Compatibility and characterization of Bio-PE/PCL blends

Bezerra, Elieber Barros; França, Danyelle Campos; Morais, Dayanne Diniz de Souza; Silva, Ingridy Dayane dos Santo; Siqueira, Danilo Diniz; Araújo, Edcleide Maria; Wellen, Renate Maria Ramos

doi:10.1590/0104-1428.02518

Cited by 20 publications

(10 citation statements)

References 38 publications

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“…Figure 10 shows the results of the heat de ection temperature of BioPE and composites, with and without macaíba oil, respectively. It is observed that the HDT value for BioPE was 70.3°C, value close of the literature [65].…”

Section: Heat De Ection Temperature (Hdt)supporting

confidence: 87%

From Waste to Reuse: Manufacture of Ecological Composites Based on Biopolyethylene/wood Powder with PE-g-MA and Macaíba Oil

et al. 2021

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This work aimed to investigate the biopolyethylene (BioPE)/wood powder (WP) composites compatibilized with polyethylene-grafted maleic anhydride (PE-g-MA), using macaíba oil (OM) as a processing aid. The composites were prepared, initially, in an internal mixer and, later, the crushed akes were molded by injection. Mechanical properties (impact, tensile, exural and Shore D hardness), heat de ection temperature (HDT), Vicat softening temperature, differential scanning calorimetry (DSC), thermogravimetry (TG), water absorption, torque rheometry and scanning electron microscopy (SEM) were evaluated. The addition of 30% wood powder to the BioPE matrix increased the elastic modulus (tensile and exural), Shore D hardness and heat de ection temperature (HDT), compared to neat BioPE. These properties were improved when 10% of the PE-g-MA compatibilizer was added, compared to neat BioPE and the non-compatibilized composite. There was a signi cant reduction in the torque of the composites with the addition of macaíba oil, indicating that it improved the processability. In addition, the incorporation of macaíba oil into the composites helped to reduce water absorption, as well as to increase impact strength. SEM micrographs illustrated a greater degree of interfacial adhesion when PEg-MA and macaiba oil were added.

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Section: Heat De Ection Temperature (Hdt)supporting

confidence: 87%

From Waste to Reuse: Manufacture of Ecological Composites Based on Biopolyethylene/wood Powder with PE-g-MA and Macaíba Oil

et al. 2021

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“…Poly(ε-caprolactone) (PCL) is a chemically synthesized polymer which is fully biodegradable and can be processed using conventional plastics machinery [ 29 ]. Moreover, it has good properties and is also compatible with other materials [ 30 ]. Regarding the use of PCL for active packaging applications, Khalid et al [ 31 ] developed biodegradable antimicrobial packaging films based on PCL, starch and pomegranate rind hybrids showing a strong antimicrobial efficiency at higher concentrations of the active compound.…”

Section: Introductionmentioning

confidence: 99%

Novel Antioxidant Packaging Films Based on Poly(ε-Caprolactone) and Almond Skin Extract: Development and Effect on the Oxidative Stability of Fried Almonds

et al. 2020

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Antioxidant films based on poly(ε-caprolactone) (PCL) containing almond skin extract (ASE) were developed for food packaging applications. The effect of ASE incorporation on the morphological, structural, colour, mechanical, thermal, barrier and antioxidant properties of the prepared films were evaluated. The structural, tensile and thermal properties of the films were not altered due to ASE addition. Although no significant differences were observed for the oxygen permeability of samples, some increase in water absorption and water vapour permeability was observed for active films due to the hydrophilic character of ASE phenolic compounds, suggesting the suitability of this novel packaging for fatty foods conservation. ASE conferred antioxidant properties to PCL films as determined by the DPPH radical scavenging activity. The efficiency of the developed films was evaluated by the real packaging application of fried almonds at different ASE contents (0, 3, 6 wt.%) up to 56 days at 40 °C. The evolution of peroxide and p-anisidine values, hexanal content, fatty acid profile and characteristic spectroscopy bands showed that active films improved fried almonds stability. The results suggested the potential of PCL/ASE films as sustainable and antioxidant food packaging systems to offer protection against lipid oxidation in foods.

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“…According Bezerra et al, the addition of Bio‐PE to PCL reduced the elastic modulus, increased the elongation at break and impact strength, allowing a control of these properties by changing the blend composition. PCL chains when oxidized exhibited new functional groups (vinyl and hydroxyl) and possible intermolecular recombination, producing an oxidized‐polycaprolactone (PCL‐OX) 81 . The blend prepared with oxidized PCL (in the same composition range) did not display signs of thermodynamic miscibility but showed an interesting thermal behaviour demonstrated by changes in the crystallization temperatures of both phases and by the melting behaviour of the PCL‐OX in the blend.…”

Section: Pcl Compatibility With Other Polymersmentioning

confidence: 99%

Poly(ε‐caprolactone): A potential polymer for biodegradable food packaging applications

et al. 2021

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Due to the increased pollution generated from traditional petroleum‐based plastics and consistent fluctuations in fuel prices, the scientists are focusing on developing the biodegradable polymers which decompose into water and carbon dioxide thereby reducing the litter. Poly(ε‐caprolactone) (PCL) is the emerging biodegradable polymers, ideal to replace the conventional polymers due to its perfect compatibility with other polymers and miscible nature. The present chapter discusses about the chemical synthesis and characteristics of PCL in addition to focusing on the biodegradation mechanism. The potential of PCL for developing biodegradable films and bags in food processing is also highlighted in association with natural fibre, nanotechnology and active packing. This chapter provides an updated information about recent scientific reports on PCL to increase its exploration as a promising biodegradable packaging material.

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Compatibility and characterization of Bio-PE/PCL blends

Cited by 20 publications

References 38 publications

From Waste to Reuse: Manufacture of Ecological Composites Based on Biopolyethylene/wood Powder with PE-g-MA and Macaíba Oil

From Waste to Reuse: Manufacture of Ecological Composites Based on Biopolyethylene/wood Powder with PE-g-MA and Macaíba Oil

Novel Antioxidant Packaging Films Based on Poly(ε-Caprolactone) and Almond Skin Extract: Development and Effect on the Oxidative Stability of Fried Almonds

Poly(ε‐caprolactone): A potential polymer for biodegradable food packaging applications

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