KR20120057966A - Predicting Method ofr Chenneling of Blast Furnace - Google Patents

Abstract

PURPOSE: A method for predicting channeling of a blast furnace is provided to reduce the number of items for prediction by using the distribution ratio of indexes. CONSTITUTION: A method for predicting channeling of a blast furnace is as follows. Ventilation resistance indexes are calculated as the pressures measured in the upper, middle, and lower parts of the blast furnace(100). The distribution ratio of the ventilation resistance indexes for the upper, middle, and lower parts of the blast furnace is output in real time(200). The change rate per hour of the average distribution ratio is calculated for a fixed time before a reference time of each distribution ratio of the ventilation resistance indexes(300). The ventilation resistance indexes are multiplied by respective weighted values and channeling is determined based on the total sum of the three values(400).

Description

Prediction Method ofr Chenneling of Blast Furnace}

The present invention relates to a method for predicting the blast phenomena of the blast furnace, and more particularly, to predict the occurrence of blast blast phenomena to prevent the occurrence of accidents due to the blow phenomenon.

In general, the blast furnace is repeatedly charged with fuel coke and ore while blowing hot air through the tuyere to melt the charged ore to produce molten iron.

The blast furnace blast serves to control the flow of gas by supplying hot air into the blast furnace as well as pulverized coal.

The present invention provides a method of predicting the blast furnace phenomena to accurately predict the occurrence of blast furnace phenomena to prevent the occurrence of accidents due to the blow phenomena, and to enable the stable production of molten iron.

The object of the present invention is a ventilation resistance index calculation step of calculating the ventilation resistance index by the pressure measured at the pressure of the upper, middle, and lower in the blast furnace;

A distribution ratio output step of outputting, in real time, a distribution ratio of an upper ventilation resistance index, a middle ventilation resistance index, and a lower ventilation resistance index calculated by the ventilation resistance index calculation step;

An item index value calculation step of calculating an hourly rate of change of the distribution ratio average value for a predetermined time before the reference time of the distribution ratio of the upper ventilation resistance index, the distribution ratio of the central ventilation resistance index, and the distribution ratio of the lower ventilation resistance index outputted in the distribution ratio output step;

A determination step of determining that the phenomenon is a drought based on the sum of the three item values after multiplying each of the upper item index value, the central item index value, and the lower item index value calculated by the item index value calculating step. This is solved by providing a method for predicting the occurrence of blast furnace phenomena which includes the blast furnace.

The present invention has the effect of accurately predicting the occurrence of the blast furnace phenomenon to prevent the occurrence of accidents due to the extraction phenomenon, and to enable the stable production of molten iron.

The present invention has the effect of maintaining the blast furnace in an optimal state to extend the life of the blast furnace and the quality of the molten iron.

Figure 1 is a schematic diagram showing the structure of the blast furnace to which the present invention is applied blast furnace prediction method
Figure 2 is a schematic diagram showing the pressure detection stage in the blast furnace to which the inventors of the blast furnace phenomena prediction method applied
3 is a flowchart showing each step of the present invention.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

As shown in FIG. 1, the hot air is blown into the blast furnace 10 through the hot stove 21 and the air vent 21a by the operation of the blower 20 during the operation of the blast furnace to which the present invention is applied. In order to improve and perform economic operation, in addition to hot air, pulverized coal and oxygen are blown together into the blast furnace 10 through the tuyere 21a.

In the upper part of the blast furnace 10, coke and sintered ore are sequentially charged into the blast furnace 10 alternately with each other through a charging facility. The charged coke and the sintered ore are lowered to form a layer, respectively.

In the blast furnace 10, the coke and the sintered ore are charged and alternately, hot gas passes through the gas filled with the coke and the sintered ore to gasify, causing reduction and melting reaction to produce molten iron, and the molten iron produced is the blast furnace (10). It is collected at the lower part of) and discharged to the outside through the exit.

The pressure received by the hot air as it passes through the furnace during the series of processes is called wind pressure (PB), and the frictional resistance that the hot air passes through each of the factors inside the furnace is called the airflow resistance index (K).

The wind pressure is detected by the pressure detecting means of the hot air line 3, and the airflow resistance index is calculated by each operation index.

Also, as shown in FIG. 2, various measurement sensors such as a plurality of pressure detectors 30 mounted at different heights in the furnace body thermometer and the blast furnace 10 to determine the internal situation of the blast furnace 10 operate. It is utilized in.

