| Title | Biomass waste materials through extrusion-based additive manufacturing: A systematic literature review |
|---|---|
| ID_Doc | 6127 |
| Authors | Romani, A; Suriano, R; Levi, M |
| Title | Biomass waste materials through extrusion-based additive manufacturing: A systematic literature review |
| Year | 2023 |
| Published | |
| Abstract | Circular economy and bioeconomy models have increasingly spread the principles of sustainable development through different strategies such as reuse and recycling. Biomass waste and by-products are often considered valuable resources. Digital technologies, i.e., extrusion-based additive manufacturing, may potentially foster their exploitation as new materials, although the current framework has not been clearly defined yet. This work wants to systematically review the publications focused on new materials from biomass waste or by-products for extrusion-based additive manufacturing processes. The current situation was analyzed on 69 selected works from 2016 searched on Scopus and WoS, focusing on the different raw materials, new 3D printable materials, 3D printing processes, and potential applications. Afterward, the emerging trends were highlighted through selected best practices from the design practice and industrial sectors. Despite the significant development of thermoplastic reinforced materials, i.e., PLA-filled composites, a wide range of biomass waste and by-products have been studied, especially for small format low-cost Fused Filament Fabrication. Although the academic field may be less focused on exploiting these new circular materials, the interest in new applications is increasing within the design practice and industrial sectors, fostering new synergies within bioeconomy and circular economy contexts. |
| https://re.public.polimi.it/bitstream/11311/1227356/5/Pre-Print_Romani_JCP_2023.pdf |
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