Influence of multiwalled carbon nanotube on progressive damage of epoxy/carbon fiber reinforced structural composite

Bhowmik, Krishnendu; Khutia, Niloy; Tarfaoui, Mostapha; Jana, Mrinmoy; Das, Kaushik; Roy, Tarapada; Bandyopadhyay, Abhijit; Chowdhury, Amit Roy

doi:10.1002/pc.26877

Cited by 10 publications

(7 citation statements)

References 44 publications

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“…Soliman et al [ 15 ] explored the low‐velocity impact response of functionalized‐CNTs/carbon fibers/EP composite and reported that the CNTs addition increased the absorbed energy. The positive effect of MWCNTs on the tensile response of carbon fiber‐EP composites was also shown by Bhowmik et al [ 18 ]…”

Section: Introductionsupporting

confidence: 60%

Effect of CNTs/nano‐TiO₂ hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

2023

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In this paper, the individual and synergistic effects of silanized-multiwalled carbon nanotubes (S-MWCNTs) and silanized-Titanium dioxide (S-TiO 2 ) nanoparticles on the drop-weight impact response of Kevlar fiber-reinforced epoxy (KE-EP) composites were evaluated. In the first step, the nanofillers were functionalized using an amino organosilane coupling agent (3-Aminopropyltrimetoxysilane [APTMS]). Next, multiscale composites were prepared by adding 0.3 wt% S-MWCNTs, 1 wt% S-TiO 2 , and 0.3 wt% S-MWCNTs + 1 wt% S-TiO 2 in the matrix.The samples were exposed to drop-weight impact at various impact energies of 15, 30, and 45 J. The findings demonstrated that the sample filled with 0.3 wt% S-MWCNTs + 1 wt% S-TiO 2 had the best impact performance, regardless of the initial impact energy. When compared to the neat KE-EP sample, the multiscale composite filled with 0.3 wt% S-MWCNTs + 1 wt% S-TiO 2 had greater peak force and absorbed energy by 23% and 18%, respectively under 45 J impact energy. Analysis of the fracture surfaces illustrated a good interfacial bonding between the Kevlar fibers and matrix for the multiscale composite having hybrid nanofillers. K E Y W O R D Sdrop-weight impact test, fiber-reinforced composite, Kevlar fiber, multiwalled carbon nanotubes, nano-TiO 2

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Section: Introductionsupporting

confidence: 60%

Effect of CNTs/nano‐TiO₂ hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

2023

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“…[10][11][12][13] The addition of 1 wt% CNTs can increase the matrix's electrical conductivity by up to 10 orders of magnitude. [14,15] Introducing dispersed CNTs is known to enhance not only the strength [16,17] and stiffness of composites [18,19] but also their fracture toughness. [20][21][22] However, the formation of local agglomerations of CNTs bundles during resin impregnation process is likely to create singularities and decrease the mechanical properties of the composites.…”

Section: Introductionmentioning

confidence: 99%

Mode I and mode II fracture behavior in nano‐engineered long fiber reinforced composites

Govignon

Rivallant

et al. 2023

Polymer Composites

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Delamination still remains one of the common concerns in continuous fibers reinforced polymer composites. In the literature, the incorporation of nanoconstituents into constitutive composites plies has been suggested with the aim of improving interface toughness. In this study, vertically aligned carbon nanotubes forests (VACNTs) are transferred at composites interfaces, and mode I (DCB tests) and mode II (ENF tests) fracture tests carried out on composite samples. Microscopic analysis of reference and nano‐engineered composites help to understand fracture behavior and toughness. While the crack path in ENF samples is observed at interlaminar VACNTs‐resin interfaces, the crack path in DCB samples is intralaminar, located within the unidirectional carbon fiber plies. These microscopic observations give explanation for unstable crack propagation in nano‐engineered ENF samples and the unchanged toughness from the nano‐engineered to the reference zone in DCB samples.

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“…Among the various types of thermoplastic resins, polyamide 6 (PA6) is frequently selected as matrix resin for manufacturing CFRTP due to its high‐impact resistance, processability, recyclability, and low cost. [ 1 ] It is generally recognized that the interfacial properties not only determine comprehensive mechanical properties, [ 2–4 ] but also affect moisture absorption, [ 5 ] aging resistance [ 6 ] and fracture behavior [ 7 ] of the composites. However, the epoxy‐based sizing on the as‐received carbon fibers (CFs) is designed for thermosetting matrix resin, [ 8 ] which may undergo thermal degradation at the processing temperature of CFRTP [ 9,10 ] and presents weak compatibility with thermoplastic matrix resin.…”

Section: Introductionmentioning

confidence: 99%

Effects of functionalized graphene oxide modified sizing agent on the interfacial and mechanical properties of carbon fiber reinforced polyamide 6 composites

et al. 2022

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In this study, a novel functionalized graphene oxide (F-GO) modified polyamide 6 (PA6) sizing agent is developed to improve the interfacial and mechanical properties of carbon fiber (CF) reinforced PA6 composites. To enhance compatibility between GO and sizing agent, PA6 molecular chains are covalently grafted onto the GO sheets in advance. The results show that the F-GO modified sizing layer improves interfacial compatibility and wettability of the CF surface. Moreover, F-GO nanoparticles retard crack propagation along the interface based on the reinforcement effect. Accordingly, the interfacial shear strength increases by 54.5% from 45.1 MPa for desized CF/PA6 composites to 69.7 MPa for F-GO modified sizing agent treated CF/PA6 composites. Meanwhile, the average interlaminar shear strength, tensile strength, and flexural strength increase by 45.2%, 15.6%, and 19.3% from 45.7, 1307.4, and 792.2 MPa for desized CF/PA6 composites to 66.3, 1511.2, and 945.2 MPa for those reinforced with the CFs treated by the F-GO modified sizing agent due to the effective stress transfer across the interface. The improvement in the mechanical properties is verified based on the cross-section morphology and fracture surfaces.

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Influence of multiwalled carbon nanotube on progressive damage of epoxy/carbon fiber reinforced structural composite

Cited by 10 publications

References 44 publications

Effect of CNTs/nano‐TiO₂ hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

Effect of CNTs/nano‐TiO₂ hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

Mode I and mode II fracture behavior in nano‐engineered long fiber reinforced composites

Effects of functionalized graphene oxide modified sizing agent on the interfacial and mechanical properties of carbon fiber reinforced polyamide 6 composites

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Influence of multiwalled carbon nanotube on progressive damage of epoxy/carbon fiber reinforced structural composite

Cited by 10 publications

References 44 publications

Effect of CNTs/nano‐TiO2 hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

Effect of CNTs/nano‐TiO2 hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

Mode I and mode II fracture behavior in nano‐engineered long fiber reinforced composites

Effects of functionalized graphene oxide modified sizing agent on the interfacial and mechanical properties of carbon fiber reinforced polyamide 6 composites

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Product

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Effect of CNTs/nano‐TiO₂ hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites

Effect of CNTs/nano‐TiO₂ hybrid system on the drop‐weight impact response of Kevlar fiber/epoxy composites