Penetration of Monodisperse, Singly Charged Nanoparticles through Polydisperse Fibrous Filters

Podgórski, Albert; Maisser, Anne; Szymanski, Wladyslaw W.; Jackiewicz, A.; Gradoń, Leon

doi:10.1080/02786826.2010.531300

Cited by 23 publications

(18 citation statements)

References 29 publications

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“…Matulevicius et al (2014) experimentally measured the collection performance of nanofiber filter media fabricated by electrospinning of polyamide, and reported that the filter with finer fibers had a high collection efficiency and a high quality factor. Sambaer et al (2014) and Podgorski et al (2011) introduced the inhomogeneity factor in the prediction of collection efficiency of a laminated nanofiber filter, which was originally proposed by Kirsch et al (1975), and reported that the predicted collection efficiency agreed well with the experimental data by the correction with the inhomogeneity factor. They also reported that the inhomogeneity factor of nanofiber filter was high compared to HEPA filters.…”

Section: Introductionmentioning

confidence: 68%

Filtration Properties of Nanofiber/Microfiber Mixed Filter and Prediction of its Performance

Choi

Kumita

Hayashi

et al. 2017

Aerosol Air Qual. Res.

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There is an increasing demand of air filters with a high collection performance, i.e., high collection efficiency and low pressure drop, for the application to indoor air cleaning. Air filters consisting of nanofibers have attracted great interests since they may have a low pressure drop because of slip flow effect and high collection efficiency due to interception. Although various nanofiber filters are available on the market, their collection performance is not as high as expected by the conventional filtration theory because non-uniform packing of fibers plays a significant role. In the present work, the collection performance of nanofiber (780 nm) and microfiber (11.2 µm) mixed filters with various mixing fractions was studied in order to maximize the quality factor of filter, q F , as a function of mixing fraction of nanofibers. The collection performance of mixed fiber filters was predicted by using theoretical equations reported by Bao et al. (1998) for bimodal distribution of fibers. As a result, it was found that the mixed fiber filters had a uniform fiber packing compared to laminated filters and that the collection efficiency was well predicted by introducing the inhomogeneity factor calculated for the filter consisting of two distinct fiber sizes. Furthermore, we found that the mixed fiber filter with the nanofiber mixing fraction of 5% in mass had the highest quality factor.

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Section: Introductionmentioning

confidence: 68%

Filtration Properties of Nanofiber/Microfiber Mixed Filter and Prediction of its Performance

Choi

Kumita

Hayashi

et al. 2017

Aerosol Air Qual. Res.

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show abstract

“…Podgorski (2009) derived a numerical method to compute the penetration of nanoparticles through inhomogeneous fibrous filters from single fiber filtration expressions corresponding to the Kuwabara flow (Kuwabara 1959). Good agreement was demonstrated in comparison with the experimental data when a proper segregation intensity for the different fibers was used (Podgorski et al 2011). However, the above models were not developed for the net structure of UNFs and the co-existing NFs, which can lead to special characteristics on the filtration performance.…”

Section: Introductionmentioning

confidence: 88%

Filtration Performance Against Nanoparticles by Electrospun Nylon-6 Media Containing Ultrathin Nanofibers

Kuo

Bruno

Wang

2014

Aerosol Science and Technology

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We investigate the formation of ultrathin nanofibers (UNFs) with diameters below 20 nm by electrospinning Nylon-6 solution with various processing parameters. It is found that the UNF density and morphology are highly dependent on the solution concentration and age, collecting distance, and ambient humidity. The sequence that ribbon-like fibers are stretched by the electric force, followed by rapid phase separation of the splitting film is proposed as a formation mechanism of the UNFs. Based on the morphological study, a model of hexagonal nets is developed in order to estimate the filtration efficiency by the UNF structure. The estimated efficiency due to the UNFs is then combined with the contribution from the un-split nanofibers (NFs) to compute the total filtration efficiency and pressure drop for each of the electrospun media by applying a layered multiple zone model. The filtration performance of the electrospun media against nanoparticles is evaluated using the quality factor and specific filtration performance index, weighed against the pressure drop and basis weight of the media, respectively. Our results show UNFs are advantageous when high filtration efficiency is required and low weight is desired and/or little space is available for the filter media.

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“…The deposition efficiency for an individual fiber with a diameter d F for a diffusion mechanism E D can be calculated based on numerous correlations described in various sources (Natanson, 1957;Stechkina and Fuchs, 1966). However, the best results were obtained from the relationship that was a combination of correlations from the quoted works which took the following form (Podgórski et al, 2011):…”

Section: Theoretical Descriptionmentioning

confidence: 99%

“…The influence of a number of very important factors on the course of the nanofiltration process was tested, including the size of aerosol particles, their morphology, the velocity of aerosol flow through the filter and the structure of the separating material. In addition, the obtained data were interpreted using the classical theory of filtration (Hinds, 1999), which states that the Brownian diffusion is the dominant mechanism for determining the filtration efficiency of nanoparticles, and the Partially Segregated Flow Model (Podgórski, 2009;Podgórski et al, 2011;Jackiewicz et al, 2013) proposed by our research group. Up to now, the model was examined whether it can be used to describe the process of separation of sub-micron and micron-sized solid particles and monodisperse nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

Separation of Nanoparticles from Air Using Melt-Blown Filtering Media

Jackiewicz

Werner

2015

Aerosol Air Qual. Res.

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Over the last few years, expectations have grown for the development of appropriate materials for separation of nanoparticles of different morphologies from air. Therefore, the objective of this work was to conduct a broad study of the process of filtration of polydisperse nanoaerosols in materials of our design and production. They were made using the modified melt-blown technology, a very promising technique that allows to produce large amounts of fibers with a wide range of diameters which when properly formed in mats or cores can be used in various filtering products, such as protective masks, car filters. The filtration efficiency for KCl solid nanoparticles and DEHS (di-ethyl-hexyl-sebacat) liquid nanoparticles in three polypropylene filters of different morphologies have been established. The obtained results show how the aerosol face velocity and the morphology of the nonwoven media affect the filtration efficiency and pressure drop. It turned out that fibrous filters of our own production can separate particles with very small diameters from the air. As the effectiveness of the separation grew with a decrease in diameter of filter fibers, a filter composed of nanoscale fibers proved to be the most effective. An increase in aerosol flow velocity through the filter negatively affected its filtering effectiveness. The observation of data for cubical KCl and spherical DEHS particles, showed no differences in filtering effectiveness, which proves that for the tested diameter range the morphology of particles removed from air does not play a significant role, as it does for larger particles. The results obtained from the filtration of polydisperse nanoaerosols were successfully interpreted using our Partially Segregated Flow Model which takes into account the polydisperse distribution of fiber diameters in the filter. What is more, it shows that the application of the classical theory of filtration significantly overvalues the results obtained in our experiments.

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Penetration of Monodisperse, Singly Charged Nanoparticles through Polydisperse Fibrous Filters

Cited by 23 publications

References 29 publications

Filtration Properties of Nanofiber/Microfiber Mixed Filter and Prediction of its Performance

Filtration Properties of Nanofiber/Microfiber Mixed Filter and Prediction of its Performance

Filtration Performance Against Nanoparticles by Electrospun Nylon-6 Media Containing Ultrathin Nanofibers

Separation of Nanoparticles from Air Using Melt-Blown Filtering Media

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