Thermoelastic Stability Behavior of Curvilinear Fiber‐Reinforced Composite Laminates With Different Boundary Conditions

Ganapathi, M.; Bharath, Anirudh; Das, Aditya Narayan; Chandra, Anant; Barua, Pradyumna

doi:10.1002/pc.25116

Cited by 6 publications

(3 citation statements)

References 57 publications

(77 reference statements)

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“…Sheet-molded composites (SMCs) are fabricated by bonding homogeneous layers of materials using a compression molding process to form nonhomogeneous composite laminates. The laminate is composed of layers and, in the case of FRP composites made of fiber sheets, buckling stability of the material improves with increasing the number of layers in the laminate [110]. SMC shows the application in large structural components like automotive body parts consisting of high strength to weight ratio [111,112,113].…”

Section: Classificationmentioning

confidence: 99%

“…Stress concentration factor (SCF) plays an important role while considering the failure prediction, without consideration of SCFs transverse strength will be overestimated [124]. Thermal buckling load for curvilinear fiber-reinforced composite laminates is more for antisymmetric laminates, while laminates with nonuniform temperature distribution exhibit high critical load carrying capacity [110].…”

Section: Classificationmentioning

confidence: 99%

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Fiber-Reinforced Polymer Composites: Manufacturing, Properties, and Applications

Pagar²,

et al. 2019

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Composites have been found to be the most promising and discerning material available in this century. Presently, composites reinforced with fibers of synthetic or natural materials are gaining more importance as demands for lightweight materials with high strength for specific applications are growing in the market. Fiber-reinforced polymer composite offers not only high strength to weight ratio, but also reveals exceptional properties such as high durability; stiffness; damping property; flexural strength; and resistance to corrosion, wear, impact, and fire. These wide ranges of diverse features have led composite materials to find applications in mechanical, construction, aerospace, automobile, biomedical, marine, and many other manufacturing industries. Performance of composite materials predominantly depends on their constituent elements and manufacturing techniques, therefore, functional properties of various fibers available worldwide, their classifications, and the manufacturing techniques used to fabricate the composite materials need to be studied in order to figure out the optimized characteristic of the material for the desired application. An overview of a diverse range of fibers, their properties, functionality, classification, and various fiber composite manufacturing techniques is presented to discover the optimized fiber-reinforced composite material for significant applications. Their exceptional performance in the numerous fields of applications have made fiber-reinforced composite materials a promising alternative over solitary metals or alloys.

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Section: Classificationmentioning

confidence: 99%

Section: Classificationmentioning

confidence: 99%

Fiber-Reinforced Polymer Composites: Manufacturing, Properties, and Applications

Pagar²,

et al. 2019

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“…Researchers have conducted numerous experiments and numerical simulations to determine carbon fiber composites' mechanical response and damage behavior under LVI over the past several decades. In these studies, external factors such as the shape of the impactor, 11,12 mass, [13][14][15] inclination angle, 16 number of impacts, 17,18 location, 19,20 angle of impact, 21 temperature and humidity, 22,23 and boundary conditions [24][25][26] were discussed. Internal factors including laminate thickness, 27 fabric architecture, 28,29 type of fiber, [30][31][32] matrix, 33 loads, 34 stacking sequence, 35,36 interfaces, 37,38 and content of nanoclay particles 39,40 were also examined.…”

Section: Introductionmentioning

confidence: 99%

Research on low‐velocity impact resistance of carbon fiber composite laminates

Hou,

Aymerich,

Feng

2024

Polymer Composites

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This research conducts a comprehensive experimental and numerical analysis of carbon fiber composite laminates under low‐velocity impact conditions. Split Hopkinson Pressure Bar (SHPB) was employed to conduct impact testing on laminates with two layup sequences ( and ) under impacts ranging from 2 to 6 J. For assessing damage in laminates, a comprehensive progressive damage model and a simplified model were developed. The primary distinction between these models lies in the fact that the former incorporates the strengthening effect of compression on the delamination behavior, while the latter does not. Both models produce a good agreement with experimental results in terms of force–time, force–displacement curves, and absorbed energies. However, notable differences were noted in the predicted internal damage; the simplified model was underpredicted in terms of damage size and distribution compared to the comprehensive progressive damage model.Highlights Impact tests were conducted on and composites. In order to simulate damage caused by impacts in laminates, an energy‐based damage model was created, and cohesive elements were utilized to model interlaminar delamination. The strengthening effect of compression was explored. Distinct damage criteria were established for two cases. Damage detection of composites by x‐rays.

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Polymeric Nano-composite Membranes for Waste Water Treatment

Jakka

Sengupta

2023

Membranes for Water Treatment and Remediation

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Thermoelastic Stability Behavior of Curvilinear Fiber‐Reinforced Composite Laminates With Different Boundary Conditions

Cited by 6 publications

References 57 publications

Fiber-Reinforced Polymer Composites: Manufacturing, Properties, and Applications

Fiber-Reinforced Polymer Composites: Manufacturing, Properties, and Applications

Research on low‐velocity impact resistance of carbon fiber composite laminates

Polymeric Nano-composite Membranes for Waste Water Treatment

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