Abstract
The fabrication of Polyvinylpyrrolidone (PVP) electrospun layers for air filter applications is the target of this study. Solutions of 10% PVP containing 0, 3, 10 and 25 wt% nanoclay were used to fabricate electrospun fibers. Scanning electron microscopy showed that the fibers’ roughness increased by increasing the nanoclay content, and it was maximum at the nanoclay concentration of 25 wt%. Concurrently, nanoclay decreased the pore size considerably and increased the range of the fibers’ size distribution up to 100%. In addition, as the nanoclay concentration increased, the frequency distribution decreased abruptly for the larger fiber sizes and increased dramatically for the small fiber sizes. This phenomenon was correlated to the effect of nanoclay concentration on the conductivity of the solution. The solution’s conductivity increased from 1.7 ± 0.05 µS/cm for the PVP solution without nanoclay to 62.7 ± 0.19 µS/cm for the solution containing 25 wt% nanoclay and destabilized the electrospun jet, increasing the range of fiber size distribution. Therefore, the PVP solution containing 25 wt% nanoclay has potential characteristics suitable for air-filter applications, owing to its rougher fibers and combination of fine and thicker fibers.
Highlights
Removing hazardous particles and aerosols from the air is in great demand in the world
Non-woven filters have the advantages of higher permeability, higher specific surface area, smaller pore size and controllable pore size distribution over woven filters, leading to higher filtration efficiency and lower pressure drop [3]
A porous non-woven layer will be deposited on the collector by selecting proper electrospinning parameters, containing very thin fibers in the range of a few nanometers to 2μm
Summary
Removing hazardous particles and aerosols from the air is in great demand in the world. Non-woven filters have the advantages of higher permeability, higher specific surface area, smaller pore size and controllable pore size distribution over woven filters, leading to higher filtration efficiency and lower pressure drop [3]. Methods such as spunbond and melt-blown have been commercialized to produce non-woven air filters. A porous non-woven layer will be deposited on the collector by selecting proper electrospinning parameters, containing very thin fibers in the range of a few nanometers to 2μm
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