Synthesis and Characterization of Hybrid Fiber-Reinforced Polymer by Adding Ceramic Nanoparticles for Aeronautical Structural Applications

Bafakeeh, Omar T.; Shewakh, Walid Mahmoud; Abu-Oqail, Ahmed; Abd‐Elaziem, Walaa; Ghafaar, M. Abdel; Abu–Okail, Mohamed

doi:10.3390/polym13234116

Cited by 26 publications

(12 citation statements)

References 42 publications

(49 reference statements)

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“…[1] As reported by Ma et al, [2] thin-walled structures can serve as an ideal energy absorber due to its several benefits, such as good energy absorbing capacity (EAC), high stiffness, strength, and corrosion resistance, lightweight, low cost, and ease of fabrication. [3][4][5][6] Several candidates of materials and different cross-sections can be applied for energy absorbing purposes. Traditionally metals like steel and aluminum (Al) are used because of their controlled plastic deformation.…”

Section: Introductionmentioning

confidence: 99%

The influence of induced holes on crashworthy ability of glass reinforced epoxy square tubes

2022

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The crashworthy ability of glass/epoxy (GFRP) square tubes with induced holes was studied under quasi‐static axial crashing. Four design parameters were chosen, each at three levels, to calculate crashworthiness indicators. The design variables are hole diameter (d), hole position/specimen length (P/L), number of holes/distribution (n), and speed (V). To get the optimum crashworthiness parameters, the design of experiments approach using Taguchi technique was adapted. Optimal conditions with minimum initial peak force (normalFip), maximum absorbed energy (U) and maximum specific energy absorption (SEA) were determined. Main effect, signal/noise ratio (S/N), and analysis of variance (ANOVA) were determined using MINITAB 18. Experiments based on L9 orthogonal array were performed. Results indicated that the dominant influencing parameter on normalFip is “n” with a contribution of 93.97%. “V” followed by “d” are the highest influencing parameters on “U” with a contribution of 49.07 and 43.02%, respectively. “d” is the highest influencing parameter on SEA, followed by “V” with a contribution of 50.71% and 46.12%, respectively. Confirmation tests were carried out to validate the estimated model with respect to experimental results. normalFip, U, and SEA of intact tube were 45.05 kN, 830.32 × 10−3 kJ, and 8.23 × 10−3 kJ/g, respectively. The optimum normalFipof GFRP tubes with cutouts was found to be 38.59% smaller than that of the intact specimen. The optimum U and SEA of are, respectively, 4.73% and 25.76% greater than those of intact specimen.

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Section: Introductionmentioning

confidence: 99%

The influence of induced holes on crashworthy ability of glass reinforced epoxy square tubes

2022

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“…1,2 Crashworthy elements as energy absorbers are widely composed of thin-walled structures due to their several benefits, such as good energy absorbing capacity (EAC), high stiffness, strength, and corrosion resistance, light weight, low cost, and ease of fabrication. 3,4 Several candidates of materials and different cross-sections can be applied for energy absorbing purposes. Traditionally, metals like steel (St) and aluminum (Al) are used because of their controlled plastic deformation [5][6][7][8] .…”

Section: Introductionmentioning

confidence: 99%

Quasi-static axial crushing performance of thin-walled tubes with circular hole discontinuities

Alshahrani

Sebaey

Allah

et al. 2022

Journal of Composite Materials

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This paper investigates the crashworthiness performance of square pipes with induced holes. Glass reinforced epoxy (GFRP) specimens were fabricated and tested under quasi-static axial crashing. Four design parameters were chosen, each at three levels, to calculate crashworthiness indicators. The design parameters are the hole diameter (d), the hole position to specimen length ratio (P/L), the number of holes and distribution (n), and crosshead speed (V). Taguchi technique has been adapted to get the optimum crashworthiness parameters. Experiments based on Taguchi’s orthogonal array with 9 experimental runs (L9) were performed. Optimal conditions with the maximum absorbed energy (U) and minimum initial peak force ([Formula: see text]) were determined. The main effects, signal to noise ratio (S/N), and analysis of variance (ANOVA) have been investigated. Results indicated that “V” followed by “d” are the highest influencing parameters on the values of “U” with a contribution of 49% and 43%, respectively. The dominant influencing parameter on the values of [Formula: see text] is “n” with a contribution of 94%. Finally, confirmation tests were carried out to validate the estimated model with respect to experimental results. The optimum U and [Formula: see text] of GFRP square pipes with circular cutouts were compared with those of non-porous specimens.

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“…Munoz et al [ 22 ] have developed a graphene oxide dispersion technique that involves many steps of mechanical dispersion in water and centrifugation, finally followed by a freeze-drying step of the GO suspension: the so obtained aerogel is mechanically mixed with the epoxy matrix and the resulting nanocomposite is characterized by an improvement of the compression strength (+39%) with only 0.3 wt% of GO. Furthermore, in the case of CFRPs, the approach consisting of the addition of micro/nanoparticles [ 23 , 24 ] to the polymer matrix, allows to remarkably improve their mechanical properties: for example, in the work of Mostovoy et al [ 25 ], the addition of the APTES/aminoacetic acid functionalized graphene oxide induces an increase in the tensile strength and modulus of about 39% and 31%, respectively, due to the improvement of the interfacial strength between the fibers and the matrix. By adding 5 wt% of SiC NPs, Alsadi [ 26 ] increased the mode II interlaminar fracture toughness of CFRPs and aramidic fiber reinforced polymers of about 34% and 46%, respectively.…”

Section: Introductionmentioning

confidence: 99%

Effect of the Mixing Technique of Graphene Nanoplatelets and Graphene Nanofibers on Fracture Toughness of Epoxy Based Nanocomposites and Composites

et al. 2022

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In this work, the effect of different mixing techniques on thermal and mechanical properties of graphene nanoplatelets (GNPs) and graphene nanofibers (GANFs) loaded epoxy nanocomposites was investigated. Three dispersion methods were employed: a high shear rate (HSR), ultrasonication (US) and the fluidized bed method (FBM). The optical microscopy has revealed that the most suitable dispersion, in terms of homogeneity and cluster size, is achieved by implementing the US and FBM techniques, leading to nanocomposites with the largest increase of glass transition temperature, as supported by the DMA analysis data. The fracture toughness results show a general increase of both the critical stress intensity factor (KIC) and the critical strain energy release rate (GIC), likely due to the homogeneity and the low scale dispersion of the carbonaceous nanostructures. Based on the nanocomposite fracture toughness improvements and also assuming a potential large scale up production of the nanocomposite matrix, a single mixing technique, namely the FBM, was employed to manufacture the carbon fiber reinforced composite (CFRC). This method has resulted in being less time-consuming and is potentially most suitable for the high volume industrial production. The CFRCs were characterized in terms of tensile, flexural and interlaminar fracture toughness properties and the results were analyzed and discussed.

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Synthesis and Characterization of Hybrid Fiber-Reinforced Polymer by Adding Ceramic Nanoparticles for Aeronautical Structural Applications

Cited by 26 publications

References 42 publications

The influence of induced holes on crashworthy ability of glass reinforced epoxy square tubes

The influence of induced holes on crashworthy ability of glass reinforced epoxy square tubes

Quasi-static axial crushing performance of thin-walled tubes with circular hole discontinuities

Effect of the Mixing Technique of Graphene Nanoplatelets and Graphene Nanofibers on Fracture Toughness of Epoxy Based Nanocomposites and Composites

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