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Plasma spraying. --- Spraying, Plasma --- Metal coating --- Plasma jets --- Protective coatings
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Recently, plasma spray has been received a large number of attentions for various type of applications due to the nature of the plasma plume and deposition structure. The plasma gas generated by the arc, consists of free electrons, ionized atoms, some neutral atoms, and undissociated diatomic molecules. The temperature of the core of the plasma jet may exceed up to 30,000 K. Gas velocity in the plasma spray torch can be varied from subsonic to supersonic using converging-diverging nozzles. Heat transfer in the plasma jet is primarily the result of the recombination of the ions and re-association of atoms in diatomic gases on the powder surfaces and absorption of radiation. Taking advantages of the plasma plume atmosphere, plasma spray can be used for surface modification and treatment, especially for activation of polymer surfaces. I addition, plasma spray can be used to deposit nanostructures as well as advanced coating structures for new applications in wear and corrosion resistance. Some state-of-the-art studies of advanced applications of plasma spraying such as nanostructure coatings, surface modifications, biomaterial deposition, and anti wear and corrosion coatings are presented in this book.
Plasma spraying. --- Spraying, Plasma --- Metal coating --- Plasma jets --- Protective coatings --- Biomedical engineering
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Metal spraying --- Plasma spraying --- Métallisation au pistolet. --- Projection au plasma. --- Spraying, Plasma --- Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Metal coating --- Plasma jets --- Protective coatings --- Surface hardening
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Plasma spraying --- Metal spraying --- Pulvérisation de plasma --- Métallisation au pistolet --- Congresses --- Congrès --- -Metal spraying --- -Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Metal coating --- Surface hardening --- Spraying, Plasma --- Plasma jets --- Protective coatings --- -Congresses --- Pulvérisation de plasma --- Métallisation au pistolet --- Congrès
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Metal spraying --- Plasma spraying --- Métallisation au pistolet --- Pulvérisation de plasma --- Congresses --- Congrès --- -Plasma spraying --- -Spraying, Plasma --- Metal coating --- Plasma jets --- Protective coatings --- Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Surface hardening --- -Congresses --- Métallisation au pistolet --- Pulvérisation de plasma --- Congrès
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Metal spraying --- Plasma spraying --- Métallisation au pistolet --- Pulvérisation de plasma --- Congresses --- Congrès --- -Plasma spraying --- -Spraying, Plasma --- Metal coating --- Plasma jets --- Protective coatings --- Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Surface hardening --- -Congresses --- Métallisation au pistolet --- Pulvérisation de plasma --- Congrès
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Metal spraying --- Plasma spraying --- Métallisation au pistolet --- Pulvérisation de plasma --- Congresses --- Congrès --- -Plasma spraying --- -Spraying, Plasma --- Metal coating --- Plasma jets --- Protective coatings --- Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Surface hardening --- -Congresses --- Métallisation au pistolet --- Pulvérisation de plasma --- Congrès
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This Brief describes the influence of the different organic chelating agents on the topography, physical properties and phases of SPPS-deposited spinel ferrite splats. The author describes how by using the SPPS process, the coating is produced directly from a solution precursor and how all physical and chemical reactions such as evaporation, decomposition, crystallization and coating formation occur in a single step. The author details not only the innovative approach to liquid feeding, but also focuses on its effects on the spinel ferrite system. The results of experimentation as well as detailed explanations of the experiments are included.
Plasma spraying. --- Metal coating --- Ferrites (Magnetic materials) --- Magnetic properties. --- Ferrates --- Gyrators --- Iron compounds --- Magnetic materials --- Coating, Metal --- Metallic coating --- Coatings --- Metallic composites --- Metallic films --- Metals --- Protective coatings --- Refractory coating --- Surfaces (Technology) --- Plating --- Spraying, Plasma --- Plasma jets --- Chemistry, inorganic. --- Chemical engineering. --- Tribology, Corrosion and Coatings. --- Industrial Chemistry/Chemical Engineering. --- Plasma Physics. --- Chemistry, Industrial --- Engineering, Chemical --- Industrial chemistry --- Engineering --- Chemistry, Technical --- Metallurgy --- Inorganic chemistry --- Chemistry --- Inorganic compounds --- Tribology. --- Corrosion and anti-corrosives. --- Coatings. --- Plasma (Ionized gases). --- Gaseous discharge --- Gaseous plasma --- Magnetoplasma --- Ionized gases --- Friction --- Anti-corrosive paint --- Atmospheric corrosion --- Metal corrosion --- Rust --- Rustless coatings --- Chemical inhibitors --- Fouling --- Materials --- Weathering --- Paint --- Waterproofing --- Surface coatings --- Coating processes --- Thin films --- Corrosion --- Deterioration --- Surfaces
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This book provides readers with the fundamentals necessary for understanding thermal spray technology. Coverage includes in-depth discussions of various thermal spray processes, feedstock materials, particle-jet interactions, and associated yet very critical topics: diagnostics, current and emerging applications, surface science, and pre and post-treatment. This book will serve as an invaluable resource as a textbook for graduate courses in the field and as an exhaustive reference for professionals involved in thermal spray technology. This book also: Provides a complete overview of the relationship between process parameters and coating properties Covers both the qualitative material of the fundamental physics principles involved, and at the same time provides sufficient quantitative information for prediction of effects of process parameter changes Includes the latest thermal spray technology developments, including new d.c. plasma and wire arc spray torch developments, r.f. induction plasma spraying, combustion based spray technologies and cold spray, particle-jet interactions and process diagnostics and on-line control methods as well as a review of current and in-development industrial applications.
