Effects of recovered brown alumina filler loading on mechanical, hygrothermal and thermal properties of glass fiber–reinforced epoxy polymer composite

Sabarinathan, P.; Annamalai, V.E.; Rajkumar, K.; Vishal, K.

doi:10.1177/09673911211046780

Cited by 13 publications

(2 citation statements)

References 36 publications

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“…Marble powder dust addition to the polymer composites, improved the shore hardness, impact and compressive strengths and marginal drop in the tensile and flexural properties [13]. Inclusion of 20% of recovered alumina to polymer composite resulted in maximum hardness and flexural strength [33]. Many ceramic fillers like Al 2 O 3 , TiO 2 , MgO, SiO 2 are added to the polymer composite and its behavior was studied and found that, the additives enhanced the flexural properties, impact strength.…”

Section: Results and Findings Discussionmentioning

confidence: 99%

Analysis on the impact of recycled ceramic waste, fiber format, and manufacturing techniques on polymer composite properties

Balan¹,

Prakash²,

Raj³

et al. 2022

Eng. Res. Express

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Dumping of construction waste is a growing issue in current situation and recycling and reusing are the suitable solutions for solving it. This effort aims to recycle and reuse of ceramic construction waste. This work examines the effects of inclusion of waste tile powder, change in the glass fiber form which was used as a reinforcement, and method of manufacturing method the polymer composite on the properties of the composite. Normal glass-reinforced polymer composites have good tensile, flexural, and toughness properties. The three forms of glass fibers used for the study includes, chopped fiber mat, glass fiber mesh, and woven glass fiber. Fillers are added to improve hardness and tribology related attributes. Composite fabrication was carried out by conventional hand layup, room temperature compression molding, and hot compression molding process. The goal is to harden the composite without reducing the tensile strength of the composite. ASTM D3039, ASTM D2240, and ASTM D570-98 procedures were adapted for measuring tensile, hardness and water intake properties respectively. Characterization was done through SEM image analysis. A result of 160.21 MPa tensile strength, Shore D hardness value of 96.7, and water absorption of 0.71 percent after 24 hours of testing was recorded. Adding waste tile powder to the polymer composite increases its hardness and reduces surface defects without affecting tensile properties. Fiber form and manufacturing method also affect the output to some extent. The effect of water absorption on the hardness property of the composite was checked and found to be negligible which makes it durable and reliable to be used in moist environments. This composite can be used in automotive parts, moist environment, window and door frames, and in electrical panels.

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Section: Results and Findings Discussionmentioning

confidence: 99%

Analysis on the impact of recycled ceramic waste, fiber format, and manufacturing techniques on polymer composite properties

Balan¹,

Prakash²,

Raj³

et al. 2022

Eng. Res. Express

View full text Add to dashboard Cite

show abstract

“…Reinforcement of fiber particulate can improve the composite's thermal stability, crystalline index, and mechanical performance (Azman et al, 2021). Various papers reported that particulate reinforcement could marginally improve compressive strength (Vinayagam, 2022), flexural strength (Sabarinathan et al, 2021), impact strength (Benin et al, 2022), ductility (Xiong et al, 2021), tensile strength (Cheang and Khor, 2003), wear (Aly et al, 2012), toughness (Bhagyashekar and Rao, 2010), scratch resistance (Ng et al, 2001), coefficient of thermal expansion (Sun et al, 2021;Xu et al, 2001), thermal conductivity (Bahl, 2020;Bae et al, 2000;Luyt et al, 2006), etc. Sawyer et al (2003 reported the beneficial use of glass particulate fiber to improve the corrosion and wear behavior of Polytetrafluoroethylene composite.…”

Section: Particulate Fiber Reinforced Composite (Pfrc)mentioning

confidence: 99%

Carbon Black: A Thermally Conductive Reinforcement for Epoxy Based Composite

SAHOO,

Patel,

Nanda

2023

Preprint

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Heat conduction plays a vital role in the performance and durability of any component. A wide range of applications is available which demand a good heat conduction ability. The property used to understand the heat conduction behavior in a solid is called effective thermal conductivity (Keff). It is recommended to reinforce an adequate amount of filler material in the matrix to increase the Keff of the composite. The current study used carbon black (CB) particulates, a by-product of waste tyre pyrolysis, as the reinforcing agent in the epoxy resin. The composites are prepared by solution casting method with different volume % of filler. To study the thermal behavior of samples, effective thermal conductivity, glass transition temperature (Tg), and co-efficient thermal expansion (CTE) are measured as a function of vol. % of filler. After plotting the experimental result, it is noticed that the Keff and Tg are increased, and CTE is decreased with an increase in vol. % of CB. The percolation threshold is also calculated from Keff vs. vol. % curve. Various mathematical models are incorporated to verify the experimental results of effective thermal conductivity. A finite element method (FEM) based numerical model is also developed to study the thermal conductivity behavior of composites. ANSYS MECHANICIAL APDL is used for the FEM analysis. The FEM results showed a marginal variation from experimental data at 0.9928 vol. % of CB. The reason behind this is the formation of voids during sample making, the effect of which is not taken in FEM.

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Hygrothermal aging and recycling effects on mechanical and thermal properties of recyclable thermoplastic glass fiber composites

Kumar,

Elen,

Sushmita

et al. 2024

Polymer Composites

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Glass fiber‐reinforced polymer composites are widely used in marine applications, including renewable energy devices and submarines, due to their strength‐to‐weight ratios and corrosion resistance. As sustainability becomes more important, recyclable thermoplastic composites are gaining attention in marine energy applications. These materials face harsh conditions such as high chloride water, UV radiation, pressurization, and thermal cycling, which can affect their durability and recyclability. This study examines the impact of hygrothermal aging on the recyclability of an Elium glass fiber (GF) composite. Samples were mechanically ground for recycling, and mechanical and thermal properties were compared between aged and unaged samples. After seawater aging, the tensile strength and modulus of the unaged composite dropped by 25% and 13% respectively, due to water ingress along the fiber‐matrix interface. The recycled composite showed reduced flexural strength as the long fiber composite was converted into short fibers during the process. Differential scanning calorimetry (DSC) revealed no change in glass transition temperature after aging. Weight loss (25%) was attributed to the thermal stability of the glass fibers. Dynamic mechanical analysis (DMA) showed that the storage modulus increased with aging, and fracture analysis confirmed a mixed mode of failure for aged composites.Highlights Hygrothermal aging lowers mechanical performance of Elium® GF composites. Failure mechanism tends to be matrix cracking and interface bonding. Glass transition temperature is not reduced by hygrothermal aging. Fractured composite was successfully recycled via thermoforming. Flexural strength of the recycled composite is lower.

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Effects of recovered brown alumina filler loading on mechanical, hygrothermal and thermal properties of glass fiber–reinforced epoxy polymer composite

Cited by 13 publications

References 36 publications

Analysis on the impact of recycled ceramic waste, fiber format, and manufacturing techniques on polymer composite properties

Analysis on the impact of recycled ceramic waste, fiber format, and manufacturing techniques on polymer composite properties

Carbon Black: A Thermally Conductive Reinforcement for Epoxy Based Composite

Hygrothermal aging and recycling effects on mechanical and thermal properties of recyclable thermoplastic glass fiber composites

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