Abstract

1. INTRODUCTION

The electrospinning process, invented by Formhals in 1934 [¹1  1. FORMHALS, A., US Patent 1-975-504, 1934.], was widely studied on the whole world during the last decades [²2  DOSHIi, J., "The elecrospinning process and applications of electrospun fibers", Thesis, Akron, 1994.,³3  WANG, P., HE, J.H. "Electrospun polyvinyl alcohol-honey nanofibers", Thermal Science, V. 17, n. 5, pp. 1549-1550, 2013.]. It has been found that the fiber diameter can be controlled within a broad range down to a few tens of nanometers by proper selection of the processing parameters [²2  DOSHIi, J., "The elecrospinning process and applications of electrospun fibers", Thesis, Akron, 1994.]. Recently a new approach was invented using polymer bubbles, which is a potential technology for mass-production of nano/micro-fibers, and it is termed as Bubbfil spinning technology [⁴4 HE,J.H., KONG,H.Y., et al. "Variational iteration method for Bratu-like equation arising in electrospinning", Carbohydrate polymer, v.105, pp.229-230, 2014].

Bubbfil spinning [⁴4 HE,J.H., KONG,H.Y., et al. "Variational iteration method for Bratu-like equation arising in electrospinning", Carbohydrate polymer, v.105, pp.229-230, 2014] is developed from the bubble-electrospinning [⁵5  He, J.H., KONG, H.Y., YANG, R.R., et al., "Review on fiber morphology obtained by bubble electrospinning and blown bubble spinning", Thermal Science, v.16, N.5,1263-1279, 2012.,⁶6 LIU,F.J., DOU, H. "A modified Young-Laplace equation for the bubble electrospinning considering the effect of humidity", Thermal Science, v. 17, n. 5, pp. 629-630, 2013,⁷7  DOU, H., LIU, H.Y., et al. "A belt-like superfine film fabricated by bubble-electrospinning", Thermal Science, v. 17, n. 5, pp. 1508-1510, 2013], blown-bubble spinning [8], and membrane spinning [⁹9  KONG, H.Y., He, J.H., et al., "Polymer liquid membrane for nanofiber fabrication", Thermal Science, V. 17, n. 5, pp. 1479-1482, 2013,¹⁰10  KONG, H.Y., HE, J.H., "A modified bubble electrospinning for fabrication of nanofibers", Journal of Nano Research, v. 23, pp. 125-128, 2013.], it is use electronic force, blowing air, or other forces to overcome the surface tension of a bubble or a membrane. The bubble electrospinning was first invented in 2007 by Ji-Huan He and his collogues (Chinese patent ZLGL2007030001). After several years¡¯ improvement, the technology has been more and more matured.

Polyether sulfone (PES) has good chemical properties and hydrolysis stability, high strength, a wide pH range from 1 to 13. In addition, the highest working temperature can reach 129 ¡æ, and it has good oxidation resistance and resistance to chloride, therefore, it has become one of important membrane materials. The fiber membrane obtained either electrospinning or Bubbfil spinning has light quality, good permeability, large specific surface, high porosity and good internal pore connectivity, being good filtering material [¹¹11 CHEN, R.X., ZHANF,L., et al., "Mechanism of nanofiber crimp", Thermal Science, v. 17, n. 5, pp. 1473-1477, 2013,¹²12  BARHATE, R.S., LOONG, C.K., et al., "Preparation and characterization of nanofibrous filtering media", J. Membr Sci, v. 283, n 1/2, pp. 209-218, 2006.,¹³13  GOPAL, R., KAUR, S., et al., "Electrospun nanofibrous filtration membrane", J. Membr Sci, v.281, n 1/2, pp. 581-586, 2006.]. In the study, the author used N,N-Dimethylacetamide (DMAC) to dissolve PES for electrospinning and Bubbfil spinning.

2. WORKING PRINCIPLE AND TECHNOLOGICAL PROCESS

The principle of electrospinning is shown in Fig. 1. The polymer solution or melt with high voltage results in charged polymer droplet under the force of electric field in which the Taylor cone is formed. When the electric field force is big enough to overcome the surface tension of Taylor cone, a moving jet is ejected. In this process of injection, the jet is solidified into fiber after solvent evaporation.

