Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (10): 191-199.doi: 10.13475/j.fzxb.20230803201

• Machinery & Equipment • Previous Articles     Next Articles

Electric field simulation and optimization on petal shaped electrospinning nozzle with multiple tips

LIU Jian1,2(), DONG Shoujun1, WANG Chenghao1, LIU Yongru2, PAN Shanshan1, YIN Zhaosong1   

  1. 1. School of Mechanical Engineering, Tiangong University, Tianjin 300387, China
    2. Center of Engineering Practice Training, Tiangong University, Tianjin 300387, China
  • Received:2023-08-13 Revised:2024-08-14 Online:2024-10-15 Published:2024-10-22

RichHTML

2

PDF (PC)

6

Abstract:

Objective Aiming at the existing problems of multi-needle electrospinning and needleless electrospinning, petal shaped electrospinning nozzle with multiple tips is proposed and used as the emitting electrode. In the electrospinning process, the structure of the emitting electrode has a great influence on the intensity and distribution of the electric field, and has been an important research object. Therefore, it is necessary to design a new electrospinning emitting electrode and optimize the specific parameters of the new emitting electrode.

Method The nozzle was designed as a semi-closed structure. The upper part was divided into a cylindrical straight pipe multi-channel structure, using the method of equal cross-sectional area of each channel, so as to divide the flow evenly while slowing down the flow speed. The lower part was divided into petal shaped flow channel expansion structure. The curve of petal shaped flow channel was designed by Bezier curve, and the end of the petal was the tip to stimulate multiple jets under low energy consumption. COMSOL finite element analysis software was used to simulate the three-dimensional electric field and find the improved methods of increasing the field intensity and reducing end effect. Finally, experiments were carried out validate of the model.

Results The distribution and change of electrospinning electric field of the new type of electrospinning nozzle were simulated. With the increase of the number of petals, the average electric field intensity of the petal tip decreases from 4.446×106 V/m to 3.336×106 V/m due to the fact that the coulomb repulsion interaction between petals became more obvious, suggesting that the number of petals should not be too many. By comparing the electric field intensity and CV value at the tip of different petal lengths, the field was most uniform when there were four pairs of petals. When the length of the outer petal was fixed, the electric field intensity CV value of the petal tip all showed a trend of decreasing first to a certain value and then increasing with the length of the inner petal changing from short to long. Compared with the parameter models with the best electric field CV value in each group, under the condition that the droplet was fully spread and formed normally, the electric field CV value was the best when the inner petal length was 20 mm and the outer petal length was 21 mm, and the value was 6.74%. The capillary effect was used to widen the petals and the distance between each petal was 4 mm, in order to drain the liquid supply and prevent the solution from leaking in the gap between the petals. After the petal dislocation arrangement, the average electric field intensity became 5.441×106 V/m, and the electric field intensity CV value reached 5.58%, indicating that increasing the average distance between petal tips can effectively improve the uniformity of the electric field intensity. Finally, the metal 3D printing nozzle was used for experimental verification, and the fiber film was obtained. Surface morphology and fiber diameter distribution were examined by Hitachi Flex SEM1000 cold field scanning electron microscope, and the average diameter of the fibers was 258.69 nm with CV value being 15.54%.

Conclusion Petal shaped electrospinning nozzle with multiple tips is proposed in this paper. The optimal structural parameters are 4 pairs of petals, 21 mm length of inner petals, and 20 mm length of outer petals, together with the dislocation arrangement of inner and outer petals. The finite element analysis shows that the new nozzle can effectively combine the advantages of needle and needle-free electrospinning, produce high field intensity and uniform distribution of electrostatic field and can effectively avoid solution volatilization and environmental pollution. The experimental results show that each tip of the petal-like multi-tip electrospinning nozzle can produce a stable and continuous jet, and the total spinning area is large, and the generated fibers are fine and uniform.

Key words: electrospinning, petal-shaped nozzle, multi-tip, COMSOL, electric field simulation

CLC Number: 

  • TS174.8

Fig.1

Model of petal shaped electrospinning nozzle with multi-tip. (a) Main view; (b) Top view"

Fig.2

Schematic diagram of multi-channel distribution of cylindrical straight pipe"

Fig.3

Unilateral curves of petals"

Fig.4

Electrospinning system model of petal shaped nozzle with multi-tip"

Fig.5

Effect of different petal logarithm on electric field intensity. (a) Electric field cloud image of electrospinning nozzle (b) Electric field intensity and CV value"

Fig.6

Electric field intensity cloud image and CV value of electrospinning nozzle with different petal length(Lout=10, 20 mm) electric field intensity CV value"

Fig.7

Electric field intensity cloud image and CV value of electrospinning nozzle with different petal length(Lout=30 mm)"

Tab.1

Average electric field intensity of electrospinning nozzle with different inner and outer petal lengths"

