KR20000026875A - Method for continuously detecting deterioration of stamp material on lower part of furnace - Google Patents

Abstract

The present invention relates to a method for detecting a phenomenon in which a refractory stamping material installed in a furnace section, which is a place for storing molten iron and slag of a blast furnace, deteriorates due to oxidative action due to a high temperature heat load as the number of operating years passes. The first thermocouple 25 is installed at the carbon edge and the intermediate portion at the portion, and the second thermocouple 26 is disposed at the contact portion between the carbon edge and the outside and the inside of the stamp material layer, and the third thermocouple (27) at the contact surface between the outside of the stamp material layer and the inner surface of the steel shell. ), The temperature is measured through these thermocouples, the thermal conductivity of the stamping material layer is calculated using the relationship between the amount of heat flow and the temperature measured by the second and third thermocouples, and the theoretical thermal conductivity in the bottom wall side layer The deterioration degree of the stamp material layer is determined by comparing the calculated thermal conductivity values of the line and the stamp material layer.

According to the present invention, the deterioration state of the nodger stamp material layer can be monitored in time series under normal conditions so as to best manage the cooling conditions of the notch side wall portion, and the integrity of the bottom edge can be ensured to extend the blast furnace life.

Description

Continuous detection method of deterioration status of stamping material

The present invention relates to a method for detecting a phenomenon in which the refractory stamping material installed in the bottom part, which is a place for storing molten iron and slag of a blast furnace, is degraded by oxidation due to a high heat load as the number of operating years passes. The deterioration state of the nosing stamp material layer can be monitored in time series under normal conditions to best manage the cooling conditions of the nosers side wall part, and the deterioration state of the nosing stamp material material which can extend the blast furnace life by securing the integrity of the nosers edges. To a sensing method.

In general, the blast furnace operation, as shown in Fig. 1, charges a charge, such as iron ore (1) and coke (2) from the top of the blast furnace into the furnace and blows hot hot air through the tuyere (6) installed in the furnace bottom to reduce in the furnace The molten reaction produces molten iron and slag.

The produced melt is stored in the bottom part 8 through the core coke layer 7 filled in the bottom part 8, and is discharged to the outside during the opening of the blast furnace exit.

As described above, the bottom portion 8 storing the hot molten iron and the slag 4 is coated with the outer shell 12 and the carbon lead 10 and mullite, which are orthogonal refractory materials, are coated on the inside thereof. The lead 9 is provided and has a structure in which a stamp material layer 11, which is an amorphous refractory material, is filled in order to improve thermal conductivity between the iron shell 12 and the carbon lead 10.

Since the nos carbon bond 10 is in contact with hot molten iron and slag 4 of 1500 ° C. or more, the stamping material layer 11 is formed by volatilization and air holes of volatile components in the stamp material under a temperature of 400 ° C. or more transmitted from the inner carbon smoke. Deterioration and damage are caused by the oxidation reaction of oxygen and carbon components introduced from 6).

When the void stamp material layer 11 is deteriorated and voids are generated between the shell 12 and the carbon lead 10, the high temperature heat transferred from the inner carbon lead 10 to the surface of the shell 12. As shown in FIG. 3, since the cooling capacity of the bottom edge duct cooled by the coolant 20 is lowered, the inner carbon tail 10 increases in thermal load, resulting in rapid damage, and as a result, a blast furnace failure or the like. Therefore, it has a fatal effect on the lifetime.

As a conventional method of checking the damage state of the bottom part stamping material layer 11, there are three methods largely.

The first is a method of measuring during blast furnace operation, and is estimated from the abnormal rise of the temperature of the thermocouple (13) installed in the carbon lead 10 of the bottom 8 as shown in FIG.

Next, after stopping the spraying of the coolant 20 cooling the surface of the shell 12 while the blast furnace is at rest, using a non-contact temperature sensing mechanism to determine the surface temperature of the shell 12 to determine or determine the shell Drilling is to visually check the state of the stamp material layer.

When the damage to the stamping material layer 11 is confirmed by using a combination of these methods, the bottom part of the damaged part in the state where the blast furnace is idle in order to refill the voids of the stamping material layer to regain a good heat transfer condition (12) ) Indentation nipple is installed on the surface and the filler is refilled with carbon paste, which is an amorphous refractory material, using an indenter.

However, according to the conventional method as described above, the deterioration state of the stamp material layer 11 could be detected through direct investigation, such as drilling the steel bar while the blast furnace is idle for repair, rather than under normal operating conditions. Therefore, there existed various problems, such as the systematic quantitative management of the blast furnace bottom part 8 being difficult.

