Insights on the bearing response of glass fiber‐reinforced stainless steel laminates: Investigating the influence of natural fiber and specimen geometry

Vasumathi, M.; Begum, S. Rashia; Gokul Nath, P.; Kavimani, V.; Romanovski, Valentin; Salah, Bashir

doi:10.1002/pc.28455

Polymer Composites

2024

DOI: 10.1002/pc.28455

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Insights on the bearing response of glass fiber‐reinforced stainless steel laminates: Investigating the influence of natural fiber and specimen geometry

M. Vasumathi,

S. Rashia Begum,

P. Gokul Nath

et al.

Abstract: This study delves into the bearing response of two types of Fiber Metal Epoxy Laminates (FMLs): Glass Fiber/Stainless Steel laminates and Glass Fiber/Jute/Stainless Steel laminates, where a portion of glass fiber is replaced with jute. The primary focus is to assess the impact of introducing natural fiber (jute) into FML on its pin‐type bearing performance, considering various edge‐to‐hole ratios (e/D), width‐to‐hole ratios (W/D), and stacking orders. The study aims to understand how these parameters influence… Show more

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Cited by 3 publications

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Flexural and low‐velocity behavior of GFPP/DP980 honeycomb sandwich structure inspired by fiber metal laminates

Lin,

Xiao,

et al. 2024

Polymer Composites

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With the rapid development of electric vehicles, a hybrid composite structure has been designed for the battery pack bottom guard to enhance impact resistance and reduce weight. The glass fiber‐reinforced polypropylene (GFPP)/DP980 honeycomb sandwich structure consists of GFPP panels with a polypropylene honeycomb core. DP980 advanced high‐strength steel plate is encapsulated within the structure, inspired by fiber metal laminates. A lightweight and high‐strength sandwich composite lay‐up solution was determined through equivalent bending stiffness theory, finite element simulation and experiment. An asymmetric sandwich structure with the steel plate on the impacted side enhanced flexural strength and ductility, demonstrating different failure sequences and a higher bending strength of 77.64 MPa compared to 50.18 MPa when the steel plate was on the unimpacted side. As impact energy increased from 100 to 200 J, the sandwich structure showed higher peak impact load, deeper craters, and increased bulge height, with significant delamination up to 175 J, while gravel impact tests revealed minimal flexural strength reduction (4.92%) even after repeated impacts. This study confirms that the use of thermoplastic sandwich structures is a viable and promising option for crash safety and the lightweight design of battery pack bottom guards.Highlights The thermoplastic honeycomb sandwich structure is polypropylene‐based. The use of advanced high strength steel is inspired by fiber metal laminates. Both thickness and surface density are considered in the structural design. The steel plate placed on the impacted side improves the flexural behavior. The sandwich structure has excellent impact resistance and lightweight level.

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Flexural and low‐velocity behavior of GFPP/DP980 honeycomb sandwich structure inspired by fiber metal laminates

Lin,

Xiao,

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

show abstract

Comparison of glass/epoxy and hemp/epoxy honeycomb core with MWCNT filler on its comprehensive performance in buckling, static and dynamic behaviors of sandwich composite plates

Raju,

Chandrasekaran

2024

Polym. Bull.

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Maximizing strength and durability in wood concrete (arbolite) via innovative additive control and consumption

Yagubkin,

Shabanov,

Niyakovskii

et al. 2024

Biomass Conv. Bioref.

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A new approach for assessing the effectiveness and determining the consumption of additives to regulate the structural and mechanical characteristics of wood concrete is proposed, which allows rapid assessment in a short time and reduces the consumption of materials. The period is reduced from 28 to 1 day, and the sample sizes are reduced from 150 × 150 × 150 to 20 × 20 × 20 mm compared to those of the standard method. The results obtained are comparable using both methods within an error of up to 7%. The thermal conductivity of wood concrete with the addition of potassium sulfate was 20.8% less than that with the addition of calcium chloride. This reduction will reduce wall thickness, material consumption, and cost by 20.8%. In this regard, potassium sulfate, which does not form crystalline hydrates and makes it possible to obtain a material with lower thermal conductivity than other additives, all other things being equal, has a new advantage for wood concrete. In addition, potassium sulfate reduces the risk of corrosion of cement stone because one of the main causes of corrosion is crystalline hydrates. Reducing the risk of corrosion will increase the durability of the material.

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Insights on the bearing response of glass fiber‐reinforced stainless steel laminates: Investigating the influence of natural fiber and specimen geometry

Cited by 3 publications

References 36 publications

Flexural and low‐velocity behavior of GFPP/DP980 honeycomb sandwich structure inspired by fiber metal laminates

Flexural and low‐velocity behavior of GFPP/DP980 honeycomb sandwich structure inspired by fiber metal laminates

Comparison of glass/epoxy and hemp/epoxy honeycomb core with MWCNT filler on its comprehensive performance in buckling, static and dynamic behaviors of sandwich composite plates

Maximizing strength and durability in wood concrete (arbolite) via innovative additive control and consumption

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