Investigation on compressive and impact performance of GO-modified hollow glass beads/epoxy resin composites in simulated deep-sea environment

Lu, Jingjing; Guan, Jipeng; Wang, Hongquan; Dang, Rui‐Qiong; Fan, Meng‐Xuan; Zhu, Song-Qing; Shen, Xiao‐Jun

doi:10.1016/j.compscitech.2022.109608

Cited by 18 publications

(8 citation statements)

References 36 publications

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“…Consequently, it is a promising strategy for the achievement of the environmental protection and high value-added reutilization of WPCB non-metallic components by developing low-cost PMCs with excellent properties. Epoxy resins (ERs) are another typical thermosetting polymer, and they have been extensively utilized in various applications, such as adhesives, coatings, electronic indus-tries, automobiles, and fiber-reinforced composites, due to their outstanding mechanical, electrical, and chemical properties [78][79][80]. Yokoyama et al explored the reuse of WPCB non-metals as the filler of epoxy resin, mainly investigating their mechanical properties [81].…”

Section: Reutilization Of Wpcb Non-metallic Components In Thermosetti...mentioning

confidence: 99%

High Value-Added Reutilization of Waste-Printed Circuit Boards Non-Metallic Components in Sustainable Polymer Composites

Hu,

Zeng,

Lin

et al. 2023

Molecules

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The reutilization non-metallic components from a waste-printed circuit board (WPCB) has become one of the most significant bottlenecks in the comprehensive reuse of electronic wastes due to its low value and complex compositions, and it has received great attention from scientific and industrial researchers. To effectively address the environmental pollution caused by inappropriate recycling methods, such as incineration and landfill, extensive efforts have been dedicated to achieving the high value-added reutilization of WPCB non-metals in sustainable polymer composites. In this review, recent progress in developing sustainable polymer composites based on WPCB non-metallic components was systematically summarized. It has been demonstrated that the WPCB non-metals can serve as a promising reinforcing and functional fillers to significantly ameliorate some of the physical and chemical properties of polymer composites, such as excellent mechanical properties, enhanced thermal stability, and flame retardancy. The recovery strategies and composition of WPCB non-metals were also briefly discussed. Finally, the future potentials and remaining challenges regarding the reutilization of WPCB non-metallic components are outlined. This work provides readers with a comprehensive understanding of the preparation, structure, and properties of the polymer composites based on WPCB non-metals, providing significant insights regarding the high value-added reutilization of WPCB non-metals of electronic wastes.

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Section: Reutilization Of Wpcb Non-metallic Components In Thermosetti...mentioning

confidence: 99%

High Value-Added Reutilization of Waste-Printed Circuit Boards Non-Metallic Components in Sustainable Polymer Composites

Hu,

Zeng,

Lin

et al. 2023

Molecules

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“…Moreover, the lowdensity property of HGB make the corresponding polyolefin-HGB composite a less dense (ρ = 0.70 g cm À 3 ) and more tensile buoyant material than LDPE (ρ = 0.92 g cm À 3 ) (Figure 7A). [70] The volume fraction of HGB (ρ = 0.32 g cm À 3 ) was ca. 30 %.…”

Section: Materials Propertiesmentioning

confidence: 99%

Outer‐Shell Self‐Supported Nickel Catalysts for the Synthesis of Polyolefin Composites

Peng

Tan

et al. 2023

Angewandte Chemie

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In situ heterogeneous olefin polymerization has attracted much attention for the synthesis of polyolefin composites. However, the complicated syntheses of specially designed catalysts or the detrimental effects of interactions between catalyst and solid supports pose great challenges. In this contribution, an outer‐shell self‐supporting strategy was designed to heterogenize nickel catalysts on different fillers via precipitation homopolymerization of ionic cluster type polar monomer. These catalysts demonstrated high activity, good product morphology control, and stable performances in ethylene polymerization and copolymerization. Moreover, various polyolefin composites with great mechanical and customized properties can be efficiently synthesized.

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“…It has garnered significant attention due to its low density and excellent strength performance. 7,8 Contemporary research on HGB is primarily focused on the following aspects: alteration of the resin matrix 9 ; modification of the surface of the HGB, such as modification of HGB with graphene oxide, 10 coupling agent modification of HGB, 11 and so forth; the incorporation of third-phase materials, including glass fiber, 12,13 carbon fiber, 14,15 nanoclay, 16,17 and so forth; along with the optimization of the fabrication process, for instance, the use of degassing methods to synthesize HGB/EP, 18 and the application of flotation techniques to produce high-strength HGB, thereby augmenting the strength of syntactic foam composite materials. 19 All these strategies are employed to enhance the compressive strength of syntactic foam composite materials at a microscopic level.…”

Section: Introductionmentioning

confidence: 99%

The effect of flame treatment on the compressive strength of composite sandwich panels made of pure epoxy resin H‐shaped structures and hollow glass bead/epoxy resin composite material

Peng,

Zhou,

Liu

et al. 2024

Polymer Engineering & Sci

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At present, syntactic foam composites (HGB/EP) made of epoxy resin (EP) and hollow glass beads (HGBs) have received extensive attention in the research field of lightweight materials because of their high compression strength‐to‐density ratio. However, the deep‐sea environment has put forward higher requirements for the compressive properties of materials. The traditional sandwich structure with HGB/EP as the core has gradually failed to meet the requirements for the mechanical properties of equipment deeper in the ocean. This paper proposes a sandwich structure comprising a pure EP H‐shaped structural component as the rigid skeleton and an HGB/EP syntactic foam composite as the lightweight filling component. The pure EP H‐shaped structural component was subjected to flame treatment using a butane flame jet at different distances. The compression resistance of the resulting sandwich structure was tested, and the results showed varying degrees of improvement in compressive strength after flame treatment. The effects of flame treatment on the surface adhesion performance of the pure EP were characterized using compression‐shear tests, optical microscopy, contact angle tests, infrared spectroscopy, and flame temperature tests. The results demonstrated that flame treatment at a distance of 0 cm significantly increased the oxygen‐containing functional groups on the surface of the pure EP, improved the wettability of the pure EP surface, increased the adhesive strength between the pure EP H‐shaped structural component and HGB/EP, and enhanced the compressive strength of the sandwich structure. The shear strength of the shear test specimens improved by 33.0%, while the compressive strength of the sandwich structure specimens increased by 17.5%.Highlights The sandwich structure composed of pure epoxy resin H‐shaped structure and foam composite material was prepared. The distance of flame treatment affects the surface chemical groups of epoxy resin. Flame treatment significantly improved the surface wettability of epoxy resin.

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Investigation on compressive and impact performance of GO-modified hollow glass beads/epoxy resin composites in simulated deep-sea environment

Cited by 18 publications

References 36 publications

High Value-Added Reutilization of Waste-Printed Circuit Boards Non-Metallic Components in Sustainable Polymer Composites

High Value-Added Reutilization of Waste-Printed Circuit Boards Non-Metallic Components in Sustainable Polymer Composites

Outer‐Shell Self‐Supported Nickel Catalysts for the Synthesis of Polyolefin Composites

The effect of flame treatment on the compressive strength of composite sandwich panels made of pure epoxy resin H‐shaped structures and hollow glass bead/epoxy resin composite material

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