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[93990] Artykuł:

Electrospinning on 3D Printed Polymers for Mechanically Stabilized Filter Composites

Czasopismo: Polymers   Tom: 11, Zeszyt: 12, Strony: 2034
ISSN:  2073-4360
Opublikowano: Grudzień 2019
 
  Autorzy / Redaktorzy / Twórcy
Imię i nazwisko Wydział Katedra Do oświadczenia
nr 3
Grupa
przynależności
Dyscyplina
naukowa
Procent
udziału
Liczba
punktów
do oceny pracownika
Liczba
punktów wg
kryteriów ewaluacji
Tomasz Kozior orcid logo WMiBMKatedra Technologii Mechanicznej i Metrologii*Takzaliczony do "N"Inżynieria mechaniczna17100.00100.00  
Al Mamun Niespoza "N" jednostki17.00.00  
Marah Trabelsi Niespoza "N" jednostki17.00.00  
Lilia Sabantina Niespoza "N" jednostki17.00.00  
Martin Wortmann Niespoza "N" jednostki17.00.00  
Andrea Ehrmann Niespoza "N" jednostki17.00.00  

Grupa MNiSW:  Publikacja w czasopismach wymienionych w wykazie ministra MNiSzW (część A)
Punkty MNiSW: 100


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Keywords:

electrospinning  3D printing  FDM printing  nanofiber mat  adhesion  water filter 



Abstract:

Electrospinning is a frequently used method to prepare air and water filters. Electrospun nanofiber mats can have very small pores, allowing for filtering of even the smallest particles or molecules. In addition, their high surface-to-volume ratio allows for the integration of materials which may additionally treat the filtered material through photo-degradation, possess antimicrobial properties, etc., thus enhancing their applicability. However, the fine nanofiber mats are prone to mechanical damage. Possible solutions include reinforcement by embedding them in composites or gluing them onto layers that are more mechanically stable. In a previous study, we showed that it is generally possible to stabilize electrospun nanofiber mats by 3D printing rigid polymer layers onto them. Since this procedure is not technically easy and needs some experience to avoid delamination as well as damaging the nanofiber mat by the hot nozzle, here we report on the reversed technique (i.e., first 3D printing a rigid scaffold and subsequently electrospinning the nanofiber mat on top of it). We show that, although the adhesion between both materials is insufficient in the case of a common rigid printing polymer, nanofiber mats show strong adhesion to 3D printed scaffolds from thermoplastic polyurethane (TPU). This paves the way to a second approach of combining 3D printing and electrospinning in order to prepare mechanically stable filters with a nanofibrous surface.