A Methodology for Blast Furnace Hearth Inner Profile Analysis

2007 ◽  
Vol 129 (12) ◽  
pp. 1729-1731 ◽  
Author(s):  
Yu Zhang ◽  
Rohit Deshpande ◽  
D. Huang ◽  
Pinakin Chaubal ◽  
Chenn Q. Zhou
Keyword(s):  
Heat Transfer ◽  
Blast Furnace ◽  
Profile Analysis ◽  
Furnace Hearth ◽  
Temperature Distributions ◽  
Blast Furnace Hearth ◽  
Computational Fluid Dynamics Cfd ◽  
The Difference ◽  
New Algorithms ◽  
Face Temperature

The wear of a blast furnace hearth and the hearth inner profile are highly dependent on the liquid iron flow pattern, refractory temperatures, and temperature distributions at the hot face. In this paper, the detailed methodology is presented along with the examples of hearth inner profile predictions. A new methodology along with new algorithms is proposed to calculate the hearth erosion and its inner profile. The methodology is to estimate the hearth primary inner profile based on 1D heat transfer and to compute the hot-face temperature using the 3D CFD hearth model according to the 1D preestimated and reestimated profiles. After the hot-face temperatures are converged, the hot-face positions are refined by a new algorithm, which is based on the difference between the calculated and measured results, for the 3D computational fluid dynamics (CFD) hearth model further computations, until the calculated temperatures well agree with those measured by the thermocouples.

A Methodology for Blast Furnase Hearth Wear Analysis

2006 ◽  
Author(s):  
Yu Zhang ◽  
Rohit Deshpande ◽  
D. Huang ◽  
Pinakin Chaubal ◽  
Chenn Q. Zhou
Keyword(s):  
Liquid Iron ◽  
Furnace Hearth ◽  
Wear Analysis ◽  
Temperature Distributions ◽  
Blast Furnace Hearth ◽  
The Difference ◽  
New Algorithms ◽  
Face Temperature ◽  
Detailed Computation ◽  
Good Agreement

The wear of a blast furnace hearth and the hearth inner profile are highly dependent on the liquid iron flow pattern, refractory temperatures, and temperature distributions at the hot face (the interface between the liquid iron and refractory or the skull). A 3-D CFD hearth model has been developed for predict the hearth erosion and its inner profile. The detailed computation results show that the hot face temperature is location dependant. Based on these discoveries, a new methodology along with new algorithms is established to calculate the hearth erosion and its inner profile. The methodology is to estimate the hearth primary inner profile based on 1-D heat transfer, and to compute the hot face temperature using the 3-D CFD hearth model according to the 1-D pre-estimated and re-estimated profiles. After the hot face temperatures are converged, the hot face positions are refined by a new algorithm, which is based on the difference between the calculated and measured results. The finalized CFD prediction temperatures are in good agreement with the experimental results except at or near the corner and taphole regions. In this paper, the detailed methodology and the new algorithm are presented along with the examples of hearth erosion and inner profile predictions.

scholarly journals Influence of Hot Metal Flow on the Heat Transfer in a Blast Furnace Hearth

1985 ◽  
Vol 71 (1) ◽  
pp. 34-40 ◽  
Author(s):  
Jiro OHNO ◽  
Masaharu TACHIMORI ◽  
Masakazu NAKAMURA ◽  
Yukiaki HARA
Keyword(s):  
Heat Transfer ◽  
Blast Furnace ◽  
Metal Flow ◽  
Hot Metal ◽  
Furnace Hearth ◽  
Blast Furnace Hearth

Numerical Investigation of Cooling Strategy for Reducing Blast Furnace Hearth Erosions

2005 ◽  
Author(s):  
Fang Yan ◽  
Chenn Q. Zhou ◽  
D. Huang ◽  
Pinakin Chaubal
Keyword(s):  
Blast Furnace ◽  
Metal Flow ◽  
Cooling Water ◽  
Hot Metal ◽  
Furnace Hearth ◽  
Cooling Water Temperature ◽  
Cooling Strategies ◽  
Temperature Distributions ◽  
Blast Furnace Hearth ◽  
Campaign Life

Hearth wearing is the key limit of a blast furnace campaign life. Hot metal flow pattern and temperature distributions are the two key variables to determine the rate and style of the hearth wearing. There are several strategies to control and reduce the hearth erosion, such as changing cooling water temperature and changing the heat transfer coefficient. In this paper, both cooling strategies are investigated using a comprehensive computational fluid dynamics (CFD) code, which was developed specifically for the simulation of blast furnace hearth. That program can predict the liquid flow patterns and temperature distributions of the hot metal as well as temperature profiles in the hearth refractory materials under different conditions. The results predicted by the CFD code were compared with actual industrial operation data. The cooling strategies are evaluated based on the energy analysis and effect on the hearth erosion.

Heat Transfer Modelling of a Blast Furnace Hearth

2010 ◽  
Vol 81 (3) ◽  
pp. 186-196 ◽  
Author(s):  
M. Swartling ◽  
B. Sundelin ◽  
A. Tilliander ◽  
P. G. Jönsson
Keyword(s):  
Heat Transfer ◽  
Blast Furnace ◽  
Furnace Hearth ◽  
Blast Furnace Hearth ◽  
Transfer Modelling

Temporal Species Concentrations in a Water Model of a Blast Furnace Hearth

2005 ◽  
Author(s):  
David Roldan ◽  
Fang Yan ◽  
C. Q. Zhou ◽  
Mayanlk Tripathi ◽  
Normand Laurendeau ◽  
...  
Keyword(s):  
Blast Furnace ◽  
Three Dimensional ◽  
Water Model ◽  
Laser Dye ◽  
Furnace Hearth ◽  
Species Concentration ◽  
Blast Furnace Hearth ◽  
Species Evolution ◽  
Computational Fluid Dynamics Cfd ◽  
Concentration Evolution

The overall purpose of this paper is to predict species evolution in a water-model hearth using a comprehensive three-dimensional computational fluid dynamics (CFD) code and to validate the code with experimental data. The water model is built to simulate the flow patterns in a blast furnace hearth. The water model is a 1/50th scale of Ispat Inlands’s BF#7. The data focus on time-dependent concentration profiles in a three-dimensional water model. The concentration is determined by using a fluorescence laser dye called rhodamine 590 chloride. The effects of flow rate and different geometries on species concentration evolution are studied.

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