Your search keyword '"KeeHyun Kim"' showing total 6 results

1. Comparison of Oxidation and Microstructure of Warm-Sprayed and Cold-Sprayed Titanium Coatings

Author

Seiji Kuroda, Makoto Watanabe, KeeHyun Kim, Renzhong Huang, Hiroshi Katanoda, and Hirotaka Fukanuma

Subjects

Materials science, ion milling, oxidation, Scanning electron microscope, microstructure, Gas dynamic cold spray, chemistry.chemical_element, cold spraying, engineering.material, Coating, Materials Chemistry, Inert gas, Thermal spraying, Metallurgy, Condensed Matter Physics, Microstructure, Surfaces, Coatings and Films, Titanium powder, x-ray diffraction, chemistry, Chemical engineering, engineering, warm spraying, Titanium

Abstract

Thick titanium coatings were prepared by the warm spraying (WS) and cold spraying (CS) processes to investigate the oxidation and microstructure of the coating layers. Prior to the coating formations, the temperature and velocity of in-flight titanium powder particles were numerically calculated. Significant oxidation occurred in the WS process using higher gas temperature conditions with low nitrogen flow rate, which is mixed to the flame jet of a high velocity oxy-fuel (HVOF) spray gun in order to control the temperature of the propellant gas. Oxidation, however, decreased strikingly as the nitrogen flow rate increased. In the CS process using nitrogen or helium as a propellant gas, little oxidation was observed. Even when scanning electron microscopy or an x-ray diffraction method did not detect oxides in the coating layers produced by WS using a high nitrogen flow rate or by CS using helium, the inert gas fusion method revealed minor increases of oxygen content from 0.01 to 0.2 wt.%. Most of the cross-sections of the coating layers prepared by conventional mechanical polishing looked dense. However, the cross-sections prepared by an ion-milling method revealed the actual microstructures containing small pores and unbounded interfaces between deposited particles.

Published

2011

2. Microstructural Development and Deposition Behavior of Titanium Powder Particles in Warm Spraying Process: From Single Splat to Coating

Author

Makoto Watanabe, Seiji Kuroda, and KeeHyun Kim

Subjects

Materials science, Metallurgy, Gas dynamic cold spray, chemistry.chemical_element, engineering.material, Condensed Matter Physics, Electrostatic spray-assisted vapour deposition, Grain size, Surfaces, Coatings and Films, Titanium powder, chemistry, Coating, parasitic diseases, Materials Chemistry, engineering, Particle, Layer (electronics), Titanium

Abstract

Warm spraying has been developed by NIMS, in which powder particles are accelerated and simultaneously heated, and deposited onto a suitable substrate in thermally softened solid state. In this study, commercially available titanium powder was sprayed onto steel substrate by the spraying process. Microstructural developments and deposition behaviors from a deposited single particle to a thick coating layer were observed by high resolution electron microscopes. A single titanium particle sprayed onto the substrate was severely deformed and grain-refined mainly along the interfacial boundary of particle/substrate by the impact of the sprayed particle. A successive impact by another particle further deformed the previously deposited particle and induced additional grain refinement of the remaining part. In a thick coating layer, the severe deformation and grain refinement were also observed. The results have demonstrated the complex deposition behavior of sprayed particles in the warm spraying using thermally softened metallic powder particles.

Published

2010

3. Jetting-Out Phenomenon Associated with Bonding of Warm-Sprayed Titanium Particles onto Steel Substrate

Author

Makoto Watanabe, KeeHyun Kim, and Seiji Kuroda

Subjects

Materials science, Metallurgy, chemistry.chemical_element, Substrate (printing), equipment and supplies, Condensed Matter Physics, Microstructure, Grain size, Surfaces, Coatings and Films, Adiabatic shear band, Titanium powder, chemistry, Materials Chemistry, Dynamic recrystallization, Particle, Titanium

Abstract

Titanium powder particles accelerated and simultaneously heated by the supersonic gas flow were deposited onto steel substrate by the warm spraying process. The sprayed particles were heavily deformed and bonded to the substrate in solid state. Especially, all the deposited particles showed jetting-out of materials out of the particle-substrate interface triggered by the adiabatic shear instability known to occur under such shock impact conditions. High-magnified images showed that grain refinement occurred in the jetting-out region by dynamic recrystallization. Furthermore, the elemental analysis using the electron energy loss spectrum showed jetting-outs of the substrate as well as the particle. Numerical simulation based on the Johnson-Cook plastic deformation model showed that the jetting-out phenomenon commences about 10 ns after the initial contact of the particle with the substrate and at a position away from the center bottom of particle, where the highest compressive stress is experienced.

