KR101435271B1 - Method for predicting coke replacement ratio of furnace pulverized coal - Google Patents

Abstract

The present invention relates to a method of predicting the replacement rate of blast furnace coke, comprising the steps of: selecting an influencing factor having a high correlation with blast furnace coke replacement rate; deriving a correlation between blast furnace coke replacement rate and blast furnace coke replacement rate for the selected influencing factor; And predicting the blast furnace coke replacement rate from the correlation derived in the correlation derivation step.
The present invention has the advantage of increasing the efficiency of blast furnace blowing operation and achieving stable and economical blast furnace operation.

Description

METHOD FOR PREDICTING COKE REPLACEMENT RATIO OF FURNACE PULVERIZED COAL

The present invention relates to a method for predicting blast furnace coke replacement ratio, and more particularly, to a blast furnace coke replacement rate predicting method for predicting coke replacement ratio of pulverized coal during pulverized coal blowing operation in a blast furnace.

Coke is a fuel used as a heat source for blast furnaces and serves as a reducing agent for reducing iron ores. Coke is produced by heating coal in a coke oven plant.

Coal for coke production must have cohesion that can be clogged well during carbonization, so coal is often used as a raw material. Coal used in the manufacture of coke may be referred to as coking coal by distinguishing it from ordinary fuel.

Prior art related to the present invention is Korean Patent No. 10-0206486 (Apr. 4, 1999) entitled " Method for producing coke for blast furnace ".

An object of the present invention is to provide a method for predicting the replacement rate of blast furnace coke by using pulverized coal in a blast furnace so as to increase the efficiency of pulverized coal blowing operation and to enable economic blast furnace operation.

According to an aspect of the present invention for achieving the above object, the present invention provides a method for manufacturing a coke oven, comprising the steps of: selecting an influencing factor having a high correlation with a blast furnace coke replacement ratio; And a step of predicting the blast furnace coke replacement ratio from the correlation derived in the correlation deriving step.

The influencing factors selected in the step of selecting the influence factor are the pulverized coal calorific value and the pulverized coal burning rate.

The pulverized coal calorific value is measured using a calorific value measuring apparatus.

The pulverized coal combustion rate is calculated by the following equation (1).

&Quot; (1) "

Fuel combustion ratio = -9.0668 占 F.R + 104.76 (F.R: Fuel ratio = FC (%) / VM (%))

[Where FC is the fixed carbon content, VM is the volatile content]

The blast furnace-pulverized coke replacement ratio is calculated by the following formula (2).

&Quot; (2) "

Blast furnace coke replacement rate = 0.003 x (pulverized coal combustion rate) + 0.016 x (pulverized coal calorific value) (MJ / kg) + 0.298

Here, the pulverized coal combustion rate is calculated from the formula: -9.07 × F.R + 104.76 (F.R: Fuel ratio = FC / VM), the pulverized coal calorific value is the measured value,

[FC is fixed carbon content, VM is volatile content]

The present invention predicts the pulverized coal combustion rate from the fixed carbon content and the volatile content of the pulverized coal, and easily predicts the pulverized coal pulverization coke replacement rate using the predicted pulverized coal combustion rate and the pulverized coal calorific value measured using the calorific value measurement apparatus.

Therefore, it is possible to quantitatively evaluate the degree of substitution of coke for blowing pulverized coal, thereby achieving a stable and economical blast furnace operation while enhancing the efficiency of blast furnace blowing operation.

1 is a graph showing the correlation between pulverized coal heating rate and blast furnace coal coke replacement ratio.
2 is a graph showing the correlation between pulverized coal combustion rate and blast furnace coal coke replacement ratio.
FIG. 3 is a graph showing the correlation with the pulverized coal combustion rate with respect to the fuel cost in the pulverized coal.
4 is a graph showing the correlation between the blast furnace coke replacement ratio predicted by the present invention and the actually measured blast furnace coke replacement ratio.
5 and 6 are graphs showing apparent permittivity as a comparative example for comparison with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The prediction method of blast furnace coke replacement ratio of the present invention predicts based on the chemical replacement ratio such as fixed carbon, calorific value, and ash.

