Your search keyword '"Giner I"' showing total 2 results

1. Sustainable composites with self‐healing capability: Epoxidized natural rubber and cellulose propionate reinforced with cellulose fibers.

Author

Utrera‐Barrios, S., Pinho Lopes, O., Mas‐Giner, I., Verdejo, R., López‐Manchado, M. A., and Hernández Santana, M.

Subjects

RUBBER, CELLULOSE fibers, REINFORCEMENT of rubber, SELF-healing materials, CELLULOSE, PROPIONATES, CIRCULAR economy

Abstract

Aligned with the UN's Sustainable Development Goals (SDGs), self‐healing elastomers stand out as a cutting‐edge field in Rubber Science and Technology. These materials have the potential to reduce resource consumption, prolong the lifespan of infrastructure and products, and contribute to the Circular Economy. This study presents the development of bio‐based self‐healing elastomeric composites prepared from blends of epoxidized natural rubber (ENR) and cellulose propionate (CP) reinforced with cellulose fibers (CFs). The ENR/CP ratio was optimized, with a 70/30 ratio enhancing the tensile strength (TS) of the base rubber and slightly reducing the elongation at break. This blend demonstrated a TS healing efficiency of 75% after a temperature‐driven healing protocol (200 bar at 150°C during 12 h). Then, the CF content was varied to enhance both mechanical performance and self‐healing capabilities. Remarkably, from medium‐high (5 phr to 15 phr) CF content, healing efficiencies higher than 85% were observed with important improvements in the mechanical performance. The self‐healing process was attributed to the synergistic interplay between the polymeric chain mobility and the formation of hydrogen bonds. This innovative approach promises materials with extended lifespans, mechanical robustness, and repairability, underscoring the commitment to SDGs 9, 11, 12, 13, 14, and 15. Highlights: Matrix of epoxidized natural rubber (ENR) and cellulose propionate (CP) blends.Cellulose fibers (CFs) reinforced the ENR/CP 70/30 optimized blend.CF addition increases tensile strength (TS) by up to 60%.Healing efficiency over 85% achieved with 5 phr to 15 phr CFs content.Self‐healing attributed to polymeric chain mobility and hydrogen bonds. [ABSTRACT FROM AUTHOR]

Published

2024

2. New recyclable and self-healing elastomer composites using waste from toner cartridges.

Author

Utrera-Barrios, S., Martínez, M.F., Mas-Giner, I., Verdejo, R., López-Manchado, M.A., and Hernández Santana, M.

Subjects

*ELECTRONIC waste, *ELASTOMERS, *THERMOPLASTIC elastomers, *NITRILE rubber, *CIRCULAR economy, *POLYURETHANE elastomers, *COMPOSITE materials

Abstract

Product recycling reintroduces what is discarded as waste and minimizes the environmental impact on our society. Among the different types of waste from electrical and electronic equipment, toner recycling often falls short, downcycling plastic components. This study introduces an innovative approach in which waste parts from toner cartridges are valorized to develop (recyclable and) self-healing elastomeric composite materials. The synergy between carboxylated nitrile rubber (XNBR) as the elastomeric phase and high-impact poly (styrene) (HIPS) as the thermoplastic phase derived from toner cartridge waste was explored and optimized. This combination resulted in the creation of a thermoplastic elastomer exhibiting robust mechanical properties and self-healing capabilities with a tensile strength of 6.6 ± 0.2 MPa and a temperature-driven mechanical recovery of 100%. Furthermore, the capacity of toner powder, an integral component of waste, to act as a reinforcing filler was confirmed, with a 50% increase in mechanical strength compared with the unfilled composite. Moreover, an increase in toner content (up to 20 phr) resulted in an optimal balance between tensile strength and self-healing capacity, surpassing the traditional antagonism between these properties. As a result, this research opens a new pathway in the field of self-healing composites and suggests a practical and environmentally friendly approach for managing electronic waste, effectively supporting the principles of Circular Economy. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023