Improvement of mechanical properties of carbon/glass fiber reinforced polymer composites through inter-ply arrangement

Jesthi, Dipak Kumar; Mohanty, Santi Swarup; Nayak, Anita; Panigrahi, Abinash; Nayak, Ramesh Kumar

doi:10.1088/1757-899x/377/1/012182

Cited by 3 publications

(5 citation statements)

References 17 publications

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“…It is possible to obtain hybrid composite materials in several ways and then find their mechanical properties related to the previous works. Researchers [4,5,6,7,8] investigated the influence of stacking sequence and the hybrid ratio of woven glass and carbon on the mechanical properties (strength and stiffness) of inter-ply hybrid FRP laminated composites. When the glass: carbon (G: C) hybrid ratio is 1:1, the balance mechanical properties were evaluated either by putting the carbon layers at the surface or by putting different layer types alternatively [4].…”

Section: Glass: Carbon Fiber Hybrid Compositementioning

confidence: 99%

“…When the glass: carbon (G: C) hybrid ratio is 1:1, the balance mechanical properties were evaluated either by putting the carbon layers at the surface or by putting different layer types alternatively [4]. In [5,6,7,8], researchers fabricated ten layers of carbon and glass laminated composites. The [GCGGC]s has tensile and flexural strength more than [CGGCG], while [CGGCG]s has higher tensile and flexural modulus by 20% and 36.2%, respectively, as compared to [GCGGC] [5].…”

Section: Glass: Carbon Fiber Hybrid Compositementioning

confidence: 99%

“…The [GCGGC]s has tensile and flexural strength more than [CGGCG], while [CGGCG]s has higher tensile and flexural modulus by 20% and 36.2%, respectively, as compared to [GCGGC] [5]. Tensile strength, strains, and flexural extension of [G3C2]s were higher by 11.5%, 23%, and 39% than [C2G3]s, but flexural strength and modulus of [C2G3]s were higher by 23% and 64% than [G3C2]s [6]. The tensile and flexural strength of [G2C2G]s were higher by 10.5% and 2.5%, respectively, than that of [CG3C]s, but the tensile strain and flexural extension of [G2C2G]s was 17.5% and 35.8% more than that of [CG3C] S , respectively [7].…”

Section: Glass: Carbon Fiber Hybrid Compositementioning

confidence: 99%

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Mechanical Behavior of Hybrid Laminated Nano Composite Containing Equal Numbers of Glass and Carbon Fiber Plies

Mohammed

Hassan

Khdir

2023

Int. J. Automot. Mech. Eng.

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Hybrid fiber reinforced polymer with nanofiller composite was introduced into a lot of industries due to its extreme mechanical properties in comparison with non-hybrid material. In this investigation, cross and quasi-fiber laminated epoxy composites with and without nano Al2O3 were fabricated using Vacuum Assisted Resine Infusion Method and Ultrasonic Dual Mixing Method. In general, the results of mechanical properties indicated that the addition of 2% nano Al2O3 enhances the tensile and flexural properties. Cross number 2 with nano Al2O3 laminate had the maximum tensile strength 628 MPa and maximum tensile strain of 1.74%, while cross number 1 with nano Al2O3 laminate had the maximum tensile modulus of 37.756 GPa in the cross group. In the quasi group, quasi number 2 with nano Al2O3 had the maximum tensile strength, maximum tensile strain, and maximum tensile modulus, equal to 294 MPa, 1.98%, and 16.409 GPa, respectively. Regarding the flexural properties, cross number 1 with nano Al2O3 laminate had a maximum flexural strength of 708.2 MPa and maximum flexural strain of 2.027%, while cross number 2 with nano Al2O3 laminate had a maximum flexural modulus of 38.73 GPa in the cross group. On the other hand, quasi number 1 with nano Al2O3 laminate had the maximum flexural strength, maximum flexural strain, and maximum flexural modulus equal to 596 MPa, 2.424%, and 29.2 GPa, respectively in the quasi group. The internal structures of the failure laminated composites through scanning electronic microscopy confirm that the adhesion between fibers and matrix is good.