Published

2009

4. Effects of Temperature of In-flight Particles on Bonding and Microstructure in Warm-Sprayed Titanium Deposits

Author

KeeHyun Kim, Makoto Watanabe, Jin Kawakita, and Seiji Kuroda

Subjects

Jet (fluid), Materials science, Scanning electron microscope, Metallurgy, chemistry.chemical_element, Substrate (electronics), Condensed Matter Physics, Microstructure, Surfaces, Coatings and Films, chemistry, Transmission electron microscopy, Materials Chemistry, Particle, Composite material, Thermal spraying, Titanium

Abstract

Micron-sized titanium particles were deposited on steel substrates by the warm spraying, which is a modified high velocity oxy-fuel (HVOF) spraying technique. In the process, nitrogen gas is mixed with the HVOF flame jet to lower the temperature of injected powder particles. Detailed observations of splats formed on polished substrates by using scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were conducted to investigate the effects of particle temperature on the bonding of splats with the substrate and the microstructure within the splats. At lower nitrogen flow rates, the particles observed were heavily deformed and exhibited diverse splat morphologies and microstructures. At higher nitrogen flow rates, most of the particles were impacted in the solid state and the oxidation of particles was remarkably less. The TEM observation revealed distinctively different microstructures within the splats as well as the splat/substrate interfaces depending on whether the particle was molten or solid before the impact.

Published

2009

5. Microstructural Development and Deposition Behavior of Titanium Powder Particles in Warm Spraying Process: From Single Splat to Coating.

Author

KeeHyun Kim, Seiji Kuroda, and Makoto Watanabe

Subjects

*COATING processes, *TITANIUM, *ELECTRON microscopes, *SUBSTRATES (Materials science), *COATINGS industry

Abstract

Warm spraying has been developed by NIMS, in which powder particles are accelerated and simultaneously heated, and deposited onto a suitable substrate in thermally softened solid state. In this study, commercially available titanium powder was sprayed onto steel substrate by the spraying process. Microstructural developments and deposition behaviors from a deposited single particle to a thick coating layer were observed by high resolution electron microscopes. A single titanium particle sprayed onto the substrate was severely deformed and grain-refined mainly along the interfacial boundary of particle/substrate by the impact of the sprayed particle. A successive impact by another particle further deformed the previously deposited particle and induced additional grain refinement of the remaining part. In a thick coating layer, the severe deformation and grain refinement were also observed. The results have demonstrated the complex deposition behavior of sprayed particles in the warm spraying using thermally softened metallic powder particles. [ABSTRACT FROM AUTHOR]

Published

2010

6. Jetting-Out Phenomenon Associated with Bonding of Warm-Sprayed Titanium Particles onto Steel Substrate.

Author

KeeHyun Kim, Watanabe, Makoto, and Kuroda, Seiji

Subjects

*RECRYSTALLIZATION (Metallurgy), *SUPERSONIC nozzles, *COATING processes, *METAL spraying, *PARTICLES (Nuclear physics), *SUBSTRATES (Materials science)

Abstract

Titanium powder particles accelerated and simultaneously heated by the supersonic gas flow were deposited onto steel substrate by the warm spraying process. The sprayed particles were heavily deformed and bonded to the substrate in solid state. Especially, all the deposited particles showed jetting-out of materials out of the particle-substrate interface triggered by the adiabatic shear instability known to occur under such shock impact conditions. High-magnified images showed that grain refinement occurred in the jetting-out region by dynamic recrystallization. Furthermore, the elemental analysis using the electron energy loss spectrum showed jetting-outs of the substrate as well as the particle. Numerical simulation based on the Johnson-Cook plastic deformation model showed that the jetting-out phenomenon commences about 10 ns after the initial contact of the particle with the substrate and at a position away from the center bottom of particle, where the highest compressive stress is experienced. [ABSTRACT FROM AUTHOR]

Published

2009