Lout=10 mm Lout=20 mm Lout=30 mm
Lin
长度		 电场强度
平均值		 Lin
长度		 电场强度
平均值		 Lin
长度		 电场强度
平均值
6.0 5.892 16.0 3.244 26.0 2.951
7.0 5.796 17.0 3.382 27.0 3.094
8.0 6.364 18.0 3.535 28.0 3.020
9.0 5.723 19.0 3.589 29.0 3.406
10.6 6.249 20.6 4.198 30.6 3.638
11.0 6.666 21.0 3.763 31.0 3.643
12.0 7.777 22.0 3.540 32.0 3.344
13.0 8.393 23.0 3.474 33.0 3.405
14.0 7.634 24.0 3.765 34.0 3.293

Fig.8

Petal center seam treatment of electrospinning nozzle"

Fig.9

Electric field cloud image(a) and tip electric field intensity value(b) of petal dislocation arrangement of electrospinning nozzle"

Fig.10

Metallic petal shaped multi-tip electrospinning nozzle. (a) Top view; (b) Side view"

Fig.11

Electrospinning situation of petal shaped multi-tip nozzle"

Fig.12

Electrospinning fiber membrane"

Fig.13

SEM image(a) and diameter distribution(b) of nanofiber membrane"

[1] LEE J, MOON S, LAHANN J, et al. Recent progress in preparing nonwoven nanofibers via needleless electrospinning[J]. Macromolecular Materials and Engineering, 2023. DOI: 10.1002/mame.202300057.
[2] SHI S, SI Y, HAN Y, et al. Recent progress in protective membranes fabricated via electrospinning: advanced materials, biomimetic structures, and functional applications[J]. Advanced Materials, 2022, 34(17): 1-31.
[3] 王艳芝. 静电纺丝技术发展简史及应用[J]. 合成纤维工业, 2018, 41(4): 52-57.
WANG Yanzhi. Development history and application of electrospinning technology[J]. Synthetic Fiber Industry, 2018, 41(4): 52-57.
[4] 刘辰昊, 卞烨, 张波. 静电纺丝纳米纤维复合材料及其在环境领域的应用[J]. 现代化工, 2023, 43(7): 63-67.
LIU Chenhao, BIAN Ye, ZHANG Bo. Electrospinning nanofiber composites and their application in environmental field[J]. Modern Chemical Industry, 2023, 43(7): 63-67.
[5] 刘鹏. 静电纺丝在生物医用材料领域的应用综述[J]. 山东纺织经济, 2020(4): 26-28, 39.
LIU Peng. Application of electrospinning in biomedical materials[J]. Shandong Textile Economy, 2020(4): 26-28, 39.
[6] XUE J, WU T, DAI Y, et al. Electrospinning and electrospun nanofibers: methods, materials, and applications[J]. Chemical Reviews, 2019, 119(8): 5298-5415.
doi: 10.1021/acs.chemrev.8b00593 pmid: 30916938
[7] 谢概, 宋庆松, 邓德鹏, 等. 无针头静电纺丝研究进展[J]. 工程塑料应用, 2014, 6(42): 117-122.
XIE Gai, SONG Qingsong, DENG Depeng, et al. Research progress of electrospinning without needle[J]. Engineering Plastics Application, 2014, 6(42): 117-122.
[8] 卓丽云, 朱自明, 郑高峰. 多射流静电纺丝稳定性的影响分析[J]. 工程塑料应用, 2020, 48(10): 59-64.
ZHUO Liyun, ZHU Ziming, ZHENG Gaofeng. Influence analysis of multi-jet electrospinning stabi-lity[J]. Application of Engineering Plastics, 2020, 48(10): 59-64.
[9] TOMASZEWSKI W, SZADKOWSKI M. Investigation of electrospinning with the use of a multi-jet electrospinning head[J]. Fibres and Textiles in Eastern Europe, 2005, 13(4): 22-26.
[10] 张艳萍, 张莉彦, 马小路, 等. 无针静电纺丝技术工业化进展[J]. 塑料, 2017, 46(2): 1-4.
ZHANG Yanping, ZHANG Liyan, MA Xiaolu, et al. Progress in industrialization of needle-free electrospinning technology[J]. Plastics, 2017, 46(2): 1-4.
[11] LIU Z, ZHAO J, ZHOU L, et al. Recent progress of the needleless electrospinning for high throughput of nanofibers[J]. Recent Patents on Nanotechnology, 2019, 13(3): 164-170.
doi: 10.2174/1872210513666190426151150 pmid: 32026765
[12] 付鹏飞. 贝塞尔曲线在汽车设计中的运用[J]. 企业技术发, 2012, 31(26): 46-47, 91.
FU Pengfei. Application of Bezier curve in automobile design[J]. Enterprise Technology Development, 2012, 31(26): 46-47,91.
[13] 刘延波, 周聪, 郝铭, 等. 二次分形螺线纺丝头设计及其对场强的影响[J]. 现代纺织技术, 2023, 31(3): 12-20.
LIU Yanbo, ZHOU Cong, HAO Ming, et al. Design of secondary fractal spiral spinning head and its influence on field intensity[J]. Advanced Textile Technology, 2023, 31(3): 12-20.
[14] LIU J, LIU Y, BUKHARI S H, et al. Field intensity simulation and optimization of a solid needle electrospinning device[J]. Chemical Journal of Chinese Universities, 2017, 38(6): 1011-1017.
