Mechanical performance of thermoplastic olefin composites reinforced with coir and sisal natural fibers: Influence of surface pretreatment

Nunes-Pereira, J.; Ferreira, Diana P.; Bessa, João M.; Matos, Joana; Cunha, Fernando Eduardo Macedo; Araújo, Isabel; Silva, Luís F.; Pinho, Elizabete; Fangueiro, Raúl

doi:10.1002/pc.25209

Cited by 34 publications

(20 citation statements)

References 24 publications

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“…Mechanical properties of NFCs have been demonstrated to be influenced by several intrinsic and environmental factors . In particular, the manufacturing process of NFC is the most relevant step in determining the properties of the final product . A simplified approach based on rule of mixtures (ROM) is often applied for the prediction of mechanical properties of NFC …”

Section: Introductionmentioning

confidence: 99%

Manufacturing and characterization of hemp‐reinforced epoxy composites

et al. 2020

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The adoption of natural‐based fibers in place of inorganic reinforcements is an effective approach to reduce the environmental and economic impact of composite materials. In particular, hemp is an attractive solution due to its mechanical, physical, and growing properties. The present article deals with the manufacturing of thermoset hemp‐reinforced composite materials. In particular, the investigation moves into the production by resin transfer molding and by resin powder molding with the use of epoxy polymeric material. To describe the effects of the technological cycle onto the characteristic of realized products, different manufacturing parameters have been combined during the braiding of reinforcement and the polymerization of the final composite. Computed tomography, microscopical analysis, and tensile tests have been used to observe the main effects of the manufacturing process and mechanical properties of the materials. Furthermore, elastic moduli of the materials have been estimated by means of modified rule of mixture and Halpin‐Tsai models in order to verify their effectiveness in forecasting stiffness of the hemp‐reinforced composites in the early design phase. The article extends the existing knowledge base on hemp‐reinforced thermoset composites manufactured with different processes. Results also illustrate relations existing between error introduced by calculation models and the intrinsic variability in mechanical properties.

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Section: Introductionmentioning

confidence: 99%

Manufacturing and characterization of hemp‐reinforced epoxy composites

et al. 2020

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“…They can be effectively employed as cheap and lightweight reinforcements in the fields of automotive industries, infrastructure and construction sectors, consumer goods, and sports goods. [6][7][8][9] Despite the above said advantages, while using as reinforcements in hydrophobic matrices the natural fibers due to their chemical structural arrangements (presence of cellulose, hemicellulose, waxes, lignin, and water-soluble substances) are hydrophilic in nature and possess some cons like low thermal stability, high aquatic captivation, and deprived adhesion characteristics. In order to overcome these disadvantages, the researchers have optimized the interfacial adhesion behavior between fibers and polymer matrix by subjecting the fibers into various surface treatment methods.…”

Section: Introductionmentioning

confidence: 99%

Preparation and characterization of new hybrid polymer composites from Phoenix pusilla fibers/E‐glass/carbon fabrics on potential engineering applications: Effect of stacking sequence

et al. 2020

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The use of bio-fiber-based hybrid composites in various commercial engineering applications is increasing day by day due to their biodegradability and versatile characteristics. Hence, in the present research investigation, an attempt has been made to scrutinize the mongrelizing possessions under different laminate stacking arrangement concerning Phoenix pusilla fibers (PPFs)/E-glass woven/ carbon woven fabric-reinforced epoxy composite laminates through the studies of density, void fraction, and different mechanical strength behavior evaluation of five resulting diverse hybrid composite laminates. The hybrid laminates were prepared by manual hand lay-up technique. The scrutinization of physical and mechanical properties and the study of fractured surfaces specify noteworthy improvement in density, void fraction, tensile properties, flexural properties, and microhardness properties of PPFs/E-glass/carbon fabrics-reinforced hybrid epoxy composites. The overall results conferred that the composite laminates fabricated in the present study could be potentially used in medium load structural applications.

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“…9 Efforts are now being made to replace TPEs by reinforced TPEs. This has encouraged studies on natural fiber-reinforced TPE composites, for example, coir fiber-mixed maleic anhydride-grafted ethylene–propylene copolymer mixtures, 10 jute fiber-reinforced ethylene–propylene copolymer composites, 11,12 and coir or sisal fiber-reinforced PP (polypropylene)-based ethylene–butane copolymer composites 13 . However, only a few reports are available on natural fiber/thermoplastic elastomeric composites and their dynamic mechanical properties, and the effects of the absorbed water on their properties have not been investigated.…”

Section: Introductionmentioning

confidence: 99%

Structure and properties of recycled bamboo fiber reinforced chemically functionalized ethylene propylene rubber composites

Dinesh

Palsule

2019

Polymers and Polymer Composites

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Recycled bamboo fiber-reinforced chemically functionalized ethylene propylene rubber (R-BMBF/CF-EPR) composites have been developed by extrusion and injection molding by Palsule process without any fiber treatment and without compatibilizer. Scanning electron microscopy (SEM) shows good R-BMBF/CF-EPR interfacial adhesion in the composites, and Fourier transform infrared (FTIR) confirms that esterification and the hydrogen bonding between functional groups of CF-EPR and of R-BMBF impart this interfacial adhesion. Mechanical, dynamic mechanical, and thermal properties and the effect of water absorption on tensile properties of the composites have been evaluated. Tensile properties of the 15/85, 25/75, and 35/65 R-BMBF/CF-EPR composites are higher than those of CF-EPR and increase with increasing R-BMBF in the composites. Storage modulus and loss modulus of the composites increase with increasing fiber contents in them but decrease with increasing temperature. Water-absorbed wet composites show thickness swelling and reduced tensile properties relative to the respective dry composites but higher tensile properties than the dry CF-EPR. Thermal stability and degradation of the composites is also reported.

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Mechanical performance of thermoplastic olefin composites reinforced with coir and sisal natural fibers: Influence of surface pretreatment

Cited by 34 publications

References 24 publications

Manufacturing and characterization of hemp‐reinforced epoxy composites

Manufacturing and characterization of hemp‐reinforced epoxy composites

Preparation and characterization of new hybrid polymer composites from Phoenix pusilla fibers/E‐glass/carbon fabrics on potential engineering applications: Effect of stacking sequence

Structure and properties of recycled bamboo fiber reinforced chemically functionalized ethylene propylene rubber composites

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