Preparation of Superelastic, Durable, and Lightweight Composite Foams Based on Multiple Cross-Linked Network Regulated Structures

Wang, Xinghuo; Gong, Zhou; Xu, Yunwang; Chen, Xiaoqing; Chen, Yukun

doi:10.1021/acs.iecr.3c03699

Ind. Eng. Chem. Res.

2024

DOI: 10.1021/acs.iecr.3c03699

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Preparation of Superelastic, Durable, and Lightweight Composite Foams Based on Multiple Cross-Linked Network Regulated Structures

Xinghuo Wang,

Zhou Gong,

Yunwang Xu

et al.

Abstract: The polymer material foaming technology plays an important role in energy conservation and emission reduction. However, modulating the structure of rubber/plastic foams to achieve low weight and high resilience is still a challenge. In this paper, ethylene vinyl acetate polymer (EVA)/epoxidized natural rubber (ENR) foams are prepared by chemical foaming kettle compression molding (KCM) with multiple cross-linked network structures consisting of covalent cross-links of EVA−EVA and ENR−ENR and hydrogen-bonded cr… Show more

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2024

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Cited by 2 publications

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Development of high‐performance EGMA/EVA‐bamboo powder composite foams with enhanced stability, strengthening and toughening for sustainable applications

Hao,

Wang,

Xie

et al. 2024

Polymer Engineering & Sci

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Commercial ethylene vinyl acetate co‐polymer (EVA) foam is already an important part of everyday life thanks to its weather resistance and stability. However, the large amount of inorganic fillers present in commercial EVA foams is the main obstacle to their full carbon recovery. In this work, high‐performance ethylene‐acrylic ester‐glycidyl methacrylate/EVA‐bamboo powder (EGMA/EVA‐BP) composite foams with multiple cross‐linked network structures were successfully prepared by introducing a bio‐based filler, BP, and using EGMA as a partial replacement of the foaming matrix. Influenced by the multiple cross‐linked networks, the EGMA/EVA‐BP foam shows increased strength and toughness. Compared with EVA foams, the stability of EGMA/EVA‐BP foam is greatly improved by the introduction of BP and dispersion of EGMA, with tensile toughness and compressive modulus reaching 7.20 kN/m3 and 1.05 MPa. Meanwhile, the EGMA/EVA‐BP foam still retains the advantages of light weight (density of 0.175 g/cm3), high resilience (52%) and good thermal stability and durability (more than 400 cycles at 20% compression). In particular, BP enables the foam fully carbon‐degradable, making it easier to achieve sustainability in commercial polymer foams. This cost‐effective strategy offers an easily scalable solution for high‐performance, eco‐friendly commercial foam production.Highlights Bio‐based bamboo powder reinforces the foam to improve strength and toughness. Multi‐crosslinking network design improves foam stability. Lightweight, flexible, and durable foam. Eco‐friendly foam: combination of renewable energy and advanced polymers.

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Development of high‐performance EGMA/EVA‐bamboo powder composite foams with enhanced stability, strengthening and toughening for sustainable applications

Hao,

Wang,

Xie

et al. 2024

Polymer Engineering & Sci

View full text Add to dashboard Cite

show abstract

Fully Recycled Polyolefin Elastomer‐Based Vitrimers with Ultra‐High, Universal, Stable, and Switchable Adhesion

Liu,

Wang,

Chen

2024

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Achieving both robust adhesion to arbitrary surfaces and thermal‐switchable/recyclable properties has proven challenging, particularly for commodity polyolefins. Herein, a simple and effective route is reported to transform polyolefins elastomer (POE) into a fully recycled epoxy‐functionalized POE vitrimers (E‐POE vit) with ultra‐high, universal, stable, and switchable adhesion via facile free radical grafting and dynamic cross‐linking. The resultant E‐POE vit exhibits increase in adhesion strength on glass exceeding three to ten times compared to those commonly used polymers, due to the synergy of dense hydrogen (H)‐bonds and strong interfacial affinity. In addition, E‐POE vit also displays strong adhesion on diverse surfaces ranging from inorganic to organic while maintaining good stability in various harsh environments. More importantly, temperature‐sensitive H‐bonds allow E‐POE vit to switch between attachment‐detachment at alternating temperatures, resulting in reversible adhesion without adhesion loss, even after 10 cycles. Moreover, E‐POE vit is able to be fully recycled and reused more than ten times via thermo‐activated transesterification reactions with negligible change in structure and performance. This work may unlock strategies to fabricate high‐performance commercial polymer‐based adhesives with adhesion and recyclable features for intelligent and sustainable applications.

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Preparation of Superelastic, Durable, and Lightweight Composite Foams Based on Multiple Cross-Linked Network Regulated Structures

Cited by 2 publications

References 40 publications

Development of high‐performance EGMA/EVA‐bamboo powder composite foams with enhanced stability, strengthening and toughening for sustainable applications

Development of high‐performance EGMA/EVA‐bamboo powder composite foams with enhanced stability, strengthening and toughening for sustainable applications

Fully Recycled Polyolefin Elastomer‐Based Vitrimers with Ultra‐High, Universal, Stable, and Switchable Adhesion

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