Abstract
Electret melt-blown nonwovens are widely used for air purification due to their low pressure drop and high filtration efficiency. However, the charge stability could be affected by the ambient temperature and humidity, reducing the filtration efficiency, resulting in the electret melt blown filter not providing effective protection. Herein, we used corona charge to prepare electret melt-blown nonwovens and systematically studied the effects of different temperature and humidity on the structure, morphology, filtration performance, and surface potential within 24 h. The effect of treatment temperature and humidity on pressure drop was minimal because the fiber morphology and web structure of melt-blown nonwovens were not damaged. When the treatment temperature was lower than 70 °C, the effect on the filtration efficiency of the sample was small, but when the temperature increased to 90 or 110 °C, the filtration efficiency decreased significantly with the increase of the treatment time, and the surface potential also declined similarly. In conclusion, high temperatures will lead to charge escape and reduce the electrostatic adsorption effect. Furthermore, at the same temperature, increasing relative humidity can accelerate the charge release and make the filtration efficiency drop more. After the sample was treated at 110 °C and 90% relative humidity for 24 h, the filtration efficiency decreased from 95.49% to 38.16% at a flow rate of 14.16 cm s−1, and the surface potential dropped to the lowest value of −1.01 kV. This result shows that all links of electret melt-blown filter material from raw material to final use should be avoided in high temperature and high humidity conditions to ensure the protection effect.
Highlights
Airborne fine particulate pollution has serious direct effects on public health
Compared with the untreated melt-blown sample, there is no visible change in appearance and structure of the samples after heat treatment at 110 ◦ C for 24 h (110 ◦ C-24 h), and heat-moisture treatment at 110 ◦ C for 24 h under 90%
High temperature and high humidity treatment had no obvious effect on the fiber morphology and structure of the electret melt-blown material, so its pressure drop changed little
Summary
Airborne fine particulate pollution has serious direct effects on public health. Many epidemiological studies have reported that exposure to particulate matter with an aerodynamic diameter less than 2.5 μm (PM2.5) could increase cardiopulmonary risk [1,2,3,4,5]. The simplest and most common protection method is the use of air filters. Melt-blown nonwovens have become the preferred air filter materials due to their three-dimensional random arrangement of fibers, large specific surface area, high porosity, small pore size, and high barrier performance [6,7]. The filtration mechanism of fiber materials for airborne particles is very complicated. There are many related theoretical studies, among which the classical filtration theory mainly focuses on the single fiber filtration mechanism
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