Abstract
Four different self-made free surface electrospinning (FSE) techniques, namely, modified bubble-electrospinning (MBE), modified free surface electrospinning (MFSE), oblique section free surface electrospinning (OSFSE) and spherical section free surface electrospinning (SSFSE), designed for high-throughput preparation of high-quality nanofibers, are presented in this paper. The mechanisms of fiber preparation of the corresponding four FSE devices were studied by simulating the electric field distribution using the Maxwell 3D software. The properties of the electric field in the device are very important for the FSE process. The effects of the particular technique on the morphology and the yield of nanofibers were experimentally investigated. The experimental data agree well with the results of the simulations and show that all four FSE devices can be used to prepare large quantities of high-quality nanofibers. A comparison of the spinning mechanisms of these four FSE devices illustrates that the SSFSE device performs best, providing the highest quality and yield of nanofibers. The SSFE device could yield 20.03 g/h of nanofibers at an applied voltage of 40 kV.
Highlights
Due to their excellent properties, such as high surface-tovolume ratio and high porosity, nanomaterials have become more and more important in industrial manufacturing
We find that the spherical section free surface electrospinning (SSFSE) apparatus is the optimal free surface electrospinning (FSE) device characterized by ordered electric field vectors, a uniform electric field distribution and the largest electric field intensity, which will result in high-quality and high yield of nanofibers
We presented four different self-made FSE devices, namely the modified bubble-electrospinning (MBE), modified free surface electrospinning (MFSE), oblique section free surface electrospinning (OSFSE) and SSFSE devices, designed to obtain high-quality PAN nanofibers in large quantities
Summary
Due to their excellent properties, such as high surface-tovolume ratio and high porosity, nanomaterials have become more and more important in industrial manufacturing. According to the above equations and figures, the distribution of the electric field intensity plays a very important role in the FSE process since multiple jets form on the entire spinning area.
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