Characterization of biobased epoxy resins to manufacture eco‐composites showing recycling properties

Saitta, Lorena; Prasad, Vishnu; Tosto, Claudio; Murphy, Neal; Ivanković, Alojz; Cicala, Gianluca; Scarselli, Gianfranco

doi:10.1002/pc.27095

Cited by 13 publications

(18 citation statements)

References 46 publications

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“…[ 203 ] Flax‐epoxy composites (40% fiber volume) using Recyclamine hardener can be degraded in concentrated acetic acid at 80 °C within a few hours. [ 204 ] In this system the polymer matrix dissolves and can be used as a thermoplastic and flax fibers can be filtered, however, their initial fabric state is converted into individual fibers. Additionally, Recyclamine is now being explored to form recyclable blades for wind turbines in collaboration with Siemens Gamesa.…”

Section: Sustainability In Aerospace Polymer Materials: How To Get Th...mentioning

confidence: 99%

Polymers as Aerospace Structural Components: How to Reach Sustainability?

Dyer,

Kumru

2023

Macro Chemistry & Physics

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The aerospace industry has been benefiting from the utilization of polymer materials since fibre reinforced polymer composites (FRPC) offers high performances at low densities compared to metals. In a way, FRPC innovated lightweight matter engineering and provided aviation as a public transport method. Since their first integration into structural parts, FRPC experiences an exponential growth over years and receives a special interest from manufacturing engineering. While FRPC today is a major focus in engineering, design of polymer matrix relies on polymer chemistry. However, aircraft materials are facing a pressing issue related to sustainability, since their environmental footprint is at alarming level. In this review, commercial thermosetting polymer composites employed in aircraft structures will be exhibited from chemistry perspective by depicting starting products and curing reactions. The potential of chemistry to architect next‐generation sustainable FRPC for structural parts by means of utilization of sustainable feedstock, energy‐efficient processing and recycling will be deciphered.This article is protected by copyright. All rights reserved

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Section: Sustainability In Aerospace Polymer Materials: How To Get Th...mentioning

confidence: 99%

Polymers as Aerospace Structural Components: How to Reach Sustainability?

Dyer,

Kumru

2023

Macro Chemistry & Physics

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“…Recently, the bio-based textile structural composites gained significant importance in load bearing applications due to rise in environmental concerns and sustainability. [1][2][3] The plant fibres have become more popular as reinforcements in composite manufacturing because of their biodegradability, low density, and cheaper cost. 4 However, the plant fibres have few limitations over synthetic fibres especially in textile structural composites, where they need to demonstrate superior long term mechanical performance to cyclic (fatigue) as well as long term constant load (creep) situations in harsh environments of varying temperature and humidity levels.…”

Section: Introductionmentioning

confidence: 99%

Creep behaviour of ozone treated jute fabric/epoxy composites

Bhattacharyya

Baheti

2023

Journal of Composite Materials

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The present work attempted to study the creep behaviour of jute fabric/epoxy composites at different environment temperatures using several creep models (i.e., Burger’s model, Findley’s power law model, and Coupling model). The surface of jute fabrics was modified by ozone gas treatment to remove the non-cellulosic materials and thereby improve their adhesion with epoxy matrix. Further, the performance of ozone surface treatment was compared with traditional alkali treatment based on surface morphology, mechanical properties, hydrophilicity, etc. The ozone surface treatment was found to remove lignin and increase hydrophilicity of jute fibres to greater extent as compared to alkali treatment, however with higher tendency of defibrillation and fibre rupture. Later, the creep resistance of alkali treated jute fabric/epoxy composites was found superior to the ozone treated jute fabric/epoxy composites at lower temperature of 40°C and 70°C. However, the ozone treated jute fabric/epoxy composites showed higher instantaneous elastic deformation and lower viscous deformation at elevated temperatures of 70°C and 100°C. The ozone treated jute fabric/epoxy composites showed extended temperature range of 100°C–120°C to restrict segmental mobility of epoxy matrix and depicted higher interfacial shear strength properties from the microbead pull out test.

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“…Recently, the closed-loop chemical recycling strategy has attracted considerable scholarly attention [ 13 , 14 , 15 , 16 ]. Closed-loop recyclability can be achieved by incorporating cleavable or dynamic chemical bonds into a thermoset network to achieve controlled degradation of conventional thermosets under certain conditions [ 13 ].…”

Section: Introductionmentioning

confidence: 99%

Preparation and Closed-Loop Recycling of Ultra-High-Filled Wood Flour/Dynamic Polyurethane Composites

et al. 2023

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The development of biomass-based composites has greatly reduced the daily consumption of plastics. However, these materials are rarely recyclable, thus, posing a severe threat to the environment. Herein, we designed and prepared novel composite materials with ultra-high biomass (i.e., wood flour) filling capacity and good closed-loop recycling properties. The dynamic polyurethane polymer was polymerized in situ on the surface of wood fiber, and then they were hot-pressed into composites. Fourier-transform infrared (FTIR), scanning electron microscopy (SEM), and dynamic thermomechanical analysis (DMA) measurements reveal good compatibility between the polyurethane and wood flour in the composites when the wood flour content is ≤80 wt%. The maximum tensile and bending strength of the composite are 37 and 33 MPa when the wood flour content is 80%. The higher wood flour content results in higher thermal expansion stability and creep resistance in the composites. Moreover, the thermal debonding of dynamic phenol–carbamate bonds facilitates the composites to undergo physical and chemical cycling. The recycled and remolded composites exhibit good mechanical property recovery rates and retain the chemical structures of the original composites.

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Characterization of biobased epoxy resins to manufacture eco‐composites showing recycling properties

Cited by 13 publications

References 46 publications

Polymers as Aerospace Structural Components: How to Reach Sustainability?

Polymers as Aerospace Structural Components: How to Reach Sustainability?

Creep behaviour of ozone treated jute fabric/epoxy composites

Preparation and Closed-Loop Recycling of Ultra-High-Filled Wood Flour/Dynamic Polyurethane Composites

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