Cavitation. --- Chemistry, inorganic. --- Hydraulic engineering. --- Materials. --- Metal spraying. --- Protective coatings. --- Structural control (Engineering). --- Chemical & Materials Engineering --- Mechanical Engineering --- Engineering & Applied Sciences --- Materials Science --- Mechanical Engineering - General --- Metal spraying --- Plasma spraying --- Metal coating --- Industrial applications. --- Spraying, Plasma --- Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Coating, Metal --- Metallic coating --- Materials science. --- Fluid mechanics. --- Industrial engineering. --- Tribology. --- Corrosion and anti-corrosives. --- Coatings. --- Materials Science. --- Tribology, Corrosion and Coatings. --- Engineering Fluid Dynamics. --- Operating Procedures, Materials Treatment. --- Coatings --- Metallic composites --- Metallic films --- Metals --- Protective coatings --- Refractory coating --- Surfaces (Technology) --- Plating --- Plasma jets --- Surface hardening --- Manufactures. --- Manufacturing, Machines, Tools, Processes. --- Manufactured goods --- Manufactured products --- Products --- Products, Manufactured --- Commercial products --- Manufacturing industries --- Engineering, Hydraulic --- Engineering --- Fluid mechanics --- Hydraulics --- Shore protection --- Inorganic chemistry --- Chemistry --- Inorganic compounds --- Hydromechanics --- Continuum mechanics --- Surface coatings --- Materials --- Coating processes --- Thin films --- Anti-corrosive paint --- Atmospheric corrosion --- Metal corrosion --- Rust --- Rustless coatings --- Chemical inhibitors --- Chemistry, Technical --- Fouling --- Weathering --- Paint --- Waterproofing --- Friction --- Corrosion --- Deterioration --- Surfaces
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This book presents the principles of plasma and heat spraying. It introduces plasma jet and the formation of plasma sprayed coatings. It explains the adhesion process and also presents standard methods for measurement according to DIN forms. Some case studies are presented for illustration.
Materials science. --- Industrial engineering. --- Tribology. --- Corrosion and anti-corrosives. --- Coatings. --- Materials --- Thin films. --- Materials Science. --- Surfaces and Interfaces, Thin Films. --- Tribology, Corrosion and Coatings. --- Operating Procedures, Materials Treatment. --- Surfaces. --- Plasma spraying. --- Metal spraying. --- Spraying, Metal --- Spraying, Thermal --- Thermal spraying --- Spraying, Plasma --- Metal coating --- Surface hardening --- Plasma jets --- Protective coatings --- Surfaces (Physics). --- Chemistry, inorganic. --- Manufactures. --- Manufacturing, Machines, Tools, Processes. --- Manufactured goods --- Manufactured products --- Products --- Products, Manufactured --- Commercial products --- Manufacturing industries --- Inorganic chemistry --- Chemistry --- Inorganic compounds --- Physics --- Surface chemistry --- Surfaces (Technology) --- Materials—Surfaces. --- Surface coatings --- Coating processes --- Thin films --- Anti-corrosive paint --- Atmospheric corrosion --- Metal corrosion --- Metals --- Rust --- Rustless coatings --- Chemical inhibitors --- Chemistry, Technical --- Fouling --- Weathering --- Paint --- Waterproofing --- Friction --- Films, Thin --- Solid film --- Solid state electronics --- Solids --- Coatings --- Thick films --- Corrosion --- Deterioration --- Surfaces --- Surfaces (Technology). --- Surfaces, Interfaces and Thin Film. --- Corrosion. --- Machines, Tools, Processes. --- Surface phenomena --- Surfaces (Physics) --- Tribology
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