[15] BAUTISTA E V, BARILLAS J L M, DUTRA Jr T V, et al. Capillary, viscous and gravity forces in gas-assisted gravity drainage[J]. Journal of Petroleum Science and Engineering, 2014, 122: 754-760.
[16] 李艳娟, 孙立新, 杨静芬, 等. 蒸压加气混凝土毛细吸水试验中尺寸效应的影响研究[J]. 建筑节能, 2020, 48(9): 71-73, 138.
LI Yanjuan, SUN Lixin, YANG Jingfen, et al. Study on the influence of size effect on capillary water absorption test of autoclaved aerated concrete[J]. Building Energy Conservation, 2020, 48(9): 71-73, 138.
[1] ZHANG Dianping, WANG Hao, LIN Wenfeng, WANG Zhenqiu. Simulation and design of multi-nozzle spinning device [J]. Journal of Textile Research, 2024, 45(10): 200-207.
[2] WANG Qingpeng, ZHANG Haiyan, WANG Yuting, ZHANG Tao, ZHAO Yan. Preparation and properties of polyethylene oxide/Al2O3 passive radiative cooling membrane [J]. Journal of Textile Research, 2024, 45(09): 33-41.
[3] WANG Yongzheng, HUANG Lintao, SONG Fuquan. Process optimization and properties of petroleum pitch/polyacrylonitrile electrospun carbon nanofibers [J]. Journal of Textile Research, 2024, 45(08): 107-115.
[4] YAN Di, WANG Xuefang, TAN Wenping, GAO Guojin, MING Jinfa, NING Xin. Preparation of porous poly(L-lactic acid) nanofiber membranes with rich imidazole groups and dual performances in water purification [J]. Journal of Textile Research, 2024, 45(08): 116-126.
[5] QIAN Yang, ZHANG Lu, LI Chenyang, WANG Rongwu. Preparation and performance of electrospun sodium alginate composite nanofiber membranes [J]. Journal of Textile Research, 2024, 45(08): 18-25.
[6] LIU Jiawei, JI Dongxiao, QIN Xiaohong. Research progress in electrospun nanofiber materials for air filtration [J]. Journal of Textile Research, 2024, 45(08): 35-43.
[7] LIU Delong, WANG Hongxia, LIN Tong. Research progress in airflow-assisted electrospinning [J]. Journal of Textile Research, 2024, 45(08): 44-53.
[8] YU Wen, DENG Nanping, TANG Xiangquan, KANG Weimin, CHENG Bowen. Review on preparation and applications of electro-blown spun micro-nano inorganic fibers [J]. Journal of Textile Research, 2024, 45(07): 230-239.
[9] LIU Sitong, JIN Dan, SUN Dongming, LI Yixuan, WANG Yanhui, WANG Jing, WANG Yuan. Research progress of nanofiber structure prepared by electrospinning [J]. Journal of Textile Research, 2024, 45(06): 201-209.
[10] XU Zhenkai, MA Ming, LIN Duojia, LIU Hang, ZHANG Jianfeng, XIA Xin. Preparation and electrochemical properties of self-supporting polypyrrilone-based carbon fiber anode materials [J]. Journal of Textile Research, 2024, 45(06): 23-31.
[11] LI Zhikun, YU Ying, ZUO Yuxin, SHI Haoqin, JIN Yuzhen, CHEN Hongli. Analysis of flexoelectric effect of polyacrylonitrile/MoS2 composite film and its applications [J]. Journal of Textile Research, 2024, 45(05): 27-34.
[12] SONG Beibei, ZHAO Haoyue, LI Xinyu, QU Zhan, FANG Jian. Application of MXene-loaded cobalt-nitrogen doped carbon nanofibers in lithium-sulfur batteries [J]. Journal of Textile Research, 2024, 45(04): 24-32.
[13] JIA Lin, DONG Xiao, WANG Xixian, ZHANG Haixia, QIN Xiaohong. Preparation and performance of polycaprolactone/MgO composite nanofibrous filter membrane [J]. Journal of Textile Research, 2024, 45(04): 59-66.
[14] LU Yaoyao, YE Juntao, RUAN Chengxiang, LOU Jin. Preparation and photocatalytic performance of titanium dioxide/porous carbon nanofibers composite material [J]. Journal of Textile Research, 2024, 45(04): 67-75.
[15] YANG Qi, DENG Nanping, CHENG Bowen, KANG Weimin. Preparation and application properties of dendritic sulfonated polyethersulfone fiber based composite solid electrolyte [J]. Journal of Textile Research, 2024, 45(03): 1-10.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd