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Numerical investigation on flow process of liquid metals in melt delivery nozzle during gas atomization process for fine metal powder production

Chang Liu, Xin Li, Xin LI, Shi Shu, Yuhe Huang, Xing-gang LI, Xing-gang LI, Qiang Zhu

2021Transactions of Nonferrous Metals Society of China23 citationsDOIOpen Access PDF

Abstract

Based on volume of fluid (VoF) interface capturing method and shear-stress transport (SST) k-ω turbulence model, numerical simulation was performed to reveal the flow mechanism of metal melts in melt delivery nozzle (MDN) during gas atomization (GA) process. The experimental validation indicated that the numerical models could give a reasonable prediction on the melt flow process in the MDN. With the decrease of the MDN inner-diameter, the melt flow resistance increased for both molten aluminum and iron, especially achieving an order of 102 kPa in the case of the MDN inner-diameter ≤1 mm. Based on the conventional GA process, the positive pressure was imposed on the viscous aluminum alloy melt to overcome its flow resistance in the MDN, thus producing powders under different MDN inner-diameters. When the MDN inner-diameter was reduced from 4 to 2 mm, the yield of fine powder (<150 μm) soared from 54.7% to 94.2%. The surface quality of powders has also been improved when using a smaller inner-diameter MDN.

Topics & Concepts

Volume of fluid methodMaterials scienceNozzleLiquid metalTurbulenceFlow (mathematics)AluminiumMetallurgyAlloyMetal powderYield (engineering)MechanicsComposite materialMetalMechanical engineeringEngineeringPhysicsFluid Dynamics and Heat TransferParticle Dynamics in Fluid FlowsAdditive Manufacturing and 3D Printing Technologies
Numerical investigation on flow process of liquid metals in melt delivery nozzle during gas atomization process for fine metal powder production | Litcius