Effect of reinforcement nanoparticles addition on mechanical properties of SBS/curauá fiber composites

Borba, Patricia M.; Tedesco, Adriana; Lenz, Denise Maria

doi:10.1590/s1516-14392013005000203

Cited by 60 publications

(43 citation statements)

References 24 publications

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“…Thus, this allows for efficient stress transfer between the matrix and the fibres [5] unlike untreated filler filled composites. The decline after saturation is attributed to agglomeration and sediment effects associated with higher filler content [6] or poor wetting between the fillers and matrix resulting in formation of micro-cracks [7]. The untreated GSP-PLA fibre showed superior UTS at 5 wt.…”

Section: Methodsmentioning

confidence: 99%

Mechanical characteristics of groundnut shell particle reinforced polylactide nano fibre

et al. 2016

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The PLA-groundnut shell solution is electrospun to produce nanocomposite fibre. The spinneret containing the composite solution was placed 24.7 cm away from the aluminium collector, tilted at an angle of 30 °, and the solution flow rate kept at 1 mL/min. Groundnut Shell particle (GSP) weight fraction used was varied from 3 -8 wt. %. Particle reinforced nanofibres were formed on the collector from the composite solution at 26 kV. These nanofibres were subjected to tensile test and the result indicates that at 6 wt. % untreated GSP reinforced fibre possessed the best tensile stiffness of 24.62 MPa. This corresponds to 2.201 % increase in Modulus of Elasticity over the unreinforced PLA (1.07 MPa). The 7 wt. % treated GSP fibre showed the least stiffness (0.33 MPa), which is 69 % reduction over that of unreinforced fibre. PLA fibre reinforced with 5 wt. % untreated GSP displayed best blend of properties over the unreinforced with increase of 286 % (4.43 x 10 -4 HB), 1,502 % (1.07 MPa), 286 % (0.22 MPa), 6.8 % (0.05 J) and 1,081 % (~ 0.15 MPa) in hardness, stiffness, UTS, energy at break and stress at break respectively. However, ductility decreased by ~33.3 % when compared to the unreinforced (18.27). The 5 wt. % untreated GSP PLA reinforced fibre showed the highest UTS (0.855 MPa). The micrographs showed beads on reinforced fibres, while the virgin PLA showed no beads.

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Section: Methodsmentioning

confidence: 99%

Mechanical characteristics of groundnut shell particle reinforced polylactide nano fibre

et al. 2016

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“…This can be proven by the high number of patents, papers and products already marketed [1][2][3][4][5][6] . Piassava fibers are extracted from the palm tree Attalea funifera Martius.…”

Section: Introducionmentioning

confidence: 99%

Effect of the Glycerol and Lignin Extracted from Piassava Fiber in Cassava and Corn Starch Films

et al. 2015

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“…The environmental awareness attracted researchers to develop new composites with addition of more than one reinforcement from natural resources, such as natural fiber/natural fiber or natural fiber/nanofiller from organic sources as an alternative to synthetic fibers [13]. Hybridization involving the combination of nanofiller and natural fiber in the matrix results reduction of water absorption properties and increased in mechanical properties [14]. Several research works depicts all these facts.…”

Section: Introductionmentioning

confidence: 99%

A Review on Potentiality of Nano Filler/Natural Fiber Filled Polymer Hybrid Composites

2014

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Abstract:The increasing demand for greener and biodegradable materials leading to the satisfaction of society requires a compelling towards the advancement of nano-materials science. The polymeric matrix materials with suitable and proper filler, better filler/matrix interaction together with advanced and new methods or approaches are able to develop polymeric composites which shows great prospective applications in constructions and buildings, automotive, aerospace and packaging industries. The biodegradability of the natural fibers is considered as the most important and interesting aspects of their utilization in polymeric materials. Nanocomposite shows considerable applications in different fields because of larger surface area, and greater aspect ratio, with fascinating properties. Being environmentally friendly, applications of nanocomposites offer new technology and business opportunities for several sectors, such as aerospace, automotive, electronics, and biotechnology industries. Hybrid bio-based composites that exploit the synergy between natural fibers in a nano-reinforced bio-based polymer can lead to improved properties along with maintaining environmental appeal. This review article intended to present information about diverse classes of natural fibers, nanofiller, cellulosic fiber based composite, nanocomposite, and natural fiber/nanofiller-based hybrid composite with specific concern to their applications. It will also provide summary of the emerging new OPEN ACCESSPolymers 2014, 6 2248 aspects of nanotechnology for development of hybrid composites for the sustainable and greener environment.

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Effect of reinforcement nanoparticles addition on mechanical properties of SBS/curauá fiber composites

Cited by 60 publications

References 24 publications

Mechanical characteristics of groundnut shell particle reinforced polylactide nano fibre

Mechanical characteristics of groundnut shell particle reinforced polylactide nano fibre

Effect of the Glycerol and Lignin Extracted from Piassava Fiber in Cassava and Corn Starch Films

A Review on Potentiality of Nano Filler/Natural Fiber Filled Polymer Hybrid Composites

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