Sliding Wear of Conventional and Suspension Sprayed Nanocomposite WC-Co Coatings: An Invited Review

Ahmed, Rehan; Ali, Omar M.; Berndt, C. C.; Fardan, Ahmed

doi:10.1007/s11666-021-01185-z

Cited by 49 publications

(29 citation statements)

References 149 publications

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“…Figure 2 shows some of the coating particle temperatures and velocity ranges achievable by thermal spray processes. [11] The particle velocity which can be achieved during the thermal spray process (Figure 2) ranges from %20 to %1050 m s À1 , which influences the mechanical, thermal, and EM properties due to the extent of the 1) designed phase transformation, for example, ratio of amorphous-tocrystalline phase for hydroxyapatite (Ca 5 (PO 4 ) 3 (OH)) coatings for biomedical applications [12,13] and controlled degree of eta phase (i.e., carbon-deficient form of WC that results in a harder or brittle cemented carbide) formation for sliding wear applications of WC-Co coatings, [9] etc., and 2) control of porosity during deposition. [14] Complex feedstock materials such as BaCoTiFe 10 O 9 , SrFe 12 O 9 , and hydroxyapatite [12,15,16] can be thermally sprayed using the correct powder chemistry, coating process, and coating process parameters.…”

Section: Thermal Spray Coatings As a Manufacturing Route For Em Mater...mentioning

confidence: 99%

“…[166] While there are numerous examples where material has been doped with REEs using techniques other than thermal spray to improve EM wave propagation characteristics, such as chemical coprecipitation [167] or hydrothermal synthesis, [156] it is also possible that doping certain REEs during thermally sprayed coatings could also help improve the EM propagation wave characteristics of materials. In an example, Bartuli, Cipri and Valente (2008) [70] used a range of complex ceramic-based composite coatings, which included lanthanum/La REE (e.g., Cr 2 O 3 þ La 0.5 Sr 0.5 MnO 3 40wt%, Cr 2 O 3 þ Al 20 wt% þ La 0.5 Sr 0.5 MnO 3 20wt%) fabricated by air plasma spraying to evaluate their tailored EM properties (essentially as absorbers in the microwave range (8)(9)(10)(11)(12)). However, thermal spraying can make REEs prone to oxidation during processing and operation, and oxidation can lead to brittle coatings and deterioration of magnetic properties.…”

Section: Materials Doped With Rare Earth Elementsmentioning

confidence: 99%

“…This has enabled them to become an integral part of the aviation, transportation, power generation, chemical, and biomedical industry, which is currently worth 7.6 billion USD. [ 9 ] As will be seen later, the substrates in such thermally sprayed coatings varied from metals, alloys, glass, and ceramics to graphite; however, there is little or no evidence where lightweight polymeric substrates were considered for EM wave propagation applications. Though not a focus of current review, application of polymeric substrates (e.g., thermoplastics, which are excellent electrical and thermal insulators) is quite possible with some degree of limitations, as demonstrated by Bobzin, Wietheger, and Knoch (2021), [ 10 ] as such materials can well be combined with a high degree of design flexibility and economical mass production.…”

Section: Thermal Spray Coatings As a Manufacturing Route For Em Mater...mentioning

confidence: 99%

“…The lamella structure results in anisotropic mechanical properties, which are dependent upon the structure–property relationships, with major differences between the in‐plane and out‐of‐plane directions. [ 9 ]…”

Section: Thermal Spray Coatings As a Manufacturing Route For Em Mater...mentioning

confidence: 99%

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Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges

et al. 2022

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This review aims to consolidate scattered literature on thermally sprayed coatings with nonionizing electromagnetic (EM) wave absorption and shielding over specific wavelengths potentially useful in diverse applications (e.g., microwave to millimeter wave, solar selective, photocatalytic, interference shielding, thermal barrier‐heat/emissivity). Materials EM properties such as electric permittivity, magnetic permeability, electrical conductivity, and dielectric loss are critical due to which a material can respond to absorbed, reflected, transmitted, or may excite surface electromagnetic waves at frequencies typical of electromagnetic radiations. Thermal spraying is a standard industrial practice used for depositing coatings where the sprayed layer is formed by successive impact of fully or partially molten droplets/particles of a material exposed to high or moderate temperatures and velocities. However, as an emerging novel application of an existing thermal spray techniques, some special considerations are warranted for targeted development involving relevant characterization. Key potential research areas of development relating to material selection and coating fabrication strategies and their impact on existing practices in the field are identified. The study shows a research gap in the feedstock materials design and doping, and their complex selection covered by thermally sprayed coatings that can be critical to advancing applications exploiting their electromagnetic properties.

