Continuous preparationand properties of nanofiber core-spun yarn based on water bath electrospinning

doi:10.19398/j.att.202204028

Advanced Textile Technology ›› 2022, Vol. 30 ›› Issue (6): 80-87.DOI: 10.19398/j.att.202204028

• Textile Engineering • Previous Articles Next Articles

Continuous preparationand properties of nanofiber core-spun yarn based on water bath electrospinning

ZHOU Xinru, HU Chengye, FAN Mengjing, HONG Jianhan, HAN Xiao

a. College of Textile and Garment; b. Key Laboratory of Clean Dyeing and Finishing Technology of Zhejiang Province, Shaoxing University, Shaoxing 312000, China

Received:2022-04-16 Online:2022-11-10 Published:2022-11-16

基于水浴静电纺的纳米纤维包芯纱连续制备与性能

周歆如, 胡铖烨, 范梦晶, 洪剑寒, 韩潇

绍兴文理学院, a. 纺织服装学院; b.浙江省清洁染整技术研究重点实验室,浙江绍兴 312000

通讯作者: 韩潇,E-mail:hanxiao@usx.edu.cn
作者简介:周歆如(1998—),女,浙江台州人,硕士研究生,主要从事功能纺织品的制备与应用方面的研究。
基金资助:
浙江省公益技术研究计划项目(LGG20E030002),纺织行业智能服装柔性器件重点实验室开放课题(SDHY2112)

Abstract

Abstract: In order to prepare nanofiber aggregates that not only have the surface properties of nanofibers, but also maintain the excellent mechanical properties of traditional fibers, and to further expand the application field of nanofibers and improve the application value, a continuous preparation method of nanofiber core-spun yarn was proposed. PET/PA6 nanofiber core-spun yarn with polyester filament (PET) as core layer and nylon 6 nanofiber (PA6) as coating layer was prepared by double needle water bath electrospinning method. The effect of spinning voltage on the structure and properties of nanofiber core-spun yarn was studied. The results show that the nanofibers prepared at different voltages have a good coating effect on the core yarn. The diameter of the nanofiber decreases with the increase of the voltage. The diameter of the nanofiber is 140.80±21.34 nm at 14 kV and 91.75±13.24 nm at 20 kV, which decreases by about 1/3. With the increase of the voltage, the coating rate and linear density of the nanofiber core-spun yarn increase. When the voltage is 20 kV, the coating rate of the nanofiber core-spun yarn is 28.58%, which is about 1.5 times of the coating rate when the voltage is 14 kV. The breaking strength of the PA6 nanofiber coating is lower than that of conventional PA6 fiber, but the breaking elongation is close to that of conventional PA6 fiber.

Key words: electrospinning, water bath method, nanofiber core-spun yarn, voltage, structure and properties

摘要： 为了制备既具备纳米纤维的表面性能,又保持传统纤维优异力学性能的纳米纤维集合体,进一步拓展纳米纤维的应用领域,提高应用价值,提出了一种纳米纤维包芯纱的连续制备方法。利用双针头水浴静电纺丝法制备了以涤纶长丝(PET)为芯层,外包聚酰胺6(PA6)纳米纤维的PET/PA6纳米纤维包芯纱。研究了纺丝电压对纳米纤维包芯纱结构与性能的影响,结果表明:制备的纳米纤维在不同电压下对于芯纱都有较好的包覆;纳米纤维的直径随电压的增加而下降,14 kV时纳米纤维的直径为(140.80±21.34) nm,20 kV 时仅为(91.75±13.24) nm,下降了约1/3;随着电压的增加,纳米纤维包芯纱的包覆率和线密度都增大,当电压为20 kV时,纳米纤维包芯纱的包覆率为28.58%,约为电压14 kV时的1.5倍;PA6纳米纤维包覆层的断裂强度要低于常规的PA6纤维,但断裂伸长在常规PA6纤维的范围内。

关键词: 静电纺丝, 水浴法, 纳米纤维包芯纱, 电压, 结构与性能

CLC Number:

TQ340.69

ZHOU Xinru, HU Chengye, FAN Mengjing, HONG Jianhan, HAN Xiao. Continuous preparationand properties of nanofiber core-spun yarn based on water bath electrospinning[J]. Advanced Textile Technology, 2022, 30(6): 80-87.

周歆如, 胡铖烨, 范梦晶, 洪剑寒, 韩潇. 基于水浴静电纺的纳米纤维包芯纱连续制备与性能[J]. 现代纺织技术, 2022, 30(6): 80-87.

