Tailoring 3D printed cellulose acetate properties produced via direct ink writing: Densification through over‐extrusion and evaporation rate control

In this study, we conducted a comprehensive experimental campaign aimed at controlling the final properties of 3D printed cellulose acetate. We equipped a commercial printer with a peristaltic pump to be able to print in a continuous fashion by means of the Direct Ink Writing technique. We investiga...

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Veröffentlicht in:	Polymer engineering and science 2023-11, Vol.63 (11), p.3786-3797
Hauptverfasser:	Slejko, E.A, Gorella, N. Sesto, Gasparini, R, Scuor, N, Seriani, S
Format:	Artikel
Sprache:	eng
Schlagworte:	Advertising campaigns Bioengineering Cellulose Cellulose acetate Densification Density Diffusion coefficient Evaporation rate Extrusion rate Mechanical properties Moisture content Parameters Peristaltic pumps Printing-ink Three dimensional printing Water absorption
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creator	Slejko, E.A Gorella, N. Sesto Gasparini, R Scuor, N Seriani, S
description	In this study, we conducted a comprehensive experimental campaign aimed at controlling the final properties of 3D printed cellulose acetate. We equipped a commercial printer with a peristaltic pump to be able to print in a continuous fashion by means of the Direct Ink Writing technique. We investigated the effect of ink concentration and printing parameters on the density, mechanical and functional properties of printed objects. Furthermore, water absorption tests demonstrated the hygroscopic behavior of cellulose acetate, with higher water content in samples with lower densities. The diffusion of water within the polymer network followed Fickian diffusion, with the diffusion coefficient influenced by the density of samples. Overall, this study highlights the importance of printing conditions in achieving desired properties in 3D printed cellulose acetate. The ability to fine-tune the mechanical properties and water absorbance of 3D printed cellulose acetate makes it promising for applications in plant science and bioengineering.
doi_str_mv	10.1002/pen.26484
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source	Wiley Online Library Journals Frontfile Complete
subjects	Advertising campaigns Bioengineering Cellulose Cellulose acetate Densification Density Diffusion coefficient Evaporation rate Extrusion rate Mechanical properties Moisture content Parameters Peristaltic pumps Printing-ink Three dimensional printing Water absorption
title	Tailoring 3D printed cellulose acetate properties produced via direct ink writing: Densification through over‐extrusion and evaporation rate control
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