Ethylene–octene copolymer–wood flour/oil flax straw biocomposites: Effect of filler type and content on mechanical properties

Zykova, A. K.; Pantyukhov, P. V.; Попов, А. А.

doi:10.1002/pen.24626

Cited by 30 publications

(19 citation statements)

References 30 publications

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“…In the process of preparing the biocomposite film, the powdery substances added in the raw materials will inevitably agglomerate, which will cause several stress concentration points inside the material which lowers the tensile strength. This is partially like some researchers’ 31,46 findings, where they found that the higher the particle content, the darker the color. The composite film with small particle additives has better mechanical properties.…”

Section: Resultssupporting

confidence: 88%

“…29,30 Many scholars developed biocomposites based on straw and plastic by mixing the rice straw and plastic mechanically and studying the mechanical properties of the mixture. 31,32 The microstructure and optimization of composites based on wheat straw were in the focus of few studies. This paper provides insights into novel fabrication and optimization of biocomposite prepared by the wheat straw micropowders and RLDPE.…”

Section: Introductionmentioning

confidence: 99%

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Enhancement of the thermal stability and mechanical properties of recycled low density polyethylene/wheat biocomposite films with targeted repairing technology and network skeleton construction

Xiao

Qing

et al. 2019

Journal of Plastic Film & Sheeting

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In this paper, biocomposite films were prepared by using recycled low density polyethylene from marine plastic waste and wheat straw micropowders from common agricultural wastes in northern China. In order to determine the optimal ratio, eight experimental groups were set up for comparative testing. For further improving the performance of the biocomposite film, the three-dimensional network skeleton construction and targeted repairing technology of the material were designed. The specimens were characterized by a HD camera, a universal examination machine, a research grade inverted microscope, and a thermogravimetric analyzer. The results indicate that the agglomeration of powders reduces the tensile strength of the material, and the elongation at break depends on the properties of the polyolefin matrix itself. The reinforced biocomposite film has a 13.7 MPa tensile strength and a 243% elongation at break. It has slightly better mechanical properties than ordinary materials, which can be used as an economical, thermally stable, and environmentally friendly material to manufacture new packaging and courier bags.

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Section: Resultssupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Enhancement of the thermal stability and mechanical properties of recycled low density polyethylene/wheat biocomposite films with targeted repairing technology and network skeleton construction

Xiao

Qing

et al. 2019

Journal of Plastic Film & Sheeting

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“…LC 670 has a melting point of 57 C, 1-octene content of 35 mol%, the density of 0.870 g/cm 3 , melt flow index (MFI) of 5 g/10 minutes at 190 C, the weight-average molecular weight of 75 000 g/ mol, and polydispersity index of 2.34. [28] A maleic anhydride-grafted PP, PP-g-MA, namely Polybond 3200 with maleic anhydride grafting level of 2.0 wt% and the weight-average molecular weight of 84 000 g/mol was supplied by Crompton. In this work, the TPO matrix is comprised of 23 wt% POE.…”

Section: Methodsmentioning

confidence: 99%

Mechanical properties of extruded glass fiber reinforced thermoplastic polyolefin composites

et al. 2020

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Engineered structural materials are required to feature a combination of deformability (ductility) and strength to be considered damage‐tolerant for safety‐critical applications. These two mechanical properties, however, tend to be mutually exclusive, encouraging optimization of the trade‐off between strength and toughness. In this report, an elastomer and a glass fiber were incorporated into a blend of two grades of polypropylene (PP) to improve matrix toughness through both intrinsic and extrinsic toughening mechanisms. This study investigates the impact resistance (at 23°C and −30°C), and strength, stiffness, deformability, and processability of extruded compatibilized glass fiber reinforced thermoplastic polyolefin (TPO) composites at 23°C. For the hybrid composites contribution of different toughening mechanisms in attainment of the final impact strength is governed by the testing temperature and processing (extruder screw) speed. The intrinsic toughening mechanism induced by the presence of the ethylene α‐olefin copolymer is suppressed by the introduction of glass fiber at 23°C, irrespective of screw speed and screw configuration design. The heat distortion temperature (HDT), flexural modulus, and tensile strength exhibit a marked improvement by glass fiber inclusion at 23°C. By evaluating the performance of the composites at −30°C, it was observed that the impact energy of the elastomer modified hybrid composites may be enhanced in the same manner as the glass fibers toughen the brittle unmodified PP matrix. It was noted that contrary to the tensile properties at break, the yield behavior of the composites containing fibers, severely shortened, is independent of the presence of the fibers at 23°C.

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“…Apparently, small particles interfere with the straightening of polyethylene macromolecules less than the large ones. It is likely that more elongated particles of FS (L/D ratio of FS = 6.7, L/D ratio of WF = 4.5) [ 41 ] inside randomly oriented films are more likely to interfere with the straightening of polyethylene macromolecules.…”

Section: Discussionmentioning

confidence: 99%

Biocomposites of Low-Density Polyethylene Plus Wood Flour or Flax Straw: Biodegradation Kinetics across Three Environments

et al. 2021

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The purpose of this study was to assess the potential for biocomposite films to biodegrade in diverse climatic environments. Biocomposite films based on polyethylene and 30 wt.% of two lignocellulosic fillers (wood flour or flax straw) of different size fractions were prepared and studied. The developed composite films were characterized by satisfactory mechanical properties that allows the use of these materials for various applications. The biodegradability was evaluated in soil across three environments: laboratory conditions, an open field in Russia, and an open field in Costa Rica. All the samples lost weight and tensile strength during biodegradation tests, which was associated with the physicochemical degradation of both the natural filler and the polymer matrix. The spectral density of the band at 1463 cm−1 related to CH2-groups in polyethylene chains decreased in the process of soil burial, which is evidence of polymer chain breakage with formation of CH3 end groups. The degradation rate of most biocomposites after 20 months of the soil assays was greatest in Costa Rica (20.8–30.9%), followed by laboratory conditions (16.0–23.3%), and lowest in Russia (13.2–22.0%). The biocomposites with flax straw were more prone to biodegradation than those with wood flour, which can be explained by the chemical composition of fillers and the shape of filler particles. As the size fraction of filler particles increased, the biodegradation rate increased. Large particles had higher bioavailability than small spherical ones, encapsulated by a polymer. The prepared biocomposites have potential as an ecofriendly replacement for traditional polyolefins, especially in warmer climates.

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Ethylene–octene copolymer–wood flour/oil flax straw biocomposites: Effect of filler type and content on mechanical properties

Cited by 30 publications

References 30 publications

Enhancement of the thermal stability and mechanical properties of recycled low density polyethylene/wheat biocomposite films with targeted repairing technology and network skeleton construction

Enhancement of the thermal stability and mechanical properties of recycled low density polyethylene/wheat biocomposite films with targeted repairing technology and network skeleton construction

Mechanical properties of extruded glass fiber reinforced thermoplastic polyolefin composites

Biocomposites of Low-Density Polyethylene Plus Wood Flour or Flax Straw: Biodegradation Kinetics across Three Environments

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