Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse

Research output: Contribution to conferencePosterResearch

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Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse. / Ravindran, Bharath; Fauster, Ewald.
2024. Poster session presented at 32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives', Leoben, Austria.

Research output: Contribution to conferencePosterResearch

Harvard

Ravindran, B & Fauster, E 2024, 'Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse', 32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives', Leoben, Austria, 21/11/24 - 22/11/24.

APA

Ravindran, B., & Fauster, E. (2024). Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse. Poster session presented at 32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives', Leoben, Austria.

Vancouver

Ravindran B, Fauster E. Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse. 2024. Poster session presented at 32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives', Leoben, Austria.

Author

Ravindran, Bharath ; Fauster, Ewald. / Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse. Poster session presented at 32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives', Leoben, Austria.

Bibtex - Download

@conference{b957604f99e147819526e504021244cd,
title = "Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse",
abstract = "Bio-based materials are increasingly recognized as sustainable alternatives to fossil resource-based materials, aligning with circular economy principles. However, the thermosetting nature of bio-based epoxy systems poses a significant challenge, lim-iting their suitability for conventional repair and recycling methods commonly ap-plied to thermoplastics [1]. This limitation complicates the management of their end-of-life scenarios, raising concerns about sustainability. To address these challeng-es, efforts have been directed toward integrating bio-based precursors into trans-esterification vitrimers, leading to the creation of advanced bio-based vitrimer sys-tems that align with green chemistry principles. The QB3R project (Quality controlled high-performance components consisting of 100% bio-based resins with high po-tential for repair and recycling) is at the forefront of this approach. The focus of this research project is on the development of a 100% bio-based material system com-posed of natural fibers and bio-based polymers. The project explores various manu-facturing techniques to process this system and demonstrates its applicability in me-chanically demanding applications through the production of a sledge demonstrator. Additionally, it aims to analyze the vitrimer functionality of the material, exploring repair options via matrix re-linking and re-infiltration [2]. The project also investigates the mechanical recycling potential and material re-use within the composite pro-cessing [3], contributing to the advancement of sustainable composites within a cir-cular economy framework.",
author = "Bharath Ravindran and Ewald Fauster",
year = "2024",
language = "English",
note = "32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives' ; Conference date: 21-11-2024 Through 22-11-2024",

}

RIS (suitable for import to EndNote) - Download

TY - CONF

T1 - Circular Economy Potential of Sustainable Bio-Based Composites: Repair, Recycle and Reuse

AU - Ravindran, Bharath

AU - Fauster, Ewald

PY - 2024

Y1 - 2024

N2 - Bio-based materials are increasingly recognized as sustainable alternatives to fossil resource-based materials, aligning with circular economy principles. However, the thermosetting nature of bio-based epoxy systems poses a significant challenge, lim-iting their suitability for conventional repair and recycling methods commonly ap-plied to thermoplastics [1]. This limitation complicates the management of their end-of-life scenarios, raising concerns about sustainability. To address these challeng-es, efforts have been directed toward integrating bio-based precursors into trans-esterification vitrimers, leading to the creation of advanced bio-based vitrimer sys-tems that align with green chemistry principles. The QB3R project (Quality controlled high-performance components consisting of 100% bio-based resins with high po-tential for repair and recycling) is at the forefront of this approach. The focus of this research project is on the development of a 100% bio-based material system com-posed of natural fibers and bio-based polymers. The project explores various manu-facturing techniques to process this system and demonstrates its applicability in me-chanically demanding applications through the production of a sledge demonstrator. Additionally, it aims to analyze the vitrimer functionality of the material, exploring repair options via matrix re-linking and re-infiltration [2]. The project also investigates the mechanical recycling potential and material re-use within the composite pro-cessing [3], contributing to the advancement of sustainable composites within a cir-cular economy framework.

AB - Bio-based materials are increasingly recognized as sustainable alternatives to fossil resource-based materials, aligning with circular economy principles. However, the thermosetting nature of bio-based epoxy systems poses a significant challenge, lim-iting their suitability for conventional repair and recycling methods commonly ap-plied to thermoplastics [1]. This limitation complicates the management of their end-of-life scenarios, raising concerns about sustainability. To address these challeng-es, efforts have been directed toward integrating bio-based precursors into trans-esterification vitrimers, leading to the creation of advanced bio-based vitrimer sys-tems that align with green chemistry principles. The QB3R project (Quality controlled high-performance components consisting of 100% bio-based resins with high po-tential for repair and recycling) is at the forefront of this approach. The focus of this research project is on the development of a 100% bio-based material system com-posed of natural fibers and bio-based polymers. The project explores various manu-facturing techniques to process this system and demonstrates its applicability in me-chanically demanding applications through the production of a sledge demonstrator. Additionally, it aims to analyze the vitrimer functionality of the material, exploring repair options via matrix re-linking and re-infiltration [2]. The project also investigates the mechanical recycling potential and material re-use within the composite pro-cessing [3], contributing to the advancement of sustainable composites within a cir-cular economy framework.

M3 - Poster

T2 - 32. Leobener Kunststoffkolloquium - 32nd Leoben-Conference on Polymer Engineering and Science 'New Materials – New Perspectives'

Y2 - 21 November 2024 through 22 November 2024

ER -