Toughened carbon fibre-reinforced polymer composites with nanoparticle-modified epoxy matrices

Carolan, Declan; Ivanković, Alojz; Kinloch, A. J.; Sprenger, Stephan; Taylor, A. C.

doi:10.1007/s10853-016-0468-5

Cited by 89 publications

(46 citation statements)

References 51 publications

(75 reference statements)

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“…The nano-silica was obtained pre-dispersed at 40% in DGEBA (Nanopox F400, Evonik Hanse) or HDE (Nanopox F640, Evonik Hanse) to achieve the desired concentrations. Surface functionalisation with amine and the spherical shape of the particles ensure good dispersion as has been shown in samples prepared in the same fashion [33]. Table 1 summarises the compositions of the samples used.…”

Section: Methodsmentioning

confidence: 91%

Simultaneous improvements in flammability and mechanical toughening of epoxy resins through nano-silica addition

Roenner

Hutheesing

Fergusson³

et al. 2017

Fire Safety Journal

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Section: Methodsmentioning

confidence: 91%

Simultaneous improvements in flammability and mechanical toughening of epoxy resins through nano-silica addition

Roenner

Hutheesing

Fergusson³

et al. 2017

Fire Safety Journal

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“…giving a CTT \ 0.5. However, values of the CTT of 1.0 have also been reported [23] for 4 wt% of nanosilica filler particles in an anhydride-cured epoxy polymer with respect to a CFRP composite. Also, values of CTT of 5.5 were found for 10 wt% of nanosilica filler particles in a similar anhydride-cured epoxy polymer employed as the matrix for an unidirectional (UD) GFRP composite [24].…”

Section: Introductionmentioning

confidence: 96%

On the extent of fracture toughness transfer from 1D/2D nanomodified epoxy matrices to glass fibre composites

et al. 2020

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In this study, the effects of adding nanofillers to an epoxy resin (EP) used as a matrix in glass fibre-reinforced plastic (GFRP) composites have been investigated. Both 1D and 2D nanofillers were used, specifically (1) carbon nanotubes (CNTs), (2) few-layer graphene nanoplatelets (GNPs), as well as hybrid combinations of (3) CNTs and boron nitride nanosheets, and (4) GNPs and boron nitride nanotubes (BNNTs). Tensile tests have shown improvements in the transverse stiffness normal to the fibre direction of up to about 25% for the GFRPs using the 'EP ? CNT' and the 'EP ? BNNT ? GNP' matrices, compared to the composites with the unmodified epoxy ('EP'). Mode I and mode II fracture toughness tests were conducted using double cantilever beam (DCB) and end-notched flexure (ENF) tests, respectively. In the quasi-static mode I tests, the values of the initiation interlaminar fracture toughness, G C IC , of the GFRP composites showed that the transfer of matrix toughness to the corresponding GFRP composite is greatest for the GFRP composite with the GNPs in the matrix. Here, a coefficient of toughness transfer (CTT), defined as the ratio of mode I initiation interlaminar toughness for the composite to the bulk polymer matrix toughness, of 0.68 was recorded. The highest absolute values of the mode I interlaminar fracture toughness at crack initiation were achieved for the GFRP composites with the epoxy matrix modified with the hybrid combinations of nanofillers. The highest value of the CTT during steady-state crack propagation was * 2 for all the different types of GFRPs. Fractographic analysis of the composite surfaces from the DCB and ENF specimens showed that failure was by a combination of cohesive (through the matrix) and interfacial (along the fibre/matrix interface) modes, depending on the type of nanofillers used.

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“…Many polymer nanocomposites consist of polymers and thermally conductive nanomaterial were reported to obtain polymers with high thermal conductivity [10][11][12]. The commonly used nanomaterial include carbon(carbon nanotubes [13], carbon nanofibers [14], graphene [15], etc. ), oxides (aluminum oxide (Al 2 O 3 ) [16], beryllium (BeO) [17], (titanium oxide(TiO 2 ) [18], etc.…”

Section: Introductionmentioning

confidence: 99%

Thermal and mechanical properties study of boron nitride nanosheets decorated by silver/epoxy nanocomposites

Zhang

2020

SN Appl. Sci.

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Epoxy is widely used in mechanical and electronic industries due to its excellent adhesive properties and mechanical performances. However, the poor thermal conductivity limits its application, especially in high density equipment. In order to improve the thermal conductivity of epoxy, silver nanoparticles decorated boron nitride nano-sheets (Ag-BN) were prepared and incorporated into the epoxy matrix to obtain nanocomposites (EP-AB) in this work. The EP-AB behaves a significant enhancement of 1089% at an Ag-BN loading of 25 vol% compared to the pure epoxy. The thermogravimetric curve shows that the thermal stability of nanocomposites is improved with the addition of Ag-BN. Moreover, dynamic thermomechanical analysis reveals that Ag-BN can effectively reduce the segmental mobility of the epoxy matrix, which helps to improve the stiffness, decrease the mechanical loss, and increase the glass transition temperature of EP-AB. Those three properties gain an optimum value when the content of Ag-BN is 20 vol%. Also, the nanocomposites perform more stability in mechanical properties than pure epoxy under a varied frequency. The Cole-Cole plot of storage modulus and loss modulus shows that the pure epoxy and nanocomposites with low nanomaterial content are homogenous and the uniformity begins to decrease when the addition of Ag-BN is 20 vol%.

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Toughened carbon fibre-reinforced polymer composites with nanoparticle-modified epoxy matrices

Cited by 89 publications

References 51 publications

Simultaneous improvements in flammability and mechanical toughening of epoxy resins through nano-silica addition

Simultaneous improvements in flammability and mechanical toughening of epoxy resins through nano-silica addition

On the extent of fracture toughness transfer from 1D/2D nanomodified epoxy matrices to glass fibre composites

Thermal and mechanical properties study of boron nitride nanosheets decorated by silver/epoxy nanocomposites

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