References

[1] 丁彬,俞建勇.功能静电纺纳米纤维材料[M].北京:中国纺织出版社,2019.
DING Bin, YU Jianyong. Functional Electrospinning Nano-fiber Materials[M]. Beijing: China Textile Press, 2019.
[2] 岳青,王绍德,徐飞,等.静电纺丝技术及其在各领域中的应用[J].材料导报,2021,35(S1):594-599.
YUE Qing, WANG Shaode, XU Fei, et al.Electrostatic spinning technology and its application in various fields [J]. Materials Reports, 2021,35(S1):594-599.
[3] LIU C K, SUN R J, LAI K, et al. Preparation of short submicron-fiber yarn by an annular collector through electrospinning [J]. Materials Letters, 2008, 62(29): 4467-4469.
[4] FAKHRALI A, EBADI S V, GHAREHAGHAJI A A, et al. Analysis of twist level and take-up speed impact on the tensile properties of PVA/PA6 hybrid nanofiber yarns [J]. E-polymers, 2016, 16(2):125-135.
[5] HAJIANI F, JEDDIA A A,GHAREHAGHAJI A A. An investigation on the effects of twist on geometry of the electrospinning triangle and polyamide-66 nanofiber yarn strength [J]. Fibers and Polymers, 2012,13(2):244-252.
[6] AFIFIA M, NAKANO S, YAMANE H, et al. Electrospin-ning of continuous aligning yarns with a funnel target [J]. Macromolecular Materials and Engineering, 2010,295(7):660-665.
[7] 郑贤宏,胡侨乐,聂文琪,等.高弹性MXene/TPU纳米纤维纱线的制备及其应变传感性能[J].精细化工,2022,39(1):80-85
ZHENG Xianhong, HU Qiaole, NIE Wenqi, et al. Prepa-ration and strain sensing performance of highly stretchable MXene/TPU nanofiber yarn[J]. Fine Chemicals, 2022, 39(1):80-85.
[8] YOUSEFZADEH M, LATIF M, TEO W E, et al. Produc-ing continuous twisted yarn from well-aligned nanofibers by
water vortex [J]. Polymer Engineering & Science, 2011, 51:323-329.
[9] LI B, LIU C K, ZHOU F L, et al. Preparation of electros-pun core-sheath yarn with enhanced bioproperties for biomedical materials[J]. Biotechnology Letters, 2018, 40(2):279-284.
[10] 刘呈坤,贺海军,孙润军,等.纺丝工艺对静电纺纳米纤维包芯纱覆盖性能的影响[J].高分子材料科学与工程,2016,32(12):82-86.
LIU Chengkun, HE Haijun, SUN Runjun, et al. Influence of spinning process on covering property of core-spun nanofiber yarn[J]. Polymer Materials Science and Engineering,2016, 32(12): 82-86.
[11] BAZBOUZ M B, STYLIOS G K. A new mechanism for the electrospinning of nanoyarns[J]. Journal of Applied Polymer Science, 2012, 124(1): 195-201.
[12] TONG X, BIN J X. Preparation and characterization of polyester staple yarns nanowrapped with polysulfone amide fibers[J]. Industrial & Engineering Chemistry Research, 2015, 54(49):12303-12312.
[13] 彭蕙,毛宁,覃小红.不同亲疏水性微纳米纤维/棉纤维包芯纱织物的导湿性能[J].东华大学学报(自然科学版),2020,46(5):694-702.
PENG Hui, MAO Ning, QIN Xiaohong. Moisture conduc-tivity of different hydrophilic submicron fiber/cotton fiber core-spun yarn fabrics[J]. Journal of Donghua University (natural science edition), 2020, 46(5): 694-702.
[14] HE J X, ZHOU Y M, WU Y C, et al. Nanofiber coated hybrid yarn fabricated by novel electrospinning-airflow twisting method[J]. Surface and Coatings Technology, 2014, 258:398-404.
[15] ZHOU Y M, WANG H B, HE J X, et al. Highly stretchable nanofiber-coated hybrid yarn with wavy structure fabricated by novel airflow-electrospinning method[J]. Materials Letters, 2019, 239:1-4.
[16] 王怡婷,詹建朝,王迎.静电纺制备聚氨酯-Fe₃O₄纳米纤维包芯纱[J].上海纺织科技,2018,46(6):41-43,48.
WANG Yiting, ZHAN Jianchao, WANG Ying. Electrospun of polyurethane-Fe₃O₄ nanofiber core-spun yarn[J]. Shanghai Textile Science & Technology, 2018, 46(6): 41-43, 48.
[17] 胡铖烨,马金星,周歆如,等.基于水浴静电纺的芳纶/PA6纳米纤维包芯纱制备与表征[J].丝绸,2022,59(1):31-37.
HU Chengye,MA Jinxing, ZHOU Xinru, et al. Preparation and characterization of PPTA/PA6 nanofiber core-spun yarn based on water bath electrospinning[J]. Journal of Silk, 2022, 59(1): 31-37.

Continuous preparationand properties of nanofiber core-spun yarn based on water bath electrospinning

基于水浴静电纺的纳米纤维包芯纱连续制备与性能

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 7

Recommended Articles

Metrics

[1]	WANG Huijia, CHEN Qiang, YI Yuqing, SHI Jingya, LI Ni. Effect of chain extension time on properties of polyurethane and electrospun nanofibers [J]. Advanced Textile Technology, 2022, 30(5): 67-73.
[2]	LI Xiao, LIU Yuanjun, ZHAO Xiaoming. Research progress of electrospinning nanofiber-based sound-absorbing materials [J]. Advanced Textile Technology, 2022, 30(5): 246-258.
[3]	SHI Min, WANG Tao, WANG Sheng. Properties and preparation of PVDF/PDMS superhydrophobic membrane for rapid oil-water separation by one-step method [J]. Advanced Textile Technology, 2022, 30(4): 108-114.
[4]	WEI Yue, WANG Sheng, JI Lülü. Synthesis of nickel sulfide-based carbon nanofibers for electrocatalytic hydrogen evolution reaction [J]. Advanced Textile Technology, 2022, 30(3): 81-88.
[5]	ZHENG Zuobao, JIA Jiao, FENG Yangyang, HOU Yijie, JIA Yongtang. Preparation of PMMA/PU new thermal retention material by electrospinning and its properties [J]. Advanced Textile Technology, 2022, 30(3): 89-96.
[6]	JIA Ziqi, WANG Chen, ZHAO Tiantian, LIU Yang. Preparation and photocatalytic performance of N-doped graphene oxide/TiO₂/PAN composite nanofiber membranes [J]. Advanced Textile Technology, 2022, 30(3): 97-107.
[7]	ZHOU Rongxin, GE Yeqian. Preparation and electrochemical properties of carbon nanofiber anode materials [J]. Advanced Textile Technology, 2022, 30(1): 41-46.