Elevated temperature mechanical behavior of waste short carbon fiber incorporated glass fiber/epoxy composites

Dasari, Srinivasu; Patnaik, Satyaroop; Behera, P.; Ray, Bankim Chandra; Prusty, Rajesh Kumar

doi:10.1002/pc.27089

Cited by 8 publications

(10 citation statements)

References 76 publications

(99 reference statements)

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“…The nitrogen flow rate was kept constant at 200 mL/min. The optimum loaded samples (8-10 mg) were heated from ambient temperature to 800 C at different heating rates (5,10,20, and 40 C/min). The specimens were measured precisely (0.005 g) before being aged and subjected to characterization.…”

Section: Characterization Of Fabricated Composites Materialsmentioning

confidence: 99%

“…[ 4 ] In contrast, enormously efficient composites, such as synthetic fibers like nylon, glass, polyesters, metallic and carbon fibers, have a broad array of applications in industries such as household goods and aerospace. [ 5 ] Although, the issue with recycling and its need for significant amounts of energy sources like fossil fuels for operations cause environmental degradation on earth. The distinct properties of bio‐composites using natural fibers are superior to synthetic fibers in some determined situations, making them potentially more sustainably beneficial than glass or carbon fiber reinforced composites in significant applications.…”

Section: Introductionmentioning

confidence: 99%

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Response of extreme environmental aging on the novel Moringa stenopetala husk fiber/epoxy composites: Understanding the characteristics and thermokinetic behavior

Mishra

Sinha

2023

Polymer Composites

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The increasing use of composite components in various engineering disciplines necessitates detailed comprehension of their operation. When subjected to adverse environmental circumstances, such as variable humid surroundings and UV radiations, the structural and mechanical characteristics of the composites can deteriorate. Additionally, using these composite materials for structural applications such as rooftop buildings or household properties may reduce lifespan. In this study, the static and dynamic mechanical properties and the stability of novel lignocellulosic Moringa stenopetala (MS) husk fiber‐based epoxy composites exposed to various environmental factors were assessed. These harsh conditions were picked to imitate those encountered outside and influence the longevity of these composites. The obtained fiber from the husk was examined for its physiological, structural, and thermal characteristics. Using the Broido, Kissinger, Flynn‐Wall‐Ozawa (FWO), Coats‐Redfern and Kissinger‐Akahira‐Sunose (KAS) isoconventional models, the thermal degradation kinetics of the fibers were investigated. KAS method results in the best‐fitted curve and shows maximum activation energy of 175.13 KJ/mol. After husk fiber assessment, composite materials were fabricated using a Hand layup method, and their static and dynamic mechanical properties, water uptake rate, and contact angle analysis with surface energy behavior under various environmental aging circumstances were studied. In comparison to the composites “as developed,” the findings indicate that the mechanical characteristics of husk fiber‐based epoxy composites are significantly reduced by humidity and UV aging. Overall, the development of thermoset composites for structural applications can utilize husk fiber. Furthermore, after curing the water and UV‐aged composites, qualities can be recovered.

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Section: Characterization Of Fabricated Composites Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Response of extreme environmental aging on the novel Moringa stenopetala husk fiber/epoxy composites: Understanding the characteristics and thermokinetic behavior

Mishra

Sinha

2023

Polymer Composites

View full text Add to dashboard Cite

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“…[30,[42][43][44] However, GF benefits from significantly lesser price, an important economic factor for mass production in industries. [36,45,46] Additionally, CF is developed from fossil fuels that are presently deliberated limited nonrenewable materials. Adopting a fiber hybridization technique might be feasible for minimizing the environmental impact and cost.…”

