Kamnis et al., 2008 - Google Patents
Mathematical modelling of Inconel 718 particles in HVOF thermal sprayingKamnis et al., 2008
View PDF- Document ID
- 8249167304078264376
- Author
- Kamnis S
- Gu S
- Zeoli N
- Publication year
- Publication venue
- Surface and Coatings Technology
External Links
Snippet
High velocity oxygen fuel (HVOF) thermal spray technology is able to produce very dense coating without over-heating powder particles. The quality of coating is directly related to the particle parameters such as velocity, temperature and state of melting or solidification. In …
- 239000002245 particle 0 title abstract description 168
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Kamnis et al. | Mathematical modelling of Inconel 718 particles in HVOF thermal spraying | |
| Xiong et al. | Three-dimensional simulation of plasma spray: effects of carrier gas flow and particle injection on plasma jet and entrained particle behavior | |
| Dongmo et al. | Analysis and optimization of the HVOF process by combined experimental and numerical approaches | |
| Tabbara et al. | Computational modelling of titanium particles in warm spray | |
| Kamnis et al. | 3-D modelling of kerosene-fuelled HVOF thermal spray gun | |
| Wen et al. | Modeling of coaxial powder flow for the laser direct deposition process | |
| Li et al. | Modeling and control of high-velocity oxygen-fuel (HVOF) thermal spray: a tutorial review | |
| Mostaghimi et al. | Modeling thermal spray coating processes: a powerful tool in design and optimization | |
| Pan et al. | Numerical analysis of flame and particle behavior in an HVOF thermal spray process | |
| Kamnis et al. | Computational simulation of thermally sprayed WC–Co powder | |
| Jadidi et al. | A three-dimensional analysis of the suspension plasma spray impinging on a flat substrate | |
| Zeoli et al. | Computational simulation of metal droplet break-up, cooling and solidification during gas atomisation | |
| Wang et al. | Investigation on the clogging behavior and additional wall cooling for the axial-injection cold spray nozzle | |
| Zhang et al. | Computer modelling of the influence of process parameters on the heating and acceleration of particles during plasma spraying | |
| Tabbara et al. | Computational simulation of liquid-fuelled HVOF thermal spraying | |
| Gu et al. | Numerical modelling of in-flight particle dynamics of non-spherical powder | |
| Jadidi et al. | Numerical study of suspension HVOF spray and particle behavior near flat and cylindrical substrates | |
| Djebali et al. | Scrutiny of plasma spraying complexities with case study on the optimized conditions toward coating process control | |
| Zeoli et al. | Numerical simulation of in-flight particle oxidation during thermal spraying | |
| Kumar et al. | Simulation of cooling of liquid Al–33 wt.% Cu droplet impinging on a metallic substrate and its experimental validation | |
| Kamnis et al. | Study of in-flight and impact dynamics of nonspherical particles from HVOF guns | |
| Liu et al. | Computational insights into gas atomization of FeCoNiCrMoBSi high-entropy alloy: From droplet formation to rapid solidification | |
| Qunbo et al. | 3D simulation of the plasma jet in thermal plasma spraying | |
| Zhao et al. | Mechanism evaluations of conventional and suspended HVOF thermal spraying based on EDC and EDM combustion models | |
| Gawne et al. | Computational analysis of the influence of a substrate, solid shield and gas shroud on the flow field of a plasma jet |