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Section: Thermal Spray Coatings As a Manufacturing Route For Em Mater...mentioning

confidence: 99%

Section: Materials Doped With Rare Earth Elementsmentioning

confidence: 99%

Section: Thermal Spray Coatings As a Manufacturing Route For Em Mater...mentioning

confidence: 99%

Section: Thermal Spray Coatings As a Manufacturing Route For Em Mater...mentioning

confidence: 99%

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Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges

et al. 2022

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“…However, despite the apparent dense microstructure of HVOF coatings, the electrochemical tests generally reveal that the as-sprayed metal coatings could not provide the substrate with effective and reliable protection from corrosion due to the existence of unbonded lamellar interfaces (Ref 25 , 26 ). Moreover, limited bonding also degrades the wear performance of hard alloy coatings since lamella spalling occurs easily through the propagation of sub-surface cracks along the lamellar interface at high stress conditions (Ref 24 , 27 ), especially as the coatings are subjected to dynamic loading (such as cavitation erosion) (Ref 28 ). Hiraga et al reported that compared with vacuum plasma-sprayed NiTi coating the laser remelting treatment leading to the formation of bulk-like NiTi presented the enhanced cavitation erosion resistance by a factor of magnitude from one order to over two orders (Ref 29 , 30 ).…”

Section: Introductionmentioning

confidence: 99%

Recent Research Advances in Plasma Spraying of Bulk-Like Dense Metal Coatings with Metallurgically Bonded Lamellae

Luo

Dong

et al. 2022

J Therm Spray Tech

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Although thermal spray metallic coatings have been widely used for materials protection from wear, corrosion and oxidation, its porous feature limits the full utilization of materials potential. Moreover, the oxidation inherent to thermal spraying in the ambient atmosphere is detrimental to interlamellar bonding formation, which further degrades the performance of thermal spray metal coatings. How to tape out the full potential of spray materials in the form of the coating is a still great challenge to thermal spray coating technology. Facing such challenge, recent efforts have been made to deposit dense metallic coatings with sufficiently bonded lamellae by oxide-free molten droplets through atmospheric plasma spraying. In this paper, the strategies for depositing bulk-like metal coatings will be reviewed. The formation of the bulk-like coating through post-spray treatments is briefly reviewed including post-spray heat treatment and laser remelting following the brief introduction to the features of thermal spray metallic coatings. The effect of the substrate preheating temperature on the splat formation and subsequently the adhesion formation was examined to reveal the dominant limitation of resultant oxide scale. Then, the role of the deposition temperature on the formation of bulk-like metal deposits with neglecting the effect of oxidation during spraying by vacuum plasma spraying practices is shortly presented. The recent progress on the new strategies to develop spread-fusing bonding mechanism and in-situ in-flight deoxidizing mechanism through developing ultra-hot metallic droplets will be introduced. The thermodynamics and kinetics requirements for the in-situ in-flight deoxidizing through deoxidizer elements adding to alloy spray powders for achieving oxide-free molten droplets in the ambient atmosphere are examined. The conditions to develop the spread-fusing mechanism during the spreading of impacting molten metal droplet for metallurgical bonding are presented. It is obvious from this review paper that the realization of two mechanisms depends on both the spray materials design and heating control of in-flight particles. Through the generation of ultra-hot droplets by plasma spraying to achieve oxide-free molten droplets, strategically it will be possible to deposit bulk-like dense metallic coating through spread-fusing of splat surfaces with limited post-spray oxidation. Such strategies will tape out the full potential of coating materials and open up the new application fields for plasma spraying.

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Application of Thermal Spray Coatings in Electrolysers for Hydrogen Production: Advances, Challenges, and Opportunities

et al. 2022

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Thermal spray coatings have the advantage of providing thick and functional coatings from a range of engineering materials. The associated coating processes provide good control of coating thickness, morphology, microstructure, pore size and porosity, and residual strain in the coatings through selection of suitable process parameters for any coating material of interest. This review consolidates scarce literature on thermally sprayed components which are critical and vital constituents (e.g., catalysts (anode/cathode), solid electrolyte, and transport layer, including corrosion-prone parts such as bipolar plates) of the water splitting electrolysis process for hydrogen production. The research shows that there is a gap in thermally sprayed feedstock material selection strategy as well as in addressing modelling needs that can be crucial to advancing applications exploiting their catalytic and corrosion-resistant properties to split water for hydrogen production. Due to readily scalable production enabled by thermal spray techniques, this manufacturing route bears potential to dominate the sustainable electrolyser technologies in the future. While the well-established thermal spray coating variants may have certain limitations in the manner they are currently practiced, deployment of both conventional and novel thermal spray approaches (suspension, solution, hybrid) is clearly promising for targeted development of electrolysers.

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Sliding Wear of Conventional and Suspension Sprayed Nanocomposite WC-Co Coatings: An Invited Review

Cited by 49 publications

References 149 publications

Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges

Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges

Recent Research Advances in Plasma Spraying of Bulk-Like Dense Metal Coatings with Metallurgically Bonded Lamellae

Application of Thermal Spray Coatings in Electrolysers for Hydrogen Production: Advances, Challenges, and Opportunities

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