Section: Introductionmentioning

confidence: 99%

Mode I and II interlaminar fracture toughness of glass/carbon inter‐ply hybrid FRP composites: Effects of stacking sequence and testing temperature

et al. 2023

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Even though laminated FRP composites show exceptional performance in various modes of loading, they are susceptible to delamination. The ambient temperature and elevated temperature delamination resistance of glass/carbon fiber interply hybrid composites were assessed via mode I and mode II interlaminar fracture toughness tests performed at 30, 50 and 70 C. Interply hybrid composites performed better than composites with single type of fiber. The fracture toughness of inter-ply hybrid composites varied with the stacking position. At 30 C, mode I fracture toughness value of alternative glass and carbon fiber stacking sequence (G 1 C 1 ) 5 of hybrid composite showed 40% improvement over 10 layered carbon/epoxy (C 10 ) composite. Further, Mode II fracture toughness of C 5 G 5 composite showed 22% enhancement, and C 10 exhibited 42% improvement over 10-layered glass/epoxy composite. Increasing the test temperature of all composites improved their G IC and G IIC values. The increment in the mode I fracture toughness properties of all composite was in the range of 5%-23% at 70 C from its room temperature value. The fractographic images of fractured samples were studied under a scanning electron microscope and failure mechanisms of composites were identified. K E Y W O R D Shigh temperature durability, inter-ply hybrid composite, mode I ILFT, mode II ILFT, stacking sequence of glass and carbon fibers

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“…14,15 The introduction of nanomaterials (e.g., clay, graphene) into GFRP to improve both interfacial adhesion and matrix properties has become a hot topic. [16][17][18][19][20][21] Li et al fabricated the graphene/carbon fiber (CF) hierarchical reinforcements by sizing deposition to improve the interfacial bonding. Compared to the untreated CF composites, the interlaminar shear strength (ILSS) and flexural strength of graphene-modified composites increased by 23.2% and 34.4%, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…Such interfacial layer is conducive to stress transfer and dispersion, thus effectively restraining crack propagation 14,15 . The introduction of nanomaterials (e.g., clay, graphene) into GFRP to improve both interfacial adhesion and matrix properties has become a hot topic 16–21 . Li et al fabricated the graphene/carbon fiber (CF) hierarchical reinforcements by sizing deposition to improve the interfacial bonding.…”

Section: Introductionmentioning

confidence: 99%

Enhanced interfacial and mechanical properties of glass fabric/epoxy composites via grafting silanized carbon nanotubes onto the fibers

et al. 2023

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For enhancing the interfacial adhesion of glass fabric (GF)/epoxy composites, silanized multi‐walled carbon nanotubes (MWCNTs) were used to treat GF surface, where carboxyl MWCNTs were functionalized by silane coupling agents based on the covalent or non‐covalent bonding, followed by the vacuum infusion process of laminated composites. A detailed study was employed to confirm the effects of silanized MWCNTs uniform dispersion and interfacial properties of resultant composites. Making full use of suitable silane coupling agents (γ‐aminopropyltriethoxysilane) treatment, the uniform MWCNTs dispersion and strong fiber/matrix interfacial adhesion could be achieved. Compared with the control sample, flexural and interlaminar shear strengths of resultant composites were enhanced by about 24% and 22%, respectively, indicating superior mechanical strength for composites; flexural modulus and storage modulus in the glassy state were improved by about 36% and 68%, respectively, suggesting higher stiffness for composites; the work of fracture (Wf) under interlaminar shear tests was raised by about 188%, revealing better interlaminar fracture toughness of composites. In addition, glass transition temperature of resultant composites also increased. This work provides a guiding strategy for manufacturing fiber‐reinforced composites requiring adjustable strength, stiffness, and toughness.Highlights Silane coupling agent was grafted on MWCNTs by covalent/non‐covalent bonding. Active groups of silanized MWCNTs induced crosslinking reactions with matrix. Silanized MWCNTs dispersion and glass fiber/matrix adhesion were improved. Strengthening/toughening mechanisms of laminated composites were analyzed.

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Elevated temperature mechanical behavior of waste short carbon fiber incorporated glass fiber/epoxy composites

Cited by 8 publications

References 76 publications

Response of extreme environmental aging on the novel Moringa stenopetala husk fiber/epoxy composites: Understanding the characteristics and thermokinetic behavior

Response of extreme environmental aging on the novel Moringa stenopetala husk fiber/epoxy composites: Understanding the characteristics and thermokinetic behavior

Mode I and II interlaminar fracture toughness of glass/carbon inter‐ply hybrid FRP composites: Effects of stacking sequence and testing temperature

Enhanced interfacial and mechanical properties of glass fabric/epoxy composites via grafting silanized carbon nanotubes onto the fibers

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