Knowledge Agora

Title	A comprehensive overview of conventional and bio-based fillers for rubber formulations sustainability
ID_Doc	10461
Authors	Dadkhah, M; Messori, M
Title	A comprehensive overview of conventional and bio-based fillers for rubber formulations sustainability
Year	2024
Published
Abstract	In recent years, there has been a significant increase in literature regarding the development of sustainable rubber composites. This is due to the widespread use of rubber and the need to transition towards a circular economy, which addresses environmental concerns such as global warming and pollution. Extensive research has been conducted to replace conventional fillers like silica and petroleum-based fillers in rubber composites with eco-friendly and sustainable alternatives, namely bio-based fillers. These biofillers present diverse fundamental characteristics, making them promising substitutes for carbon black or inorganic mineral-based fillers, reducing reliance on petroleum. They possess biodegradable properties, resulting in a reduced environmental footprint, as well as lower density and cost compared to conventional counterparts. Furthermore, their unique properties, such as high specific strength and stiffness, render them well-suited for various rubber applications. The performance of reinforced rubber composites is influenced by factors including the matrix polymer, as well as the source, size, shape, chemical composition, and volume fraction of fillers. Rubber composites incorporating biofillers offer the dual advantages of economic efficiency and environmental sustainability. This article provides a comprehensive review of recent research in rubber composite development, with a specific focus on utilizing various fillers. Additionally, it examines the characterization of both conventional and bio-based fillers and their effects on the behaviour and performance of rubber composites, including morphology, thermal properties, and mechanical properties.
PDF

Similar Articles

ID	Score	Article
14137		Ghosh, R; Mani, C; Krafczyk, R; Schnell, R; Talma, A; Blume, A; Dierkes, WK Exploring the Impact of Reinforcing Filler Systems on Devulcanizate Composites(2024)Polymers, 16, 11
10433		Tom, M; Thomas, S; Seantier, B; Grohens, Y; Kochaidrew, MP; Subramanian, R; Mohanty, TR; Vahabi, H; Maria, HJ; Paduvilan, JK; Thomas, MG Role of nanocellulose geometric structures on the properties of green natural rubber composites(2024)Express Polymer Letters, 18, 6
64886		Irtiseva, K; Lapkovskis, V; Mironovs, V; Ozolins, J; Thakur, VK; Goel, G; Baronins, J; Shishkin, A Towards Next-Generation Sustainable Composites Made of Recycled Rubber, Cenospheres, and Biobinder(2021)Polymers, 13.0, 4
21976		Urrego-Yepes, W; Cardona-Uribe, N; Vargas-Isaza, CA; Martínez, JD Incorporating the recovered carbon black produced in an industrial-scale waste tire pyrolysis plant into a natural rubber formulation(2021)
18218		Utrera-Barrios, S; Mas-Giner, I; Manzanares, RV; Verdejo, R; López-Manchado, MA; Santana, MH Recyclability and self-healing capability in reinforced ionic elastomers(2024)
21689		Singh, P; Singh, DN; Debbarma, S Macro- and micro- mechanisms associated with valorization of waste rubber in cement-based concrete and thermoplastic polymer composites: A critical review(2023)
17858		Fragassa, C; de Camargo, FV; Santulli, C Sustainable Biocomposites: Harnessing the Potential of Waste Seed-Based Fillers in Eco-Friendly Materials(2024)Sustainability, 16, 4
10268		Singh, P; Singh, DN Polymer composites from waste plastics and reclaimed rubber from tires for sustainable development(2024)
8606		Bragaglia, M; Paleari, L; Berrocal, JA; Lamastra, FR; Nanni, F Towards sustainable rubber compounds: The use of waste raw materials(2023)Journal Of Applied Polymer Science, 140.0, 16
6069		Bashpa, P; Bijudas, K; Dileep, P; Singh, M; Elanthikkal, S; Francis, T Natural rubber composites reinforced with sodium sulfate waste from pigment industry: A circular economy approach for solid waste management(2024)