Solid particle erosion of composite materials: A critical review

Miyazaki, Noriyuki

doi:10.1177/0021998315617818

Cited by 50 publications

(26 citation statements)

References 194 publications

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“…Erosive wear occurs due to impact of high-velocity liquid or particles on solid surface. 24 Investigations into erosive behaviour of FRP materials have increased in recent years due to the fact that a wide variety of machinery components undergo erosion. For example, impact of dust particles on FRP gas turbine blades, impact of slurry on pump impeller blades, 25,26 etc.…”

Section: Tribological Performance Of Carbon and Glass Fibre-reinforcementioning

confidence: 99%

Tribological behaviour of fibre-reinforced thermoset polymer composites: A review

Kumar

Singh

2020

Proceedings of the Institution of Mechanical Engineers, Part L:

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Application of fibre-reinforced polymer composites has increased over the last two decades as compared to conventional materials. This improvement in the application of fibre-reinforced polymer composites is attributed to their unique material properties, such as high strength and stiffness-to-weight ratio, specific modulus and internal vibration damping. However, in most of the industrial applications, composite materials encounter tribological complications. Economic indicators and market dynamics suggested that the market for composite materials is booming and the dominant materials are carbon fibres, glass fibres and thermoset polymer (polyester resin) in resin segments. That is why tribological characteristics are crucial in designing carbon and glass-based fibre-reinforced polymer components. Owing to this importance, the study of tribological behaviour of fibre-reinforced polymer composite materials has expanded significantly. The present study has made an attempt to review the fundamental tribological applications and critical aspects of fibre-reinforced polymers, based on research work, which has been carried out over the past couple of decades. This work has primarily focused on the fibre-reinforced polymer composites, based on carbon and glass fibres with thermosets as the matrix material for probing into tribological behaviours. In the process, the focus has largely been on the most commonly occurring erosive and abrasive mode of wear process.

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Section: Tribological Performance Of Carbon and Glass Fibre-reinforcementioning

confidence: 99%

Tribological behaviour of fibre-reinforced thermoset polymer composites: A review

Kumar

Singh

2020

Proceedings of the Institution of Mechanical Engineers, Part L:

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“…Mathias et al [30] found that composite material was eroded easily than matrix polymer. Miyazaki [31] reviewed the papers of solid particle erosion and mentioned that the maximum erosion angle of composite material was larger than that of corresponding matrix. Ameli et al [32] reported that the addition of CF could improve the EMI shielding property of composites.…”

Section: Introductionmentioning

confidence: 99%

Solid particle erosion resistance and electromagnetic shielding performance of carbon fiber reinforced polycarbonate composites

Fang

Zhang

et al. 2020

Mater. Res. Express

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Thermoplastic polycarbonate (PC) has attracted tremendous attention due to its superior recyclability and environmental friendliness compared with thermosetting resins. In this work, thermoplastic polycarbonate was used as the matrix material and the solid particle erosion resistance of carbon fiber reinforced polycarbonate (CF/PC) composites, as well as the influence of solid particle erosion on the mechanical properties of composites were studied systematically. The results indicated that the maximum erosion angle for CF/PC is 30°, and samples are easier to be eroded when impacted in parallel direction to CF than the vertical. In addition, after 2 min solid particle erosion, the tensile strength and the maximum load decreased by 11.9% and 11.8% respectively, and flexural properties of all samples declined (flexural modulus by 49%, flexural strength and maximum load by 14.6%, flexural strain by 11.9%). Finally, an excellent EMI shielding effectiveness (SE) of around 40 dB over 12 GHz to 18 GHz was achieved for composites. Due to the destruction of CF/PC composite structure and the reduction of its thickness, its EMI shielding effectiveness was greatly decreased to 28 dB after sand erosion.

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“…[ 1,2 ] However, the relatively low erosion resistance of polymers has been problematic, thus motivating researchers to seek effective solutions to improve it. [ 3,4 ] The use of hard and relatively brittle ceramic particles to reinforce polymeric composites is common in industry, mostly to enhance their mechanical properties such as elastic modulus and tensile strength. [ 5 ] However, in most cases, because of the relatively low fracture toughness of the ceramic particles, the erosion resistance of the resulting composite has been found to be lower than the polymer it was meant to reinforce.…”

Section: Introductionmentioning

confidence: 99%

Numerical and experimental investigation of the erosion of zirconia particulate‐reinforced epoxy matrix composites by angular silicon carbide particles

et al. 2020

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An smooth particle hydrodynamics/finite element (SPH/FEM) model was developed to simulate the erosion of zirconia particle‐reinforced epoxy composites, due to the overlapping impacts of angular particles at both perpendicular and oblique incidences. For each composite target, multiple sub‐volumes, each having their own random reinforcement distribution, were modeled. The reinforcements were assumed as noneroding and nondeforming and were distributed in the modeled sub‐volumes according to the random distributions measured in the actual samples. Erosion tests were performed to verify the numerical model, and it was found that the erosion rates of the zirconia‐reinforced composites were in all cases significantly lower than the neat epoxy. The experimentally‐observed erosion mechanisms were successfully simulated by the model, and the predicted erosion rates matched the measured ones to within 2% to 11%. It is anticipated that similar models can be used to predict erosion of other particulate composite systems whose reinforcement erosion and fracture is negligible compared to the matrix erosion.

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Solid particle erosion of composite materials: A critical review

Cited by 50 publications

References 194 publications

Tribological behaviour of fibre-reinforced thermoset polymer composites: A review

Tribological behaviour of fibre-reinforced thermoset polymer composites: A review

Solid particle erosion resistance and electromagnetic shielding performance of carbon fiber reinforced polycarbonate composites

Numerical and experimental investigation of the erosion of zirconia particulate‐reinforced epoxy matrix composites by angular silicon carbide particles

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