Hong Lei scite author profile

Knowledge of gas-liquid multiphase flow behavior in the Rheinsahl-Heraeus (RH) system is of great significance to clarify the circulation flow rate, decarburization, and inclusion removal with a reliable description. Thus, based on the separate model of injecting gas behavior, a novel mathematical model of multiphase flow has been developed to give the distribution of gas holdup in the RH system. The numerical results show that the predicted circulation flow rates, the predicted flow velocities, and the predicted mixing times agree with the measured results in a water model and that the predicted tracer concentration curve agrees with the results obtained in an actual RH system. With a lower lifting gas flow rate, the rising gas bubbles are concentrated near the wall; with a higher lifting gas flow rate, gas bubbles can reach the center of the up-snorkel. A critical lifting gas flow rate is used to obtain the maximum circulation flow rate.

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Simulation on Decarburization and Inclusion Removal Process in the Ruhrstahl–Heraeus (RH) Process with Ladle Bottom Blowing

Geng

Jinxing

Wang

et al. 2015

Metall Mater Trans B

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Mathematical Model for Nucleation, Ostwald Ripening and Growth of Inclusion in Molten Steel

Lei¹,

Nakajima

Jiang³

2010

ISIJ Int.

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Numerical simulation is a powerful tool to investigate inclusion behavior in the molten steel. Although many mathematical models have been developed to predict inclusion collision-growth behavior in different metallurgical reactors, the inclusion size distribution had to be obtained by experiment or assumption. Thus, a general nucleation-growth model, which involves in chemical reaction, homogeneous nucleation and growth kinetics, is developed to investigate the inclusion nucleation, Ostwald ripening, Brownian collisiongrowth, Stokes collision-growth and turbulent collision-growth. In order to speed up the calculation, the deoxidation products are divided into two parts. The first part only consists of embryos, and directly numerical simulation is used to solve the differential equations. The second part only consists of inclusion particles, and particle-size-grouping method is introduced to solve the related equations. Numerical results showed that the predicted inclusion size distributions are consistent with previous experimental data. With the increasing diffusion coefficient, the peak-value diameter keeps unchanged and the maximum number density decreases. With the increasing turbulent energy dissipation rate, the peak-value diameter and the maximum number density decrease under the assumption on floating-out of larger inclusions.

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Simulation on flow field and mixing phenomenon in RH degasser with ladle bottom blowing

Geng

Lei

Jiang

2012

Ironmaking & Steelmaking

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A numerical method has been employed to investigate the flow field and mixing characteristic in the Rheinsahl-Heraeus (RH) degasser with side-bottom blowing. The numerical results showed that stream flows in the up snorkel, the vacuum chamber, the down snorkel and the ladle form a large rectangular circulation zone in the RH degasser with side-bottom blowing, which can enhance the circulation flow rate effectively. For an RH with side-bottom blowing, when the included angle of the line between bottom blowing location and ladle centre and the line between two snorkels is zero, the circulation flow rate increases initially with increasing dimensionless distance between the bottom blowing location and the ladle centre and then decreases, while the mixing time increases with increasing dimensionless distance. On the other hand, when the dimensionless distance is 0?2, both the circulation flow rate and the mixing time decrease with the increasing included angle initially, reach their minimum value and then increase. The optimum values for the dimensionless distance and the included angle to achieve large circulation flow rate and small mixing time are 0?2 and p/4 in the present work.

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Fluid Flow and Heat Transfer in a Tundish with Channel Type Induction Heating

Yang

Lei

et al. 2018

steel research int.

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Because of the high heating efficiency, channel type induction heating is utilized in the tundish in order to reduce the temperature fluctuations of the molten steel in the process of continuous casting. In order to have a deep insight into the complex MHD (magneto hydrodynamic) process in the tundish with channel type induction heating, water model and mathematical model are performed to describe the fluid flow and the heat transfer in the tundish. A non-isothermal water model with channel heater is built to investigate the thermal convection in the tundish. The electromagnetic force and Joule heating are introduced into the momentum equations and the energy conservation equation as a source term, and the coupled flow and temperature field are solved by the finite volume method. The results show that the predicted flow field and temperature field agree with the experimental data. In the case of channel type induction heating, there are two spiral flow in the channel due to electromagnetic force, and the temperature difference of molten steel is 12 C between the inlet and the outlet of the channel due to Joule heating.

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Hong Lei

Numerical Simulation of the Multiphase Flow in the Rheinsahl–Heraeus (RH) System

Simulation on Decarburization and Inclusion Removal Process in the Ruhrstahl–Heraeus (RH) Process with Ladle Bottom Blowing

Mathematical Model for Nucleation, Ostwald Ripening and Growth of Inclusion in Molten Steel

Simulation on flow field and mixing phenomenon in RH degasser with ladle bottom blowing

Fluid Flow and Heat Transfer in a Tundish with Channel Type Induction Heating

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