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INTERACTION OF MULTIPLE JETS IN BUBBLE ELECTROSPINNING

ABSTRACT
The bubble electrospinningis a peerless technology for mass-production of various functional nanofibers. During the spinning process, multiple jets are ejected, which might be interacted with each other. The interaction might result in mass transfer, energy transfer and force in balance, all these factors will greatly affect the mechanical property and morphology of the resultant fibers. A theoretical model is established to study the two-jets combination during the spinning process, the mass conservation and momentum conservationare considered, and the combined fiber’s diameter and moving velocity are theoretically elucidated. The present theory analysis can be easily extended to multile jets interation.
KEYWORDS
PAPER SUBMITTED: 1970-01-01
PAPER REVISED: 2022-03-08
PAPER ACCEPTED: 2022-04-02
PUBLISHED ONLINE: 2022-06-04
DOI REFERENCE: https://doi.org/10.2298/TSCI211228083L
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2023, VOLUME 27, ISSUE Issue 3, PAGES [1741 - 1746]
REFERENCES
  1. Li, X.X., He, J.H. Bubble Electrospinning with an Auxiliary Electrode and an Auxiliary Air Flow, Recent Patents on Nanotechnology, 14(2020), No.1, pp. 54-42
  2. Liu, G.L., et al., Last Patents on Bubble Electrospinning, Recent Patents on Nanotechnology, 14(2020), No.1, pp.5-9
  3. Liu, L.G., et al. Dropping in electrospping process: A General Strategy for Fabrication of Microspheres, Thermal Science, 25(2021), No.2, pp. 1295-1303
  4. Lin, L., et al. Fabrication of PVDF/PES nanofibers with unsmooth fractal surfaces by electrospinning: A General Strategy and Formation Mechanism, Thermal Science, 25(2021), No.2, pp.1287-1294
  5. Dmitriev, A. I., Numerical model of a local contact of a polymer nanocomposite and its experimental validation, Facta Universitatis-Series Mechanical Engineering, 19(2021), No.1, pp.79-89
  6. Theron, S. A., et al. Multiple jets in electrospinning: experiment and modeling, Polymer 46(2005), No.9, pp. 2889-2899.
  7. Yang, Y., et al. Multiple jets in electrospinning, 2006 IEEE 8th International Conference on Properties & applications of Dielectric Materials, IEEE, 15 January 2007
  8. Wu, Y.-K., et al. A double-switching voltage: Controlling multiple jets in electrospinning, Materials Letters 233 (2018), pp. 359-362.
  9. Varesano, A., et al. Experimental investigations on the multi-jet electrospinning process, Journal of Materials Processing Technology 209 (2009), No.11, pp.5178-5185.
  10. Li, X. X., et al. Multiple needle electrospinning for fabricating composite nanofibers with hierarchical structure , Journal of Donghua University(English Edition), 38(2021), No.1, pp. 63-67.
  11. Wu, YK and Liu, Y. Fractal-like multiple jets in electrospinning process, Thermal Science, 24(2020), No.4, pp.2499-2505
  12. Qian, M.Y., He, J.H., Collection of polymer bubble as a nanoscale membrane, Surfaces and Interfaces, 28(2022), Dec., 101665
  13. He, J.H., et al. The Maximal Wrinkle Angle During the Bubble Collapse and Its Application to the Bubble Electrospinning, Frontiers in Materials, 8(2022), Feb., 800567
  14. He, J.-H., et al. Quasistatic model for two-strand yarn spinning, Mechanics Research Communications 32.2 (2005): 197-200.
  15. Zhang, LN and He, JH. Periodic and chaotic motion in Sirofil yarn spinning, Fibers & Textiles in Eastern Europe, 16 (2008) , No.2, pp.27-29
  16. Zhang, LN and He, JH. Resonance in Sirospun yarn spinning using a variational iteration method, Computers & Mathematics with Applications, 54 (2007), Nos.7-8 , pp.1064-1066
  17. He, J.H., et al., Nonlinear instability of two streaming-superposed magnetic Reiner-Rivlin Fluids by He-Laplace method, Journal of Electroanalytical Chemistry, 895(2021), 115388
  18. He, J.-H.; et al. Periodic Property and Instability of a Rotating Pendulum System. Axioms, 10(2021), 191.
  19. He, C.H., et al. Hybrid Rayleigh -Van der Pol-Duffing Oscillator (HRVD): Stability Analysis and Controller, Journal of Low Frequency Noise, Vibration & Active Control, 2021, DOI: 10.1177/14613484211026407
  20. Tian, D., et al. Fractal N/MEMS: from pull-in instability to pull-in stability, Fractals, 29(2021): 2150030
  21. Chen, C.L., et al., Design of extended backstepping sliding mode controller for uncertain chaotic systems, International Journal of Nonlinear Sciences and Numerical Simulation, 8(2007), No.2, pp.137-145
  22. Yau, H.T., et al., Synchronization control for a class of chaotic systems with uncertainties, International Journal of Bifurcation and Chaos, 15(2005), No.7, pp.2235-2246
  23. Lin, J.-S., et al., Synchronization of unidirectional coupled chaotic systems with unknown channel time-delay: adaptive robust observer-based approach, Chaos, Solitons and Fractals, 26(2005), No.3, pp.971-978.
  24. Yau, H.T., Generalized projective chaos synchronization of gyroscope systems subjected to dead-zone nonlinear inputs, Physics Letters A, 372(2008), No. 14, pp. 2380-2385
  25. Yau, H.T., Nonlinear rule-based controller for chaos synchronization of two gyros with linear-plus-cubic damping, Chaos, Solitons and Fractals, 34(4)(2007), pp 1357-1365, 2007.
  26. Lin, C.J., et al., Chaos suppression control of a coronary artery system with uncertainties by using variable structure control, Computers & Mathematics with Applications, 64(2012), No.5, pp.988-995.
  27. Yau, H.T., et al., Comparison of Extremum-Seeking Control Techniques for Maximum Power Point Tracking in Photovoltaic Systems, Energies, 4(2011), No.12, pp. 2180-2195.
  28. Chen,J.H., et al., Design and implementation of FPGA-based Taguchi-chaos-PSO sun tracking systems, Mechatronics, 25(2015), Frb., pp. 55-64

© 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