Mathematical Model of Solid Flow Behavior in a Real Dimension Blast Furnace

Nick, Reza Safavi; Tilliander, Anders; Jonsson, T.; Jönsson, Pär G.

doi:10.2355/isijinternational.53.979

Cited by 12 publications

(6 citation statements)

References 41 publications

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“…41) For fluids, the well-known Semi-Implicit Method for PressureLinked Equations (SIMPLE) scheme 42) was used to solve Eqs. (3), (4), (8), and (12) and the conservation of momentum, energy, and mass for a fluid cell. Each term was discretized with second-order accuracy.…”

Section: Solution Methodsmentioning

confidence: 99%

“…At present, this method can predict the change in the melting zone from the temperature distribution. 7) Although there have been considerable researches focused on burden distribution modeling, 8,9) calculating the discrete inter-particle stress using the E-E method is too complicated. Using the Euler-Lagrange (E-L) method is much easier; 10) this approach can generate transport equations of an individual solid particle.…”

Section: Mathematical Modelingmentioning

confidence: 99%

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Effect of High Reactivity Coke for Mixed Charge in Ore Layer on Reaction Behavior of Each Particle in Blast Furnace

et al. 2013

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A low coke rate operation in blast furnace is desired to decrease the carbon input and mitigate global warming problem. However, low coke rate operation tends to cause the gas permeability to deteriorate. The mixing of small-size coke (nut coke) including high reactivity coke in ore layer is considered to be a promising way to improve permeability and increase reaction efficiency in a blast furnace. Although adding a nut coke mixing to an ore layer is predicted to be empirically effective in low coke rate operation, there is little actual data on microscopic phenomena of each particle in the packed bed. In the present study, an Euler-Lagrange approach was introduced to precisely understand the influence of the packed bed structure on the reaction behavior of each particle in the three-dimensional particle arrangement.It was observed that the heterogeneity on the reaction rate and temperature distribution was influenced by the particle arrangement. When high-reactivity coke was used at approximately 1 273 K, although CO gas fraction increased, the gaseous phase temperature decreased due to the active solution loss reaction rate of the nut coke in the mixed layer. As a result, the ore reduction rate decreased. The contribution of high-reactivity coke to the ore reduction rate depends on the particle arrangement through the heat transfer and reaction heat. Accordingly, in the case of the mixed charge of the high reactivity nut coke in the ore layer, the design of the packed bed structure is important.

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Section: Solution Methodsmentioning

confidence: 99%

Section: Mathematical Modelingmentioning

confidence: 99%

Effect of High Reactivity Coke for Mixed Charge in Ore Layer on Reaction Behavior of Each Particle in Blast Furnace

et al. 2013

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“…This simplified model does not accurately predict the quasi‐stagnant zone, which is associated with the strong inter‐particle friction and should be described by a more complicated model, as shown by Zhang et al On the other hand, it is superior to the early potential, kinematic, or viscous model and is simple to be included in a process model. Recently, Nick et al extended the model of Zhang et al from 2D to 3D.…”

Section: Modeling and Simulation Of Different Bf Regionsmentioning

confidence: 99%

Review on Modeling and Simulation of Blast Furnace

Kuang

2017

steel research int.

157

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The design and control of blast furnace (BF) ironmaking must be optimized in order to be competitive and sustainable, particularly under the more and more demanding and tough economic and environmental conditions. To achieve this, it is necessary to understand the complex multiphase flow, heat and mass transfer, and global performance of a BF under different conditions. Mathematical modeling, often coupled with physical modeling, plays an important role in this area. This paper reviews the recent developments in this direction. The emphasis is given to mathematical models for different BF regions from the top charging system, body, and finally down to raceway and hearth. The needs for the further research and developments are also discussed.

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“…Present development of laboratory equipment and numerical methods are the means to obtain the data easily with the use of physical and mathematical modeling of the metallurgical processes. numerous investigations which help to study the processes inside metallurgical reactors carried out with mathematical modeling have been described in literature [2][3][4][5][6][7][8][9].…”

Section: Mathematical Model Of Gas Powder and Bed Flow In Metallurgimentioning

confidence: 99%

Mathematical Model of Gas, Powder and Bed Flow in Metallurgical Shaft Furnaces

Panic

2016

Archives of Metallurgy and Materials

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This paper presents the second phase of model investigations. In the first phase research into flow for the system “gas transporting powder - moving packed bed” was conducted in the physical modeling. The influence of bed, powder and gas parameters on values of interaction forces and phenomena occurring in investigated system was defined.The article discusses the successive stage of investigations into gas flow carrying the powder through the descending packed bed. The research was performed with the application of mathematical modeling after tests with a physical model in use had been accomplished. The elaborated mathematical model was used to calculate resistance values of gas flow carrying the powder through the descending packed bed, masses of ‘static’ and ‘dynamic’ powders as well as total mass of powder holdup in the bed. Then the verification of the model was done comparing the obtained results with those from the physical model.

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Mathematical Model of Solid Flow Behavior in a Real Dimension Blast Furnace

Cited by 12 publications

References 41 publications

Effect of High Reactivity Coke for Mixed Charge in Ore Layer on Reaction Behavior of Each Particle in Blast Furnace

Effect of High Reactivity Coke for Mixed Charge in Ore Layer on Reaction Behavior of Each Particle in Blast Furnace

Review on Modeling and Simulation of Blast Furnace

Mathematical Model of Gas, Powder and Bed Flow in Metallurgical Shaft Furnaces

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