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Section: Glass: Carbon Fiber Hybrid Compositementioning

confidence: 99%

Section: Glass: Carbon Fiber Hybrid Compositementioning

confidence: 99%

Section: Glass: Carbon Fiber Hybrid Compositementioning

confidence: 99%

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Mechanical Behavior of Hybrid Laminated Nano Composite Containing Equal Numbers of Glass and Carbon Fiber Plies

Mohammed

Hassan

Khdir

2023

Int. J. Automot. Mech. Eng.

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“…Woven Kevlar fibers can also improve the fracture toughness of the hybrid composites [8]. Therefore, the hybridization of ductile fibers with high-strength carbon fibers may achieve the desired mechanical properties for different engineering applications at a lower cost [9][10][11][12]. Carbon and Kevlar fibers are costly, which would be a significant barrier to their hybridization.…”

Section: Introductionmentioning

confidence: 99%

“…By increasing the number of high-performance fibers, mechanical properties are improved. It has been suggested that the fatigue and mechanical characteristics of the glass-carbon hybrid composite can be used to build structural components [10,[23][24][25][26]. Cihan et al [27] reported that both pure flax composites and flax hybrid composites exhibit excellent mechanical properties compared to E-glass fiber-reinforced polymer composites.…”

Section: Introductionmentioning

confidence: 99%

Development of Improved Flexural and Impact Performance of Kevlar/Carbon/Glass Fibers Reinforced Polymer Hybrid Composites

et al. 2022

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The present investigation focuses on developing cost-effective Carbon/Glass/Kevlar fiber-reinforced polymer hybrid composite laminates for achieving its synergistic effect on flexural and impact performance. It investigates the effect of stacking sequence induced by the use of different fiber types (Kevlar = K, glass = G, and carbon = C) on the flexural and impact performance of the composites. Five hybrid composites (labelled as A = [G2K3G2], B = [KG2CG2K], C = [CKGCGKC], D = [CGKCKGC], E = [CK2CK2C]) and three plain (i.e., non-hybrid) composites (F = [K]7, G = [G]7, H = [C]7) have been fabricated through manual pre-preg lay-up manufacturing techniques. The flexural strength and modulus, hardness, and Izod impact strength have been evaluated for the fabricated composites and compared. The results showed that the D-type hybrid composite achieves the maximum positive hybrid effect as compared to other hybrid composites, possesses a hardness of 59 BHN, a flexural strength of 380 MPa, and modulus of 36 GPa, and impact strength of 80 KJ/m2. The fracture surfaces of the hybrid composite specimen have been analysed using scanning electron microscopy, and compared against the properties achieved for enabling correlations. Furthermore, the cost-efficiency of the hybridization in terms of flexural strength/cost, modulus/cost, and impact strength/cost ratio were evaluated for potential engineering and design applications.

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Effect of Nano-TiO2 Content (wt.%) on Hardness of Epoxy Polymer Matrix Nanocomposites

Chanda

Mishra

Rout

et al. 2023

Lecture Notes in Mechanical Engineering

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Improvement of mechanical properties of carbon/glass fiber reinforced polymer composites through inter-ply arrangement

Cited by 3 publications

References 17 publications

Mechanical Behavior of Hybrid Laminated Nano Composite Containing Equal Numbers of Glass and Carbon Fiber Plies

Mechanical Behavior of Hybrid Laminated Nano Composite Containing Equal Numbers of Glass and Carbon Fiber Plies

Development of Improved Flexural and Impact Performance of Kevlar/Carbon/Glass Fibers Reinforced Polymer Hybrid Composites

Effect of Nano-TiO2 Content (wt.%) on Hardness of Epoxy Polymer Matrix Nanocomposites

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