Figure 1
Traditional electrospinning device

Figure.2 gives a bubble electrospinning set up. Bubbles are produced by a controllable syringe pump, and number of bubbles depends upon the size of tube. The number of bubbles reduces with decrease of the diameter of the tube, when the tube reduces to a threshold value, only a single bubble is formed. The voltage is applied to overcome the surface tensions of bubbles, when the voltage reaches a threshold, multiple jets are ejected from bubbles. After the bubble burst to debris, under non-uniform electric field or flow field, they further stretches to form fibers. A metal receiver above is used for collecting fibers. Bubble-spinning is to overcome the surface tension of the bubble to complete the spinning process, in which its surface tension has nothing to do with the nature of the solution as that in Taylor cone, and is only affected by the size of the bubbles and the gas pressure difference between inside and outside of the bubble.

Figure 2
Device for bubble-electrospinning

3. EXPERIMENTAL PROCEDUR

The Polyether sulfone material was purchased from American SOLVAY and the pure N, N dimethyl acetamide was produced from the United States Dupont Chemical Group Co., LTD. A variable high voltage power supply was used to produce voltages ranging from 0 to 50 kV. The indoor humidity is kept at 40%RH, and all spinning conditions are kept same for comparison of the two technologies.

Considering the control factors in the process of spinning, whether traditional or bubble-electrospinning, three parameters of solution concentration, applied voltage and tip-to-collector distance were meaningful and studied here. The applied voltage was increased gradually from 15kv, 20kv, to 25kv. The polymer concentrations 25wt% and 30wt%, respectively, and the tip-to-collector distances in the experiment were set as 10cm and 15cm, respectively. The samples collected were placed in a vacuum oven for 24 h at room temperature in order to remove the solvent residuals.

4. RESULTS AND DISCUSSION

The morphology of the fibers was examined with scanning electron microscopy (SEM, GSM-5900, Jeol. Co., Japan). The diameter and distribution of the bead were obtained by using image analyzer. The results are given in Figure 3 and Figure 4 at diffenerent spinning conditions.

Figure 3
SEM images of PES/DMAC membranes fabricated by electrospinning at different solution concentrations, applied voltage, and tip-to-collector distances

Figure 4
SEM images of PES/DMAC membranes fabricated by bubble-electrospinning at the same spinning parameters as electrospinning

The change of bead morphology and nanofiber morphology is shown in Figure 3 and Figure 4. Through a series of experiments, in traditional electrospinning if PES concentration was lower than 16wt%, then small droplets appeared. In the process of increasing the concentration, although it could not completely rule out the emergence of small droplets, electrospinning effect was becoming more and more stable. When the PES concentration was higher than 35wt%, it could not be used for spinning due to condensate easily, either. Similarly, the threshold values for Bubbfil spinning were 20wt% and 38wt%.

In both of the electrospinning and the bubble-electrospinning, the change trend of bead morphology and nanofiber morphology is the same as shown in Fig.5 and Fig.6. With increasing concentration, the diameter of bead became smaller while that of nanofiber showed a trend of increase. On the contrary, the diameter of bead became bigger, but showed a trend of decrease about nanofiber when the tip to collector distances were enlarged. The shape of the droplet at the syringe tip and the continuous fragment resulted from the bubbles can be changed by the intensity of the applied voltage and the resulting morphology and aspect ratio became smaller and then larger. Overall, the aspect ratio increased first and then decreased with the applied voltage, with this transition occurring at a midpoint voltage.

Figure 5
The change of bead morphology in the electrospinning and bubble-electrospinning

Figure 6
The change of nanofiber morphology in electrospinning and bubble-electrospinning

However, the morphology of fibers got at the two spinning methods had a main difference. The nanofibers made by electrospinning tend to be smooth mostly while what got from bubble-electrospinning were all porous nanofibers as shown in Fig.4.

5. CONCLUSIONS

The working principles of the two methods are totally different, as a result the morphologies of the fibers diverge greatly even though the change trend of bead morphology and nanofiber morphology formed on either electrospun or bubble-electrospun polystyrene fibers is the same. The main advantages of the Bubbfil spinning is the high throughout for industrial applications and porous fibers for many potential applications in various fields especially in filtration.

6. ACKNOWLEDGEMENT

The work is supported by Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD), National Natural Science Foundation of China under grant No.11372205, No. 51403143 and Project for Six Kinds of Top Talents in Jiangsu Province under grant No.ZBZZ-035, Science & Technology Pillar Program of Jiangsu Province under grant No.BE2013072, Research and Innovation Project for College Graduates of Jiangsu Province under grant No. CXZZ13-0817, Jiangsu Province Key Laboratory No.KJS1314 and Jiangsu Planned Projects for Postdoctoral Research Funds1401076B, Natural Science Foundation of Jiangsu Province (Grant No. BK20140398), China Postdoctoral Science Foundation (Grant No. 2014M551658), Postdoctoral Research funding plan of Jiangsu Province (Grant No. 1302101B).

7. BIBLIOGRAPHY

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