The pressure detecting stage 30 is provided with a pressure gauge for measuring the pressure in the furnace, the pressure gauge while the hot air from the bottom of the blast furnace 10 is gasified into the hearth while passing through the charge, that is, the filling layer of coke and sintered ore. This is for measuring the change in the blowing pressure of the upper pressure detection stage 31, the middle pressure detection stage 32, the lower pressure detection stage 33 is divided.

Hereinafter, a method for accurately predicting a bleeding phenomenon occurring when producing molten iron in the blast furnace 10 will be described in detail.

The blow-up phenomenon is a phenomenon in which the gas rising up the packed layer in the blast furnace 10 exits the furnace as it is at a high temperature without heat exchange with the charges.

Usually, slip and collapse that occur in general are classified as cathodic phenomena due to instantaneous brittleness or minor adverse effects after they occur. When the large blow-out phenomenon occurs, hot air introduced at 1200 ° C. into the blast furnace 10 almost rises to the top of the furnace with little heat exchange with the charges, and releases gas at a temperature of up to 1000 ° C. or more to several tens of seconds for several minutes. It causes a lot of damage.

In order to predict the phenomenon of blow out during the operation, it is preferable to set a judgment process for the process of occurrence of blow out according to the characteristics of each operation of the blast furnace 10.

The present invention is a ventilation resistance index calculation step 100 to calculate the ventilation resistance index by the pressure measured at the pressure of the upper, middle, and lower in the blast furnace 10, the upper ventilation resistance index, the central ventilation resistance index, the lower ventilation resistance Find the index.

The blast furnace 10 is provided with a plurality of pressure detection stages with a height difference as described above. In the present invention, when 12 detection stages are provided, the wind pressure and the lowermost end of the blast furnace 10 to the sixth stage are provided. The pressure is divided into the lower pressure detecting stage 33, and the pressure of the seventh to tenth stage is divided into the middle pressure detecting stage 32, and the pressure between the eleventh stage and the stationary pressure into the upper pressure detecting stage 31. Take this as an example.

In the above example, the equation for obtaining the upper ventilation resistance index UK is as shown in Equation 1 below.

SP11: 11th stage pressure (kg / cm ² )

PT: Blast pressure of blast furnace (kg / cm ² )

1033 is the atmospheric pressure (g / cm ² )

VBG: Blast Furnace Bosch Gas Pressure (Nm ³ / min)

In addition, in the above example, the formula for obtaining the central ventilation resistance index (MK) is shown in Equation 2 below.

SP7: 7th stage pressure (kg / cm ² )

SP10: 10th stage pressure (kg / cm ² )

1033 is the atmospheric pressure (g / cm ² )

VBG: Blast Furnace Bosch Gas Pressure (Nm ³ / min)

Further, in the above example, the equation for obtaining the lower ventilation resistance index LK is as shown in Equation 3 below.

PB: Wind pressure of blast furnace (kg / cm ² )

SP6: 6th stage pressure (kg / cm ² )

1033 is the atmospheric pressure (g / cm ² )

VBG: Blast Furnace Bosch Gas Pressure (Nm ³ / min)

After the ventilation resistance index calculation step 100, the distribution ratio output step 200 for real-time outputting the distribution ratios of the upper ventilation resistance index, the middle ventilation resistance index, and the lower ventilation resistance index calculated in the ventilation resistance index calculation step 100 is Is done.

The distribution ratio is a distribution ratio of each ventilation resistance index when the sum of the upper ventilation resistance index, the central ventilation resistance index, and the lower ventilation resistance index is 100.

As an example, if the upper air resistance index is 20, the central air resistance index is 20, and the lower air resistance index is 60, the distribution ratio of the upper ventilation resistance index is 20, the distribution ratio of the central ventilation resistance index is 20, and the distribution ratio of the lower ventilation resistance index is 60.

As described above, the distribution ratio is output per minute in real time, and through the item index value calculation step 300 for calculating the rate of change of the distribution ratio average value for a predetermined time before the reference time point of each distribution ratio output per minute, respectively.

The item index value calculating step 300 may calculate each item index value by subtracting an hourly change rate of the distribution ratio average value for a short time before the reference time point from the hourly change rate of the distribution ratio mean value for a long time before the reference time period longer than the short time. Do.

As an example, a short time may be 12 minutes before the reference time point, and the long time may be 1 hour before the reference time point.

This is to accurately understand the difference between the change rate for one hour, that is, for a long time, and for a short time, and to accurately output each item index rapidly changing for a short time.

