The Effect of Electro-Induced Multi-Gas Modification on Polymer Substrates’ Surface Structure for Additive Manufacturing

The Effect of Electro-Induced Multi-Gas Modification on Polymer Substrates’ Surface Structure for Additive Manufacturing

We investigated the effect of electro-induced multi-gas modification (EIMGM) duration on the adhesion and wear resistance of PET and LDPE polymer substrates used in the printing industry. It was found that EIMGM increases the polar component and the complete free surface energy from 26 to 57 mJ/m2 f...

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Veröffentlicht in:Processes 2023-03, Vol.11 (3), p.774
Hauptverfasser: Doronin, Fedor, Rytikov, Georgy, Evdokimov, Andrey, Rudyak, Yury, Taranets, Irina, Nazarov, Victor
Format: Artikel
Sprache:eng
Schlagworte:
Bending stresses
Biocompatibility
Carbon
Chemical modification
Force and energy
Free surfaces
Heterogeneity
Photocatalysis
Plasma etching
Polyethylene terephthalate
Polymer industry
Polymerization
Polymers
Prototyping
Shear strength
Substrates
Surface energy
Surface layers
Surface properties
Surface structure
Three dimensional printing
Wear resistance
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Zusammenfassung:We investigated the effect of electro-induced multi-gas modification (EIMGM) duration on the adhesion and wear resistance of PET and LDPE polymer substrates used in the printing industry. It was found that EIMGM increases the polar component and the complete free surface energy from 26 to 57 mJ/m2 for LDPE and from 37 to 67 mJ/m2 for PET (due to the formation of oxygen-containing groups on the surface of the materials). Although the degree of textural and morphological heterogeneity of the modified LDPE increased more than twice compared to the initial state, it is not still suitable for application as a substrate in extrusion 3D printing. However, for PET, the plasma-chemical modification contributed to a significant increase (~5 times) in filament adhesion to its surface (due to chemical and morphological transformations of the surface layers) which allows for using the FFF technology for additive prototyping on the modified PET-substrates.
ISSN:2227-9717
2227-9717
DOI:10.3390/pr11030774