Prediction of impact behaviour for natural fiber-reinforced composites using the finite element method

Parvathaneni, Phani Prasanthi; Madhav, V. V. Venu; Chaitanya, Chadalavada Sri; Spandana, Vallabhaneni Veda; Saxena, Kuldeep K.; Garg, Sahil; Zeleke, Migbar Assefa

doi:10.1177/26349833221145016

Cited by 2 publications

(1 citation statement)

References 27 publications

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“…The investigation into the mechanical properties of flax/ramie hybrid epoxy composites with variations in stacking sequence suggests potential applications in automotive settings [11]. Considerable outcomes have also been achieved in the field of natural fiber-reinforced composites using numerical methods [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Exploring the influence of stacking sequence on the mechanical properties of flax-ramie bi-quadratic layered hybrid epoxy composites

Tarun,

Ganesan,

Sundar

2024

Mater. Res. Express

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Over the past two decades, there has been a remarkable surge in the utilization of composites, with fiber-reinforced polymer composites gaining significant traction owing to their commendable structural performance. Concurrently, extensive research has been conducted to assess the behavior of composite materials, focusing on various parameters such as fiber type, lamination order, matrix type, and the inclusion of filler materials. In this study, we investigated the mechanical properties of flax (F)/ramie (R) epoxy hybrid composites, specifically exploring the effects of different lamination sequences. Four distinct lamination sequences were chosen: FFRR, FRFR, FRRF, and RFFR. The composites were fabricated using compression molding techniques, adhering to ASTM standards for the evaluation of mechanical properties including tensile strength, flexural strength, impact strength, and interlaminar shear strength. Among the laminate sequences studied, FRFR exhibited the lowest void content at 4.76%, while RFFR composites showed the highest void content at 16.67%. The most favorable results were observed with FRFR composites, boasting a tensile strength of 77.06 MPa, impact strength of 13.36 kJ m−2, and interlaminar shear strength of 8.13 MPa. Notably, the FFRR composite exhibited the highest flexural strength at 118.09 MPa. Additionally, scanning electron microscopy (SEM) analysis was conducted to investigate surface morphology and identify reasons for failure.

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Section: Introductionmentioning

confidence: 99%

Exploring the influence of stacking sequence on the mechanical properties of flax-ramie bi-quadratic layered hybrid epoxy composites

Tarun,

Ganesan,

Sundar

2024

Mater. Res. Express

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Moisture Induced Mechanical Characterization of Composite through Numerical Simulation

Nelson

2023

SAE Technical Paper Series

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<div class="section abstract"><div class="htmlview paragraph">Composite materials find extensive applications in numerous fields, including mechanical components, which are often subjected to varying climatic conditions. Due to the contrasting conditions, there is a difference in the external loadings, leading to the transfer of air, heat, and moisture between the environments. Here, the study is done to model the moisture-based diffusion in order to predict the output beforehand so that necessary precautions can be taken before it fails. The study primarily investigates the heat and moisture-based absorption behavior of composite materials. The Representative Volume Element (RVE) approach is chosen, which enables the simulation of the behavior of the composite at a microscale level, giving insights into the micromechanics and analyzing the material absorption behavior of moisture. The FEA approach for the same is carried out using the COMSOL Multiphysics software. The required RVE of the composite is modeled, and the effect of fiber volume fraction on the hygroscopic swelling, followed by the effect on its properties, is derived. Subsequently, the mechanical characterization of the material is performed. The composite model is run through a moisture-based environmental condition, as in the previous case to evaluate the effects of moisture on the strength of the composite material. The material exposed to the moisture environment showed water uptake. The increase in water uptake causes a decrease in the strength of the material compared to the material with no exposure to moisture. The study focuses on the relationship between the composite’s moisture content and its mechanical characteristics, which can be helpful for the responsible modeling of components in the required environment.</div></div>

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Prediction of impact behaviour for natural fiber-reinforced composites using the finite element method

Cited by 2 publications

References 27 publications

Exploring the influence of stacking sequence on the mechanical properties of flax-ramie bi-quadratic layered hybrid epoxy composites

Exploring the influence of stacking sequence on the mechanical properties of flax-ramie bi-quadratic layered hybrid epoxy composites

Moisture Induced Mechanical Characterization of Composite through Numerical Simulation

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