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Effect of Thermal Buoyancy on Fluid Flow and Residence-Time Distribution in a Single-Strand Tundish

Dong-Yuan Sheng, Pär G. Jönsson

2021Materials28 citationsDOIOpen Access PDF

Abstract

Natural convection of molten steel flow in a tundish occurs due to the temperature variation of the inlet stream and heat losses through top surface and refractory walls. A computational fluid dynamics (CFD) model was applied to study the effect of thermal buoyancy on fluid flow and residence-time distribution in a single-strand tundish. The CFD model was first validated with the experimental data from a non-isothermal water model and then applied to both scale-down model and prototype. The effects of flow control devices, including weir, dam and turbulence inhibitor, were compared and analyzed. Parameter studies of different heat losses through the top surface were performed. The results show that thermal buoyancy has a significant impact on the flow pattern and temperature distributions of molten steel in the tundish. The increase of heat loss through the top surface shortens the mean residence time of molten steel in the tundish, leading to an increase in dead volume fraction and a decrease in plug flow volume fraction.

Topics & Concepts

TundishBuoyancyMechanicsResidence time distributionMaterials scienceTurbulenceWater modelFluid dynamicsComputational fluid dynamicsFlow (mathematics)Residence time (fluid dynamics)Volume of fluid methodPlug flowFree surfaceIsothermal processThermodynamicsContinuous castingMetallurgyChemistryGeotechnical engineeringEngineeringMolecular dynamicsComputational chemistryPhysicsMetallurgical Processes and ThermodynamicsFluid Dynamics and MixingNuclear Engineering Thermal-Hydraulics
Effect of Thermal Buoyancy on Fluid Flow and Residence-Time Distribution in a Single-Strand Tundish | Litcius