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The Influence of Chosen Plant Fillers in PHBV Composites on the Processing Conditions, Mechanical Properties and Quality of Molded Pieces

By November 14, 2021January 4th, 2022No Comments

. 2021 Nov 14;13(22):3934.

doi: 10.3390/polym13223934.

Wiesław Frącz 1Grzegorz Janowski 1Robert Smusz 2Marek Szumski 3
Affiliations 

Free PMC article

Abstract

This work is inspired by the current European policies that aim to reduce plastic waste. This is especially true of the packaging industry. The biocomposites developed in the work belong to the group of environmentally friendly plastics that can reduce the increasing costs of environmental fees in the future. Three types of short fibers (flax, hemp and wood) with a length of 1 mm each were selected as fillers (30% mass content in PHBV). The biocomposites were extruded and then processed by the injection molding process with the same technical parameters. The samples obtained in this way were tested for mechanical properties and quality of the molded pieces. A significant improvement of some mechanical properties of biocomposites containing hemp and flax fibers and quality of molded pieces was obtained in comparison with pure PHBV. Only in the case of wood-PHBV biocomposites was no significant improvement of properties obtained compared to biocomposites with other fillers used in this research. The use of natural fibers, in particular hemp fibers as a filler in the PHBV matrix, in most cases has a positive effect on improving the mechanical properties and quality of molded pieces. In addition, it should be remembered that the obtained biocomposites are of natural origin and are fully biodegradable, which are interesting and desirable properties that are a part of the current trend regarding the production and commercialization of modern biomaterials.

Keywords: PHBV, biocomposites, biopolymers, extrusion process, injection molding process, plant fibers

Conflict of interest statement

The authors declare no conflict of interest.

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References

    1. Iwata T. Biodegradable and bio-based polymers: Future prospects of eco-friendly plastics. Angew. Chem. Int. Ed. 2015;54:3210–3215. doi: 10.1002/anie.201410770. – DOI – PubMed
    1. Álvarez-Chávez C.R., Edwards S., Moure-Eraso R., Geiser K. Sustainability of bio-based plastics: General comparative analysis and recommendations for improvement. J. Clean. Prod. 2012;23:47–56. doi: 10.1016/j.jclepro.2011.10.003. – DOI
    1. Scholz C. Poly(13-Hydroxyalkanoates) as potential biomedical materials: An overview. In: Scholz C., Gross R.A., editors. Polymers from Renewable Resources: Biopolyesters and Biocatalysis. Volume 764. American Chemical Society; Washington, DC, USA: 2001. pp. 328–334.
    1. Vogel R., Tändler B., Voigt D., Jehnichen D., Häußler L., Peitzsch L., Brünig H. Melt spinning of bacterial aliphatic polyester using reactive extrusion for improvement of crystallization. Macromol. Biosci. 2007;7:820–828. doi: 10.1002/mabi.200700041. – DOI – PubMed
    1. Lenz R.W., Marchessault R.H. Bacterial polyesters: Biosynthesis, biodegradable plastics and biotechnology. Biomacromolecules. 2005;6:1–8. doi: 10.1021/bm049700c. – DOI – PubMed

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