Effects of silane surface modified alumina nanoparticles on the mechanical, thermomechanical, and ballistic impact performances of epoxy/oxidized <scp>UHMWPE</scp> composites

Belgacemi, Raouf; Derradji, Mehdi; Mouloud, Abdelrazak; Zegaoui, Abdeldjalil; Mehelli, Oussama; Khiari, Karim

doi:10.1002/pc.25730

Cited by 21 publications

(11 citation statements)

References 30 publications

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“…The tan delta peak has also been extended which is a direct result of the loading of the reinforcing nanophase, this is known as the relaxation process. [ 35 ] Moreover, the incorporation of the nanofillers also produced the reducing of the Tan Delta peak height, this is also known as the dilution phenomena. [ 36 ]…”

Section: Resultsmentioning

confidence: 99%

Toward an efficient stress transfer with a fully connected hybrid network from epoxy, oxidized UHMWPE fibers, and silane surface modified silicon carbide nanoparticles

et al. 2020

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In this work, a new high‐performance hybrid material was designed targeting excellent static and dynamic mechanical properties. To achieve this goal, the hybrid constituents, namely the ultra‐high molecular weight polyethylene fibers and silicon carbide nanoparticles, were respectively, surface modified to graft the proper chemical species in order to maximize the interactions between the reinforcing phases and the epoxy matrix. The adopted grafting procedures were characterized by vibrational and morphological analyses. The generation a fully connected network resulted in consequent ameliorations in the mechanical and thermomechanical properties. Meanwhile, the effect of various amounts of the treated silicon carbide nanoparticles was also investigated. The finding indicated a gradual improvement in the overall mechanical properties up to 5 wt% for which the tensile strength reached its maximum value of about 477 MPa. The same hybrid materials displayed the remarkable storage modulus of 7.7 GPa at 25°C and a glass transition temperature of about 66°C. The synergistic stress transfer between the constituents was further evidenced by a proper investigation of the sample's fractured surfaces. Overall, the study revealed the great advantage of a fully connected network in developing lightweight and high‐performance materials for exigent applications.

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Section: Resultsmentioning

confidence: 99%

Toward an efficient stress transfer with a fully connected hybrid network from epoxy, oxidized UHMWPE fibers, and silane surface modified silicon carbide nanoparticles

et al. 2020

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“…Flexural stressstrain curves demonstrate that as the nanofiller concentration increases from 1% to 4%, the strain percentage decreases gradually, which indicates that the ductility of the composite decreases. This is associated with less chain mobility and deformability of the matrix due to the presence of additional rigid nanofillers, which disturb the deformation of the crystalline region in the matrix, resulting in improved bending properties [13,62]. Additionally, it is noted that none of the samples failed abruptly, but exhibited pseudo-plastic behaviour before reaching the ultimate flexural stress value.…”

Section: Flexural Propertiesmentioning

confidence: 99%

Effect of Fibre Surface Treatment and Nanofiller Addition on the Mechanical Properties of Flax/PLA Fibre Reinforced Epoxy Hybrid Nanocomposite

et al. 2021

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Natural fibre-based materials are gaining popularity in the composites industry, particularly for automotive structural and semi-structural applications, considering the growing interest and awareness towards sustainable product design. Surface treatment and nanofiller addition have become one of the most important aspects of improving natural fibre reinforced polymer composite performance. The novelty of this work is to examine the combined effect of fibre surface treatment with Alumina (Al2O3) and Magnesia (MgO) nanofillers on the mechanical (tensile, flexural, and impact) behaviour of biotex flax/PLA fibre reinforced epoxy hybrid nanocomposites. Al2O3 and MgO with a particle size of 50 nm were added in various weight proportions to the epoxy and flax/PLA fibre, and the composite laminates were formed using the vacuum bagging technique. The surface treatment of one set of fibres with a 5% NaOH solution was investigated for its effect on mechanical performance. The results indicate that the surface-treated reinforcement showed superior tensile, flexural, and impact properties compared to the untreated reinforcement. The addition of 3 wt. % nanofiller resulted in the best mechanical properties. SEM morphological images demonstrate various defects, including interfacial behaviour, fibre breakage, fibre pullout, voids, cracks, and agglomeration.

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“…Nano-SiO 2 was dried in a vacuum at 105 C for 6 h to remove the adsorbed moisture. The dried nano-SiO 2 was placed in 3-triethoxysilylpropylamine (5 wt% of nano-SiO 2 ) ethanol solution, mechanically stirred for 24 h. The activated SiO 2 was rinsed with ethanol solution three times to remove the surface silane coupling agent, and dried in an oven at 60 C for 12 h. 37…”

Section: Surface Activation Of Siomentioning

confidence: 99%

High‐performance fiber‐reinforced composites with a polydopamine/epoxy silane hydrolysis‐condensate bilayer on surface of ultra‐high molecular weight polyethylene fiber

Zhang

Cao

Zhou

et al. 2021

J of Applied Polymer Sci

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A bilayer structure with polydopamine (PDA) transition layer and 3-glycidyl ether oxy-propyl trimethoxy silane (GOPTS) hydrolysiscondensate strengthened layer on the surface of ultra-high molecular weight polyethylene (UHMWPE) fiber is prepared to improve the damage resistance of composites and more efficient stress transmission in composites. PDA is covered on the surface of UHMWPE fiber and then GOPTS is hydrolyzed and condensed to form inorganic -O-Si-O-with epoxy groups on the PDA layer. In addition, the surface activated nano-SiO 2 is dispersed in the epoxy resin to increase the strength of the matrix resin. The results show that the interfacial shear strength (IFSS), the impact strength, the flexural strength and flexural modulus of UHMWPE-PDA-GOPTS/EP-SiO 2 increase by 99.1%, 54.1%, 76.8%, and 36.6% respectively compared with unmodified UHMWPE/EP. The chemical compositions of the treated fiber surface are characterized by X-ray photoelectron spectroscopy and Fourier transform infrared spectroscopy (ATR-FTIR). With the help of the scanning electron microscopy, the interface failure and reinforcement mechanism of the composites are further explored due to UHMWPE fiber shear yield deformation, UHMWPE fiber fracture, matrix resin cracking and the relative sliding friction between the fiber and matrix.

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Effects of silane surface modified alumina nanoparticles on the mechanical, thermomechanical, and ballistic impact performances of epoxy/oxidized UHMWPE composites

Cited by 21 publications

References 30 publications

Toward an efficient stress transfer with a fully connected hybrid network from epoxy, oxidized UHMWPE fibers, and silane surface modified silicon carbide nanoparticles

Toward an efficient stress transfer with a fully connected hybrid network from epoxy, oxidized UHMWPE fibers, and silane surface modified silicon carbide nanoparticles

Effect of Fibre Surface Treatment and Nanofiller Addition on the Mechanical Properties of Flax/PLA Fibre Reinforced Epoxy Hybrid Nanocomposite

High‐performance fiber‐reinforced composites with a polydopamine/epoxy silane hydrolysis‐condensate bilayer on surface of ultra‐high molecular weight polyethylene fiber

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