After the item index value calculating step 300, the upper item index value, the central item index value, and the lower item index value calculated by the item index value calculating step 300 are multiplied by respective weights, and then the values of the three items. The addition value S is compared with the determination reference value to predict the extraction phenomenon of the blast furnace 10 through the determination step 400 of determining that the extraction phenomenon.

The upper breathable resistance index and the lower breathable resistance index rises before the extraction, and the central breathable resistance index decreases.

The cause of the extraction phenomenon is due to various reasons, after the void region is formed in the blast furnace 10, the void region rises when the upper charge of the void region falls freely, the void region rises to the top, and then the normal charge filling layer A higher porosity venting path is formed from the initial pore region generation point to the top of the road, and as the gas in the furnace is concentrated in this path, the gas flow rate increases and eventually develops into a phenomena.

When the void region rises from the point of occurrence to the top, when the isobar pressure line is drawn, it can be seen that the isobar pressure line is concentrated on the upper portion of the pore region along the path of the pore region rise, and the gap between the isobar lines is far from the middle portion.

If we draw the pressure change according to the height in the pore region upward path as the pore region rises, it can be seen that the upper permeability resistance index increases and the central permeability resistance index decreases. The lower breathable resistance index is increased relative to the decrease in the central breathable resistance index.

The weights are divided by dividing the degree of the upper breathable resistance index, the middle breathable resistance index, the lower breathable resistance index to the extraction phenomenon when the sum of the three weights based on 100.

For example, the first weight of the upper breathable resistance index is 30, the second weight of the middle breathable resistance index is 30, and the third weight of the lower breathable resistance index is 40.

The first, second, and third weights may all be equally distributed to the same value, but since the lower predictive time in the blast furnace 10 is faster and greatly affects the extraction phenomenon, the size of the third weight of the lower breathability resistance index Is set relatively large.

In addition, the determination reference value may be set differently according to each weight. For example, when the first weight is 30, the second weight is 30, and the third weight is 40, it is 60.

In the determining step 400, when the sum value S obtained by multiplying the upper item index value, the central item index value, and the lower item index value by each weight and adding the values of the three items is equal to or greater than the determination reference value, It is to inform the worker of the occurrence.

When the sum value S is less than the determination reference value, the ventilation resistance index calculation step 100, the distribution ratio output step 200, the item index value calculation step 300, and the determination step 400 are repeated. Will be.

In the present invention, in determining the extraction phenomenon, the upper breathability resistance index before the extraction phenomenon is increased and the central breathability resistance index is reduced, and the increase and decrease amount is accurately grasped through the distribution ratio calculation.

The present invention, in determining the extraction phenomenon, by predicting by using the distribution ratio of the upper breathable resistance index, the middle breathable resistance index, the lower breathable resistance index and the upper breathable resistance index, the middle breathable resistance index, the lower breathable resistance index, respectively, The number of items needed for this process is greatly reduced, so the calculation process is simple and accurate and fast prediction is possible.

The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the gist of the present invention, which is understood to be included in the configuration of the present invention.

10: blast furnace 20: blower
30: pressure detection stage 100: ventilation resistance index calculation step
200: distribution ratio output step 300: item index value calculation step
400: judgment step

Claims (3)

A ventilation resistance index calculation step of calculating the ventilation resistance index by the pressure measured at the pressures in the upper, middle, and lower parts of the blast furnace;
A distribution ratio output step of outputting, in real time, distribution ratios of an upper ventilation resistance index, a middle ventilation resistance index, and a lower ventilation resistance index calculated by the ventilation resistance index calculation step;
An item index value calculation step of calculating an hourly rate of change of the distribution ratio average value for a predetermined time before the reference time point of the distribution ratio of the upper ventilation resistance index, the distribution ratio of the central ventilation resistance index, and the distribution ratio of the lower ventilation resistance index outputted in the distribution ratio output step;
A determination step of determining that the phenomenon is a drought based on the sum of the three item values after multiplying each of the upper item index value, the central item index value, and the lower item index value calculated by the item index value calculating step. Precipitation phenomenon of blast furnace characterized by including. The method according to claim 1,
The item index value calculation step,
A method for predicting the occurrence of blast furnace blast furnaces comprising calculating the value of each item index by subtracting the hourly rate of change of the average distribution rate per long time period before the reference point longer than the short time period from the hourly rate of change of the average distribution rate for a short time before the reference time point. The method according to claim 1,
Wherein,
Inform the worker that a drooping phenomenon occurs when the sum value is greater than or equal to the judgment reference value.
And if the sum value is less than the determination reference value, the ventilation resistance index calculation step, the distribution ratio output step, the item index value calculation step, and the judgment step are repeated.

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