Numerical Modeling of In-Flight Molten Metal Droplet Dynamics and Particle Oxidation in Atmospheric Plasma Spraying

Mahrukh Mahrukh; Li Zhang; Sen Hui Liu; Chang Jiu Li

doi:10.4028/p-6M9Ed0

Paper Titles

Effect of Zirconium Conversion Coating on Corrosion Resistance of Small-Defected Auto Steel Sheets
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Optimization of Anodizing Condition for Mg-14mass%Li-3mass%Al Alloy
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Numerical Modeling of In-Flight Molten Metal Droplet Dynamics and Particle Oxidation in Atmospheric Plasma Spraying
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Microstructural Stability of a Metallic Thermal Barrier Coatings for Rocket Engine
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Strategy to Generate Oxide-Free Molten Metal Droplets for Fully Dense Corrosion-Resistant Coatings by Atmospheric Plasma Spraying
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Oxidation Behavior of Atmospheric Plasma Sprayed NiAl Coating at High Pressure Oxygen Atmosphere
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Crystallographic Textures of Al and Al-Mg Alloy Formed by Shot-Peening
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Effects of Shot Peening on Mechanical Properties and Microstructural Evolution of AMS 6265 Steel Surface Treated for Critical Aircraft Components
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HomeMaterials Science ForumMaterials Science Forum Vol. 1106Numerical Modeling of In-Flight Molten Metal...

Numerical Modeling of In-Flight Molten Metal Droplet Dynamics and Particle Oxidation in Atmospheric Plasma Spraying

Abstract:

In Atmospheric Plasma Spraying (APS), it is important to understand the controlling factors dominating molten metal droplets’ reaction dynamics to control final coating compositions and properties. The present paper focuses on a novel Computational Fluid Dynamics (CFD) modeling of mass transfer mechanisms of an inflight molten metal droplet leading to droplet oxidation control during APS. The onset conditions of droplet internal circulation and its effect on the deoxidizer oxidation behavior during APS are theoretically examined. Moreover, rapidly supplying these elements from the inside to the droplet surface requires the rapid switching of the mass transfer mechanism to rapid convective flow due to a very limited in-flight time of less than 1ms. The temperature and velocity variations within the droplet would influence the thermo-physical properties of the droplet and the plasma gas and it controls the onset of the internal circulations within the droplets. A novel User Defined Function (UDF) is developed to capture the onset of Hill’s vortex formation and its effect on the rapid-rate convective mass transfer mechanism during APS. Further, a detailed analysis of particle size effect on in-flight in-situ deoxidation during APS of NiAlC droplets was performed. It is observed that the smaller size droplets will undergo more severe oxidation during a flight than larger size droplets due to more molecules of O2 available for reaction in the smaller droplet.

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Periodical:

Materials Science Forum (Volume 1106)

Pages:

15-20

DOI:

https://doi.org/10.4028/p-6M9Ed0

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Online since:

December 2023

Authors:

Mahrukh Mahrukh*, Li Zhang, Sen Hui Liu, Chang Jiu Li

Keywords:

Atmospheric Plasma Spraying, Deoxidization, Mass Transfer Mechanism, Metal Coating, Molten Metal Spray Droplet, Oxidation

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References

[1] P. Fauchais and A. Vardelle, Thermal sprayed coatings used against corrosion and corrosive wear, in Advanced Spray Applications, J. Hamid, Ed., InTech, 2012.