Specifically, the method for predicting blast furnace coke replacement rate prediction method includes the steps of: selecting an influencing factor having a high correlation with the blast furnace coke replacement ratio; deriving a correlation between blast furnace coke replacement rate and blast furnace coke replacement rate for a selected influencing factor; And estimating the blast furnace coke replacement ratio from the correlation derived from the blast furnace.

The coke replacement ratio indicates the rate at which consumption of coke is reduced by blowing pulverized coal.

Pulverized coal injection means finely crushing low cost coking coal instead of coke used for blast furnace and injecting it directly into the blast furnace through tuyere. The pulverized coal is a coal having a particle size of 0.5 mm or less, and preferably the pulverized coal is a coal having a particle size of 75 μm or less after pulverization of 70 to 80% or more.

Because the cost of pulverized coal is 40% lower than the cost of coke, it can contribute to cost savings by lowering the operating cost of the coke oven as well as significantly reducing the production cost of the charcoal, reducing the coke production load and prolonging the life of the coke oven.

However, if the blowing of the pulverized coal is increased more than a certain level, the coke replacement ratio of the pulverized coal is lowered, so that the blast furnace operation becomes unstable and the fuel cost may increase.

As described above, the pulverization of pulverized coal substitutes for coke to reduce the amount of coke used, but excessive pulverization causes unstable blast furnace operation, so it is important to quantitatively evaluate the degree of substitution of coke for pulverizing coal.

Quantitative evaluation of the degree of substitution of coke for pulverized coal injection is used as an index to evaluate the economical efficiency of pulverized coal and blast furnace operation efficiency.

The influencing factors correlating with the pulverized coal coke replacement ratio include pulverized coal, pulverized coal calorific value, pulverized coal particle size, blast furnace blowing conditions (eg acid consumption), blowing conditions (eg, ventilation wetness, oxygenation) Charge distribution, heat flow ratio), and raw material conditions (eg, reductive differentiation, hot strength).

As described above, there are various factors such as coal characteristics and blast furnace operating conditions that are highly correlated with the blast furnace coke replacement ratio. Among them, the pulverized coal (MJ / kg) and the pulverized coal combustion rate (%) are the most important chemical factors that have a high correlation with the pulverized coal coke replacement ratio.

The calorific value of pulverized coal is the amount of heat generated when the pulverized coal is completely burned, and is one of the characteristics of the coal litter that affects the coke replacement ratio of pulverized coal. The pulverized coal combustion rate determines the amount of heat and the amount of reducing gas (CO) generated, which serve as a substitute for the coke, according to the degree of combustion of pulverized coal.

For this reason, the pulverized coal calorific value and the pulverized coal combustion rate are selected as important factors of the method of predicting the pulverized pulverized coal coke replacement ratio.

1 and 2, the pulverized coal gas calorific value and the pulverized coal combustion rate are highly correlated with the pulverulent pulverized coal coke replacement ratio.

The calorific value of pulverized coal is measured using a calorimeter (BOMB). The calorific value measuring device is a device for measuring the heat of reaction in which coal is burned and released in the form of heat.

Since the pulverized coal combustion rate is difficult to directly measure the pulverized coal combustion rate in the blast furnace, the pulverized coal combustion rate is calculated by a predictive formula.

After the influence factors affecting the pulverized coal combustion rate are collected, the influential factors that are highly correlated with the pulverized coal combustion rate are selected as the independent variables by applying the collected influential factors to the regression analysis method, The pulverized coal combustion rate prediction equation is calculated.

The independent variable is the fuel cost. Fuel cost is expressed as fixed carbon content with respect to volatile content. The lower the fuel cost in the pulverized coal, the higher the combustion efficiency in the gas state.

The pulverized coal combustion rate is calculated by the following equation (1).

&Quot; (1) "

Fuel combustion ratio = -9.0668 占 F.R + 104.76 (F.R: Fuel ratio = FC (%) / VM (%))

[Where FC is the fixed carbon content, VM is the volatile content]

As shown in FIG. 3, the pulverized coal combustion rate calculated by Equation (1) has a high correlation with the pulverized coal combustion rate and the determination coefficient R ² of 0.9144 as measured in the actual operation.

