THERMAL SCIENCE

International Scientific Journal

Authors of this Paper

External Links

NUMERICAL APPROACH TO HIGH-THROUGHPUT OF NANOFIBERS BY A MODIFIED BUBBLE-ELECTROSPINNING

ABSTRACT
Nanofibers were prepared in large quantities using a modified bubble-electro-spinning, where the distribution of electric field played an important role, and its distribution was studied numerically using 3-D Maxwell equation and verified experimentally. The results showed the increase of electric field strength could decrease the nanofiber diameter and enhance the nanofiber production.
KEYWORDS
PAPER SUBMITTED: 2019-03-29
PAPER REVISED: 2019-09-15
PAPER ACCEPTED: 2019-09-20
PUBLISHED ONLINE: 2020-06-21
DOI REFERENCE: https://doi.org/10.2298/TSCI2004367Y
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2020, VOLUME 24, ISSUE Issue 4, PAGES [2367 - 2375]
REFERENCES
  1. Tian, D., et al., Geometrical Potential and Nanofiber Membrane's Highly Selective Adsorption Property, Adsorption Science & Technology, 37 (2019), 5-6, pp. 367-388
  2. Li, X. X., et al., Nanoscale Adhesion and Attachment Oscillation Under the Geometric Potential, Part 1: The Formation Mechanism of Nanofiber Membrane in the Electrospinning, Results in Physics, 12 (2019), Mar., pp. 1405-1410
  3. He, J. H., et al., Review on Fiber Morphology Obtained by Bubble Electrospinning and Blown Bubble Spinning, Thermal Science, 16 (2012), 5, pp. 1263-1279
  4. Liu, Z., et al., Active Generation of Multiple Jets for Producing Nanofibres with High Quality and High Throughput, Materials & Design, 94 (2016), Mar., pp. 496-501
  5. Liu, Z., et al., Tunable Surface Morphology of Electrospun PMMA Fiber Using Binary Solvent, Applied Surface Science, 364 (2016), Feb., pp. 516-521
  6. Liu, Z., et al., Needle-Disk Electrospinning Inspired by Natural Point Discharge, Journal of Materials Science, 52 (2017), 4, pp. 1823-1830
  7. Li, Y., He, J. H., Fabrication and Characterization of ZrO2 Nanofibers by Critical Bubble Electrospin-ning for High-Temperature-Resistant Adsorption and Separation, Adsorption Science & Technology, 37 (2019), 5-6, pp. 425-437
  8. Zhou, C. J., et al., Silkworm-Based Silk Fibers by Electrospinning, Results in Physics, 15 (2019), Dec., 102646
  9. Chen, R. X., et al., Numerical Approach to Controlling a Moving Jet's Vibration in an Electrospinning System: An Auxiliary Electrode and Uniform Electric Field, Journal of Low Frequency Noise, Vibration and Active Control, 38 (2019), 3-4, pp. 1687-1698
  10. Zhao, J. H, et al., Needle's Vibration in Needle-Disk Electrospinning Process: Theoretical Model and Experimental Verification, Journal of Low Frequency Noise, Vibration and Active Control, 38 (2019) 3-4, pp. 1338-1344
  11. Kishimoto, Y., et al., Comparisons between Silk Fibroin Nonwoven Electrospun Fabrics Using Aqueous and Formic Acid Solutions, International Journal of Polymeric Materials and Polymeric Biomaterials, 67 (2018), Mar., pp. 462-467
  12. Song, Y. H., et al., Preparation and Characterization of Highly Aligned Carbon Nano-tubes/Polyacrylonitrile Composite Nanofibers, Polymers, 9 (2017), 1, ID 1
  13. Liu, X. K., et al., Tunable Zero-Order Drug Delivery Systems Created by Modified Triaxial Electrospin-ning, Chemical Engineering journal, 356 (2018), Jan., pp. 886-894
  14. Mehrasa, M., et al., Electrospun Aligned PLGA and PLGA/Gelatin Nanofibers Embedded with Silica Nanoparticles for Tissue Engineering, International Journal of Biological Macromolecules, 79 (2015), 9, pp. 687-695
  15. Kadam, V.V., et al., Electrospun Nanofibre Materials to Filter Air Pollutants - A review, Journal of In-dustrial Textiles, 47 (2018), 8, pp. 2253-2280
  16. Armer, C. F., et al., Electrospun Vanadium-Based Oxides as Electrode Materials, Journal of Power Sources, 395 (2018), Aug., pp. 414-429
  17. Ding, B., et al., Fabrication of Blend Biodegradable Nanofibrous Nonwoven Mats Via Multi-Jet Electro-spinning, Polymer, 45 (2004), 6, pp. 1895-1902
  18. Theron, S. A., et al., Multiple Jets in Electrospinning: Experiment and Modeling, Polymer, 46 (2005), 9, pp. 2889 -2899
  19. He, J. H., et al., Biomimic Fabrication of Electrospun Nanofibers with High-Throughput, Chaos Solitons & Fractals, 37 (2008), 3, pp. 643-651
  20. Shao, Z. B., et al., High-Throughput Fabrication of Quality Nanofibers Using a Modified Free Surface Electrospinning, Nanoscale Research Letters, 12 (2017), 1, ID 470
  21. Fang, Y., et al., High-Throughput Preparation of Silk Fibroin Nanofibers by Modified Bubble-Electrospinning, Nanomaterials, 8 (2018), 7, ID 471
  22. Yu, L., et al., High Throughput Preparation of Aligned Nanofibers Using an Improved Bubble-electrospinning, Polymers, 9 (2017), 12, ID 658
  23. Shao, Z. B., et al., Formation Mechanism of Highly Aligned Nanofibers by a Modified Bubble-Electrospinning, Thermal Science, 22 (2018), 1A, pp. 5-10
  24. Tang, X. P., et al., Effect of Flow Rate on Diameter of Electrospun Nanoporous Fibers, Thermal Sci-ence, 18 (2014), 5, pp. 1439-1441
  25. Zhao, J. H., et al., Experimental and Theoretical Study on the Electrospinning Nanoporous Fibers Pro-cess, Materials Chemistry and Physics, 170 (2016), 6, pp. 294-302
  26. He, J. H. A Modified Li-He's Variational Principle For Plasma, International Journal of Numerical Methods for Heat and Fluid Flow, On-line first, doi.org/10.1108/HFF-06-2019-0523, 2019
  27. He, J. H. Lagrange Crisis and Generalized Variational Principle for 3-D unsteady flow, International Journal of Numerical Methods for Heat and Fluid Flow, On-line first, doi.org/10.1108/HFF-07-2019-0577, 2019
  28. He, J. H., Sun, C., A Variational Principle for a thin Film Equation, Journal of Mathematical Chemistry. 57(2019), 9, pp. 2075-2081

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence