and clothing.

Method The semi-worsted spinning process was adopted with banana stem fiber (BF), EcoCosy^R antibacterial fibers (ATB) and rare earth antibacterial regenerated cellulose fiber (XT) as raw materials. Eight types of BF/antibacterial fibers (ATB and XT) blended yarns, with blending ratio of 50/50, 65/35, 70/30 and 85/15, and one BF pure spun yarn were prepared. The yarn density and twist were characterized, and the relationship between the blending ratio and mechanical properties, quality index and antibacterial properties of the yarn was investigated.

Results The measured linear density and twist of the 9 types of yarns were different from the designed values, but the deviation was within the tolerance range. The mechanical properties of BF pure spinning are poor, with the breaking strength being (7.12±1.45) cN/tex, the elongation at break (2.56±0.43)%, and the initial modulus (247.11±81.07) cN/tex. The mechanical properties of yarns were improved with the addition of ATB and XT content. The elongation at break of BF/ATB(50/50) and BF/XT(50/50) yarns was the highest, which was (4.19±0.46)% and (4.74±0.41)%. The breaking strength of BF/ATB(85/15) and BF/XT(70/30) yarns is the highest, and they were (9.33±1.45) cN/tex and (8.97±1.28) cN/tex respectively. With the increase of the content of ATB and XT, the defects such as knots, thick knots and detail of the yarn were greatly reduced, and the evenness of yarn strip and hairiness index were improved. The yarn unevenness was decreased from 21.83% to 13.91% and 14.8% respectively, and the hair index was decreased from 6.72 mm to 5.85 mm and 5.27 mm respectively, decreasing by 13% and 22%. The bacteriostatic rate of BF pure spinning against Escherichia coli was 65.47%, and the bacteriostatic rate of yarn increased with the increase of ATB and XT content. When the ratio of BF/ATB and BF/XT blended yarn was 50/50, the inhibition rate of Escherichia coli reached the maximum, which were 88.79% and 84.76% respectively, while for Staphylococcus aureus, the content of ATB and XT had little effect on the inhibition rate, and the inhibition rate of BF pure spun yarn and blended yarn could reach more than 95%.

Conclusion The addition of ATB and XT improved the mechanical properties and antibacterial properties of BF pure spinning. In addition, it also improves the quality indexes of BF pure spun yarn, such as strip evenness, hairiness index, knots, thick knots and details, making the blended yarn have higher breaking strength, excellent antibacterial property. It is of great significance for its application and development in clothing, and is suitable for the development of leisure woven shirt fabric and knitted fabric.

Key words: banana stem fiber, antibacterial fiber, blended yarn, mechanical property, quality index of yarn, antibacterial property

CLC Number:

TS106.5

LIU Ting, YAN Tao, PAN Zhijuan. Preparation and properties of banana stem fiber/antibacterial fiber blended yarn[J].Journal of Textile Research, 2024, 45(10): 48-54.

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URL: http://www.fzxb.org.cn/EN/10.13475/j.fzxb.20230805701

http://www.fzxb.org.cn/EN/Y2024/V45/I10/48

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References 21

[1]	王红, 翁扬, 邢声远. 香蕉纤维的制备及产品开发[J]. 纺织导报, 2010(6): 105-106.
	WANG Hong, WENG Yang, XING Shengyuan. Preparation and product development of banana fiber[J]. China Textile Leader, 2010(6): 105-106.
[2]	高冰, 黄孝海, 缪祎, 等. 香蕉梗纤维的提取及其纤维毡抗菌性能研究[J]. 武汉纺织大学学报, 2023, 36(1): 31-38.
	GAO Bing, HUANG Xiaohai, MIAO Yi, et al. Research on extraction of banana stem fiber and antibacterial properties of fiber mat[J]. Journal of Wuhan Textile University, 2023, 36(1): 31-38.
[3]	盛占武. 香蕉茎秆纤维脱胶、改性及其结构性能分析[D]. 武汉: 华中农业大学, 2018:21-40.
	SHENG Zhanwu. Degumming, modification and characterization of banana pseudo-stem fiber[D]. Wuhan: Huazhong Agricultural University, 2018:21-40.
[4]	刘杰, 田雨, 孙聆芳, 等. 香蕉纤维的碱法脱胶工艺[J]. 印染助剂, 2020, 37(11): 13-15, 36.
	LIU Jie, TIAN Yu, SUN Lingfang, et al. Alkaline degumming process of banana fiber[J]. Textile Auxiliaries, 2020, 37(11): 13-15, 36.
[5]	盛占武, 郑丽丽, 高锦合, 等. 香蕉纤维酶解脱胶工艺及脱胶纤维性能[J]. 农业工程学报, 2014, 30(10): 277-284.
	SHENG Zhanwu, ZHENG Lili, GAO Jinhe, et al. Process optimization for bio-degumming of banana fiber and characteristics of degummed fibers[J]. Transactions of the Chinese Society of Agricultural Engineering, 2014, 30(10): 277-284.
[6]	黄仙, 于湖生, 李芳, 等. 香蕉纤维增强不饱和聚酯树脂复合材料的制备工艺研究[J]. 现代纺织技术, 2019, 27(3): 5-9.
	HUANG Xian, YU Husheng, LI Fang, et al. Study on preparation of unsaturated polyester resin composite reinforced by banana fiber[J]. Advanced Textile Technology, 2019, 27(3): 5-9.
[7]	BOOPATHI S, NAVEENKUMAR N, SAMPATHKUMAR P, et al. Experimental comparative study of banana fiber composite with glass fiber composite material using Taguchi method[J]. Materials Today: Proceedings, 2022, 49(5): 1475-1480.
[8]	王艳, 梁宝生, 蔡中庶. 香蕉纤维/棉混纺纱的开发与应用[J]. 上海纺织科技, 2008, 36(12): 21-22.
	WANG Yan, LIANG Baosheng, CAI Zhongshu. Development and application of banana fiber/cotton blended yarn[J]. Shanghai Textile Science & Technology, 2008, 36(12): 21-22.
[9]	蔡永东. 香蕉纤维/粘胶/天丝^TM混纺纱线家纺床品面料的生产技术[J]. 纺织导报, 2018(11): 90-92.
	CAI Yongdong. Production technology of the bedding fabrics made by banana leaf fiber/viscose/Tencel^TM blended yarn[J]. China Textile Leader, 2018(11): 90-92.
[10]	SARKAR S R, DEO S, GAYATRI M, et al. Eco-friendly banana/cotton union fabric: its preferences and potentiality[J]. International Journal of Chemical Studies, 2019, 7(3): 1533-1535.
[11]	APARNA P, DEVI A S. Geometrical and handle properties of banana blended textiles[J]. Asian Journal of Home Science, 2013, 8(1): 65-68.
[12]	JORDAN W, CHESTER P. Improving the properties of banana fiber reinforced polymeric composites by treating the fibers[J]. Procedia Engineering, 2017, 200: 283-289.
[13]	DARWISH L R, WAKAD M T E, FARAG M M, et al. The use of starch matrix-banana fiber composites for biodegradable maxillofacial bone plates[J]. 2021, 15: 115-120.
[14]	SORAISHAM L D, GOGOI N, MISHRA L, et al. Extraction and evaluation of properties of Indian banana fiber (Musa Domestica Var. Balbisiana, BB Group) and its processing with ramie[J]. Journal of Natural Fibers, 2022, 19(13):5839-5850.
[15]	BALAKRISHNAN S, WICKRAMASINGHE G, WIJAYAPALA U S. Investigation on improving banana fiber fineness for textile application[J]. Textile Research Journal, 2019, 89(21): 4398-4409.
[16]	PHIROM-ON K A J. Development of cellulose-based prebiotic fiber from banana peel by enzymatic hydrolysis[J]. Food Bioscience, 2021. DOI:10.1016/j.fbio.2021.101083.
[17]	MOSTAFA H S. Banana plant as a source of valuable antimicrobial compounds and its current applications in the food sector[J]. Journal of Food Science, 2021, 86(9): 3778-3797. doi: 10.1111/1750-3841.15854 pmid: 34337757
[18]	曾社平, 刘超, 唐建东. 再生纤维素纤维纱线特点和浆纱生产[J]. 纺织器材, 2022, 49(S1): 39-42, 64.
	ZENG Sheping, LIU Chao, TANG Jiandong. Yarn characteristic and sizing production of regenerated cellulose fiber[J]. Textile Accessories, 2022, 49(S1): 39-42, 64.
[19]	操赛洪, 徐畅, 张欢怡, 等. 抗菌优可丝安泰贝/棉混纺可降解织物的制备[J]. 上海纺织科技, 2022, 50(5): 50-51, 64.
	CAO Saihong, XU Chang, ZHANG Huanyi, et al. Preparation of biodegradable anti-bacterial EcoCosy/cotton blended fabric[J]. Shanghai Textile Science & Technology, 2022, 50(5): 50-51, 64.
[20]	韩涛. 优可丝安泰贝抗菌纤维在牛仔面料开发中的技术探讨[J]. 纺织导报, 2020(10): 44-47.
	HAN Tao. Technological discussion on the EcoCosy^® antibacterial fiber in denim development[J]. China Textile Leader, 2020(10): 44-47.
[21]	张凤, 周湘祁. 苎麻纱线毛羽成因分析及改善措施[J]. 毛纺科技, 2012, 40(6): 12-15.
	ZHANG Feng, ZHOU Xiangqi. Analysis and improvement measures of the hairiness of ramie yarn[J]. Wool Textile Journal, 2012, 40(6): 12-15.