The fixed carbon in the pulverized coal reacts with oxygen in the air, blowing moisture, and oxygen by the oxygen load to generate CO gas, which has an important influence on the pulverized coal combustion rate.

In addition, the volatile matter in the pulverized coal has a significant influence on the pulverized coal combustion rate as a component which becomes a gas.

The correlation is derived by applying the session analysis method. Regression analysis is a statistical technique that explains and predicts the value of a particular variable from one or more variables by determining the relationship between two or more variables.

The pulverized coal coke replacement ratio is calculated by the following formula (2).

&Quot; (2) "

Blast furnace coke replacement rate = 0.003 x (pulverized coal combustion rate) + 0.016 x (pulverized coal calorific value) (MJ / kg) + 0.298

Here, the pulverized coal combustion rate is calculated from the above-described equation (1) = -9.07 × F.R + 104.76 (F.R: Fuel ratio = FC / VM) and the pulverized coal calorific value is a measured value.

FC is the fixed carbon content, and VM is the volatile content.

As shown in FIG. 4, the blast furnace-pulverized coke replacement ratio calculated by the equation (2) is high with a correlation coefficient R ² of 0.51, which shows a correlation with the actually measured blast furnace-pulverized coke replacement ratio.

In the actual blast furnace operation, the complex reaction occurs simultaneously with the endothermic reaction of iron ore in the blast furnace. Therefore, it is judged that the correlation coefficient is 0.51 when the coefficient of correlation with the actual measured blast furnace coke replacement ratio is 0.51.

As described above, the present invention can predict the pulverized coal combustion rate from the fixed carbon content and the volatile content of the pulverized coal, and can easily predict the pulverized coal using the pulverized coal combustion rate and the calorific value of the pulverized coal measured using the calorific value measuring apparatus. It is possible to predict the replacement rate.

Therefore, it is possible to achieve a stable and economical blast furnace operation while reducing the amount of coke used by increasing the efficiency of blast furnace blowing operation.

For comparison with the present invention, FIG. 5 and FIG. 6 show the apparent substitution ratio.

The apparent substitution rate is the ratio of the amount of decrease in coke (ΔCR) to the amount of increase in pulverized coal (Δ PCR), and is a comparative example for predicting the replacement rate of pulverized pulverized coal coke.

In the case of the apparent permittivity, it was found that there was no correlation between the pulverization rate and the apparent substitution rate.

In addition, the method of predicting the substitution rate of the pulverized coal component based on the blast furnace operation performance is further studied. However, it is difficult to quantitatively evaluate the substitution of coke for the pulverized coal injection or the prediction method is complicated unlike the present invention.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

Claims (4)

Selecting an influencing factor correlating with the pulverized coal coke replacement ratio;
Deriving a correlation with the pulverized coal coke replacement ratio to the selected influencing factor;
And predicting the superfine pulverized coal coke replacement ratio from the correlation derived in the correlation deriving step,
The influencing factor selected in the step of selecting the influence factor,
And the pulverized coal combustion rate is a pulverized coal heating value and a pulverized coal combustion rate. delete The method according to claim 1,
Wherein the pulverized coal combustion rate is calculated by the following equation (1).
&Quot; (1) "
Fuel combustion ratio = -9.0668 占 F.R + 104.76 (FR: Fuel ratio = FC (%) / VM (%))
[Where FC is the fixed carbon content, VM is the volatile content] The method according to claim 1,
Wherein the blast furnace-pulverized coke replacement ratio is calculated by the following formula (2).
&Quot; (2) "
Blast furnace coke replacement rate = 0.003 x (pulverized coal combustion rate) + 0.016 x (pulverized coal calorific value) (MJ / kg) + 0.298
Here, the pulverized coal combustion rate is calculated from the equation: -9.07 × F.R + 104.76 (FR: Fuel ratio = FC / VM), the pulverized coal calorific value is the measured value,
[FC is fixed carbon content, VM is volatile content]

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