%0 Journal Article %1 ma18030544 %A Hiller, Tim %A Altmann, Hagen J. %A Elser, Iris %A Azimian, Mehdi %A Buchmeiser, Michael R. %D 2025 %J Materials %K %N 3 %R 10.3390/ma18030544 %T Meltblow Processing of Poly (Ethylene Furanoate)–Bio-Based Polyester Nonwovens %U https://www.mdpi.com/1996-1944/18/3/544 %V 18 %X Poly(ethylene furanoate) (PEF) has been identified as a bio-based alternative or supplement to poly(ethylene terephthalate) (PET) for various applications such as food packaging and bottles as well as technical- and high-performance fibers and yarns. In this study, the processing of PEF nonwovens in the meltblow process is successfully demonstrated and reported for the first time, according to our best knowledge The resulting fabrics achieved median fiber diameters of 2.04 µm, comparable to PET. The filtration efficiency of 25 g m−2 fabrics exceeded 50% comparable to PET and PBT of the same grammage and was raised to over 90% with post-process electrostatic charging, maintaining stability. As for other aromatic polymers, applying infrared heating modules into the process indicated the potential to minimize heat shrinkage. However, the suppressed ring rotation and slower crystallization kinetics of PEF showed the need for longer post-treatment times as the heat shrinkage remained between 20% and 40% at 10 °C. Overcoming this, PEF can be a viable, bio-based alternative to PET, particularly for such high-temperature nonwoven applications that require thin layers.

@article{ma18030544, abstract = {Poly(ethylene furanoate) (PEF) has been identified as a bio-based alternative or supplement to poly(ethylene terephthalate) (PET) for various applications such as food packaging and bottles as well as technical- and high-performance fibers and yarns. In this study, the processing of PEF nonwovens in the meltblow process is successfully demonstrated and reported for the first time, according to our best knowledge The resulting fabrics achieved median fiber diameters of 2.04 µm, comparable to PET. The filtration efficiency of 25 g m−2 fabrics exceeded 50% comparable to PET and PBT of the same grammage and was raised to over 90% with post-process electrostatic charging, maintaining stability. As for other aromatic polymers, applying infrared heating modules into the process indicated the potential to minimize heat shrinkage. However, the suppressed ring rotation and slower crystallization kinetics of PEF showed the need for longer post-treatment times as the heat shrinkage remained between 20% and 40% at 10 °C. Overcoming this, PEF can be a viable, bio-based alternative to PET, particularly for such high-temperature nonwoven applications that require thin layers.}, added-at = {2025-02-10T08:26:33.000+0100}, article-number = {544}, author = {Hiller, Tim and Altmann, Hagen J. and Elser, Iris and Azimian, Mehdi and Buchmeiser, Michael R.}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2e7e7445a87da0ee2af5d1c1f02203fea/dwang}, doi = {10.3390/ma18030544}, interhash = {7739286ebbc35bdddd1d680bc913de76}, intrahash = {e7e7445a87da0ee2af5d1c1f02203fea}, issn = {1996-1944}, journal = {Materials}, keywords = {}, number = 3, timestamp = {2025-02-10T08:26:33.000+0100}, title = {Meltblow Processing of Poly (Ethylene Furanoate)–Bio-Based Polyester Nonwovens}, url = {https://www.mdpi.com/1996-1944/18/3/544}, volume = 18, year = 2025 }