De- and Re-Structuring of Starch to Control the Melt and Solid State Visco-Elasticity as Method for Getting New Multi Component Compounds with Scalable Properties

The aim of the article was to design and develop new thermodynamically stable starch-based compounds, with scalable properties, that are melt-processable into finished products by classic or 3D printing methods. This is based on phenomena of de-structuring, entanglement compatibilization, and re-str...

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Bibliographic Details
Published inPolymers Vol. 16; no. 21; p. 3063
Main Authors Dimonie, Doina, Grigorescu, Ramona-Marina, Trică, Bogdan, Raduly, Monica, Damian, Celina-Maria, Trusca, Roxana, Mustatea, Alina-Elena, Dima, Stefan-Ovidiu, Oancea, Florin
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 30.10.2024
MDPI
Subjects
3-D printers
3D printing
Electron microscopes
Entanglement
Glass transition
melt and solid-state viscoelastic properties
Methods
Miscibility
Polymers
Polyvinyl alcohol
PVA
Rheology
Scanning electron microscopy
Stability
starch
thermodynamically stability
Thermodynamics
Three dimensional printing
Viscoelasticity
United Kingdom
Netherlands
Romania
Germany
United States > US
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Summary:The aim of the article was to design and develop new thermodynamically stable starch-based compounds, with scalable properties, that are melt-processable into finished products by classic or 3D printing methods. This is based on phenomena of de-structuring, entanglement compatibilization, and re-structuring of starch, along with the modification of the polymer, polyvinyl alcohol (PVA), by following an experimental sequence involving pre-treatment and melt compounding in two stages. The new compounds selection was made considering the dependence of viscoelastic properties on formulation and flowing conditions in both the melted and solid states. Starting from starch with 125 °C glass transition and PVA with a Tg at 85 °C, and following the mentioned experimental sequence, new starch-PVA compounds with a high macromolecular miscibility and proven thermodynamic stability for at least 10 years, with glass transitions ranging from −10 °C to 50 °C, optimal processability through both classical melt procedures (extrusion, injection) and 3D printing, as well as good scalability properties, were achieved. The results are connected to the approaches considering the relationship between miscibility and the lifetime of compounds with renewable-based polymer content. By deepening the understanding of the thermodynamic stability features characterizing these compounds, it can be possible to open the way for starch usage in medium-life compositions, not only for short-life applications, as until now.
ISSN:2073-4360
2073-4360
DOI:10.3390/polym16213063