Affiliation:
1. Department of Polymers Technology, Faculty of Chemistry, Gdansk University of Technology, 11/12 Gabriel Narutowicza Street, 80-233 Gdansk, Poland
Abstract
Currently, the growing demand for polymeric materials has led to an increased need to develop effective recycling methods. This study focuses on the multiple processing of bio-based thermoplastic polyurethane elastomers (bio-TPUs) as a sustainable approach for polymeric waste management through mechanical recycling. The main objective is to investigate the influence of two reprocessing cycles on selected properties of bio-TPUs. Two series of bio-based TPUs were synthesized via a solvent-free two-step method with the use of hexamethylene diisocyanate or hexamethylene diisocyanate/partially bio-based diisocyanate mixtures, bio-based poly(triamethylene ether) glycol, and bio-based 1,3 propanediol. Both the raw bio-TPUs and those subjected to two reprocessing cycles were examined with respect to their chemical, physical, thermal, thermomechanical, and mechanical properties. The conducted research revealed that reprocessing led to changes in the phase separation between the hard and soft segments, thereby affecting the bio-TPUs’ properties. Both series of materials showed similar chemical structures regardless of reprocessing (slight changes were observed in the range of carbonyl peak). The thermal properties of TPUs exhibited slight differences after each reprocessing cycle, but generally, the non-processed and reprocessed bio-TPUs were thermally stable up to about 300 °C. However, significant differences were observed in their mechanical properties. The tensile strength increased to 34% for the twice-reprocessed bio-TPUs, while the elongation at break increased by ca. 200%. On the other hand, the processing cycles resulted in a decrease in the hardness of both bio-TPU series (ca. 3–4 °ShA). As a result, the prepared bio-TPUs exhibited characteristics that were closer to those of the sustainable materials model, promoting the circular economy of plastics, with environmental benefits arising from their recyclability and their high content of bio-based monomers (78.4–78.8 wt.%).
Funder
Gdańsk University of Technology
Subject
General Materials Science
Reference49 articles.
1. (2023, September 16). Research and Markets, Thermoplastic Polyurethane (TPU) Market Raw Material (Diisocyanates, Polyols, Diols), Type (Polyester, Polyether, Polycaprolactone), End-Use Industry (Footwear, Industrial, Machinery, Automotive, Electronics, Medical), and Region-Global Forecast to 2027. Available online: https://www.researchandmarkets.com/reports/4863433/thermoplastic-polyurethane-tpu-market-raw#tag-pos-2.
2. Segmented bio-based polyurethane composites containing powdered cellulose obtained from novel bio-based diisocyanate mixtures;Kasprzyk;Wood Sci. Technol.,2021
3. Covestro Deutschland, A.G. (2023, September 16). Driving the Circular Economy by Making TPU Raw Materials More Sustainable, (n.d.). Available online: https://solutions.covestro.com/en/highlights/articles/stories/2021/making-tpu-raw-materials-more-circular.
4. Recycling of bioplastics, their blends and biocomposites: A review;Soroudi;Eur. Polym. J.,2013
5. The changes of crosslink density of polyurethanes synthesised with using recycled component. Chemical structure and mechanical properties investigations;Eceiza;Prog. Org. Coatings,2018