Preparation and properties of <scp>PVC</scp> composites filled with walnut shell powder hybrid attapulgite

Yang, Junqian; Zhang, Keping; Chen, Dongsheng; Zhang, Xi; Zhang, Yanan

doi:10.1002/vnl.22046

Cited by 2 publications

(1 citation statement)

References 76 publications

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“…Wood–plastic composites (WPCs) prepared by the melting and blending of thermoplastics and plant fibers are green, biodegradable, easy to manufacture, and with excellent performance benefits 1,2 since the combination of wood flour (WF) and recycled polypropylene (rePP) can effectively reduce the use of the plastic matrix and also save biological resources while reducing the cost of raw materials. Nonetheless, the incompatibility of the polar WF with nonpolar polymers has restricted the widespread application of WPC‐based products.…”

Section: Introductionmentioning

confidence: 99%

Preparation and properties of recycled polypropylene‐based wood–plastic composites reinforced with a bio‐based compatibilizer

Liu,

Ye,

et al. 2024

Vinyl Additive Technology

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Wood‐plastic composites are green composites made of plastic as the matrix and wood as the filler; however, the incompatibility between these two leads to the degradation of the composites. This paper reports the synthesis of a novel bio‐based compatibilizer, annotated as OA‐g‐H20, by grafting oleic acid (OA) on a hyperbranched polyester (Boltorn H20). The effect of modifying recycled polypropylene‐based wood–plastic composites with this compatibilizer was then assessed. The Fourier transform infrared spectroscopy, thermogravimetric analysis, and gel permeation chromatography techniques were employed to characterize the fabricated OA‐g‐H20, while its modification effect was assessed by differential scanning calorimetry, dynamic thermomechanical analysis, scanning electron microscopy, and mechanical property tests. The experimental results revealed that the optimal addition amount of OA‐g‐H20 was 2.0 wt.%.Highlights A new bio‐based compatibilizer, OA‐g‐H20, for wood–plastic composites is reported. OA‐g‐H20 was obtained by grafting oleic acid on a hyperbranched polyester (H20). OA‐g‐H20 provided good mechanical reinforcement for the wood–plastic composites. OA‐g‐H20 improved the crystallinity of the composites. The reinforcement mechanism of OA‐g‐H20 in wood–plastic composites is elucidated.

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Section: Introductionmentioning

confidence: 99%

Preparation and properties of recycled polypropylene‐based wood–plastic composites reinforced with a bio‐based compatibilizer

Liu,

Ye,

et al. 2024

Vinyl Additive Technology

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Characterization of annealed‐silane modified barley husk biosilica and garment waste cotton microfiber vinyl ester composite

Kandavalli,

Sahu

et al. 2024

Vinyl Additive Technology

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This study investigates the effect of adding annealed‐silane modified biosilica and waste cotton microfiber into the vinyl‐based composite on load‐bearing properties. The primary objective of this study was to unveil the significance of annealing treatment on the biosilica and its effect on composite's properties. The biosilica was prepared from waste barely husk ash and the waste cotton microfiber was used as received. The composites were fabricated using mold casting method and their properties were assessed in accordance with ASTM standards. Among the composites examined, the VCB2 displays improved mechanical properties with a highest tensile strength of 120 MPa. In contrast, the VCB3 composite exhibited enhanced hardness with a low specific wear rate of 0.22 mm3/N m and a coefficient of friction of 0.19. Furthermore, the composite VCB3 demonstrated an elevated dielectric constant of 3.85 and a low dielectric loss of 0.136 with a high thermal stability up to 388°C. This study underscores the potential of annealing process on biosilica and its stress free grain structure in property improvement made as valuable reinforcement in waste cotton microfiber‐vinyl ester composites, opening up new avenues for diverse engineering applications with advanced material performance.Highlights Vinyl ester composites are prepared from waste biomass biosilica and cotton microfiber. Addition of biosilica improved the void filling effect of matrix. Addition of biosilica improved the mechanical properties. Addition of biosilica up to 3 vol.% improved the wear properties. Addition of biosilica up to 3 vol.% improved the thermal stability.

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Preparation and properties of PVC composites filled with walnut shell powder hybrid attapulgite

Cited by 2 publications

References 76 publications

Preparation and properties of recycled polypropylene‐based wood–plastic composites reinforced with a bio‐based compatibilizer

Preparation and properties of recycled polypropylene‐based wood–plastic composites reinforced with a bio‐based compatibilizer

Characterization of annealed‐silane modified barley husk biosilica and garment waste cotton microfiber vinyl ester composite

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