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纤维种类	平均长度/mm	线密度/ dtex	断裂强度/ (cN·dtex^-1)	断裂伸长率/%	初始模量/ (cN·dtex^-1)	抑菌率/%
纤维种类	平均长度/mm	线密度/ dtex	断裂强度/ (cN·dtex^-1)	断裂伸长率/%	初始模量/ (cN·dtex^-1)	对大肠杆菌	对金黄色葡萄球菌
香蕉茎秆纤维(BF)	106.00	5.06	7.30	2.63	272.81	64.93	98.13
优可丝安泰贝抗菌纤维(ATB)	38.00	1.33	2.49	19.49	68.26	78.57	99.06
稀土抑菌再生纤维素纤维(XT)	38.00	1.67	2.21	19.67	58.20	82.51	99.00

实验仪器	生产厂家	实验仪器	生产厂家
YK105型开松机	青岛亿祥纺织机械厂	BS224S型Sartorious电子天平	德国赛多利斯公司
BC262型和毛机	青岛中瑞特机械制造有限公司	YG155A型纱线捻度仪	常州天荣仪器设备有限公司
A186G型梳棉机	青岛亿祥纺织机械厂	INSTRON 3365通用材料试验机	美国Instron公司
FA318A型并条机	青岛云龙纺织机械有限公司	ME100型乌斯特条干仪	瑞士USTER公司
FA503型细纱机	江阴江动纺机制造有限公司	HWS-080恒温恒湿箱	上海圣科仪器设备有限公司
USTER^®QUANTUM³型络筒机	瑞士乌斯特技术公司	THZ-103B恒温培养摇床	上海叶拓科技有限公司
YG086型缕纱测长试验仪	南通宏大实验仪器有限公司	Nuaire-NU-543-500S生物安全柜	上海天美生化仪器设备工程有限公司
JWF1436C型粗纱机	天津宏大纺织科技有限公司	YXQ-LS-18S I手提式压力蒸汽灭菌器	上海博迅医疗生物仪器股份有限公司

纱线种类	实际线密度/tex	捻度/(捻·m^-1)	捻系数
100% BF	27.54±0.04	846	444
BF/ATB(85/15)	28.07±0.08	867	459
BF/ATB(70/30)	27.68±0.07	836	440
BF/ATB(65/35)	27.30±0.04	844	441
BF/ATB(50/50)	28.07±0.01	853	452
BF/XT(85/15)	27.46±0.03	846	443
BF/XT(70/30)	28.79±0.02	855	459
BF/XT(65/35)	26.24±0.02	851	436
BF/XT(50/50)	28.99±0.01	849	457

纱线种类	断裂伸长率/%	断裂强度/ (cN·tex^-1)	初始模量/ (cN·tex^-1)
100% BF	2.56±0.43	7.12±1.45	247.11±81.07
BF/ATB(85/15)	3.69±0.53	9.33±1.45	99.16±46.56
BF/ATB(70/30)	3.77±0.46	8.67±1.48	110.50±36.99
BF/ATB(65/35)	3.07±0.42	8.03±1.06	184.89±52.78
BF/ATB(50/50)	4.19±0.46	8.74±0.93	100.04±31.83
BF/XT(85/15)	3.39±0.52	8.18±1.66	78.10±36.51
BF/XT(70/30)	4.16±0.41	8.97±1.28	58.78±23.37
BF/XT(65/35)	3.54±0.35	8.46±1.09	112.24±35.06
BF/XT(50/50)	4.74±0.41	8.34±0.83	71.82±12.44

纱线种类	细节/(个·km^-1)		粗节/(个·km^-1)		棉结/(个·km^-1)
纱线种类	-40%	-50%	+35%	+50%	+140%	+200%
BF(100%)	5 830	2 164	5 350	2 934	6 929	2 666
BF/ATB(85/15)	3 397	758	4 165	1 934	4 680	1 576
BF/ATB(70/30)	2 038	340	3 091	1 217	3 286	972
BF/ATB(65/35)	1 886	290	2 991	1 199	3 158	945
BF/ATB(50/50)	653	48	2 017	640	1 646	430
BF/XT(85/15)	3 643	917	4 301	2 011	4 764	1 636
BF/XT(70/30)	1 945	318	3 176	1 263	3 008	866
BF/XT(65/35)	1 651	264	2 975	1 149	3 030	920
BF/XT(50/50)	1 086	109	2 361	785	2 051	526

Preparation and properties of banana stem fiber/antibacterial fiber blended yarn

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