That is, the method of detecting the deterioration state of the outer stamp material layer 11 using the thermocouple, under the premise that the sprinkling state of the coolant 20 cooling the outside of the outer shell 12 is normal and the thermocouple temperature sensing capability is normal. It is difficult to quantitatively evaluate the deterioration state of the stamp material layer because it is an empirical estimation method from the temperature distribution state of the thermocouple, and there was a big difference in the prediction result according to the skill of the operator who judges the deterioration degree from the thermocouple temperature information.

Next, the method for detecting the degree of deterioration of the stamp material layer using the non-contact metal shell temperature detection mechanism is the method of detecting the stamp material layer using only the peeling temperature because the temperature of the shell material varies according to the elapsed cooling water sprinkling stop time and the remaining thickness of the low carbon carbon crack. It is difficult to quantitatively evaluate the remaining thickness.

In addition, the method of measuring the degree of deterioration of the stamp material layer by drilling the bottom bark and stamp material layer was difficult to apply universally to operators because it can be used only in the idle state, and it is necessary to perform the drilling work and welding work. There was a problem of excessive time.

The present invention has been made to solve the problems of the prior art described above, continuous detection of deterioration state of the bottom portion stamping material using a contact thermocouple to detect the deterioration state of the stamping material by detecting the thermal conductivity change state of the refractory having the intrinsic thermal conductivity characteristics The purpose is to provide a method.

1 is a cross-sectional view showing a blast furnace structure,

2 is an enlarged view of a portion A of FIG. 1;

3 is a view for showing a thermocouple installation configuration for measuring the degree of degradation of the conventional stamper layer;

4 is a view showing a thermocouple installed to measure the degree of deterioration of the bottom stamp material layer according to the present invention,

5 is a view showing the heat flow in the furnace side wall portion for showing the principle of the present invention,

6 is a view showing a correlation between a calculated thermal conductivity and a deterioration state of a stamp material layer,

7 is a flowchart for explaining a method for detecting a deteriorated state of a bottom wall portion stamping material layer of the present invention.

<Explanation of symbols for main parts of drawing>

10: carbon lead 11: stamp material layer 12: shell

25, 26, 27: thermocouple

In the continuous state detection method of the bottom portion stamping material of the present invention for achieving the above object, the first thermocouple is installed in the carbon edge and the middle portion of the furnace side wall portion of the blast furnace, and the second thermocouple at the contact portion between the carbon edge and the outside and the inside of the stamp material layer And installing a third thermocouple on the contact surface between the outer side of the stamping layer and the inner surface of the steel bar, measuring the temperature through these thermocouples, and using the relationship between the amount of heat flow and the temperature measured by the second and third thermocouples. The thermal conductivity is obtained, and the deterioration degree of the stamping material layer is determined by comparing the calculated thermal conductivity values of the stamping material layer with the theoretical thermal conductivity lines in the sidewall part layer of the furnace.

The invention will now be described in detail with reference to the accompanying drawings, in which preferred embodiments are shown.

In the present invention, as shown in Figure 4, the thermocouples (25, 26, 27) are installed in the triple twist in the furnace side wall portion, the first thermocouple 25 is installed in the middle portion in the furnace side wall carbon lead 10 The second thermocouple 26 is provided at the contact portion between the carbon edge 10 outside and the stamp material layer 11 inside, and the third thermocouple 27 is between the stamp material layer 11 outside and the inner surface of the metal shell 12. Install in between.

The present invention has been made with the attention that heat transfer conditions in the refractory combination cylindrical device combined with the carbon lead 10 and the stamp material layer 11 as shown in Fig. 5 are determined as follows.

Q = H _j (2Π ₁ L) (T _i -T ₁ ) .......... (1)

Where Q is the theoretical heat flux, h _i is the heat transfer coefficient of the molten iron, k ₁ , k ₂ is the carbon conductivity (10) and the thermal conductivity of the stamp material layer (11). Where L is the thickness of the carbon lead and the stamp material layer, and T ₁ , T ₂ , and T ₃ are the temperatures measured at the first, second, and third thermocouples 25, 26, and 27, respectively, and T _i is the temperature of the molten iron, r _1, r _2, r ₃ is the distance from the first, second, third thermocouple from the center nojeo.

FIG. 6 illustrates a correlation between the theoretical thermal conductivity line and the stamp material layer deterioration degree for quantitatively determining the degree of deterioration of the stamp material layer 11 in the side wall of the furnace, and applying the calculated thermal conductivity value of the stamp material layer to the stamp material layer. The degree of deterioration can be determined quantitatively.

The deterioration state continuous detection method of the bottom part stamping material of this invention is demonstrated with reference to FIG.

During the operation of the blast furnace, the temperature is sensed through the triple thermocouples 25, 26 and 27 attached to the furnace side wall and transmitted to a blast furnace control device such as a host computer that controls the blast furnace in real time. .

In a blast furnace control device such as a host computer, the average heat flow amount per unit area of the side wall of the furnace is calculated using Equation (1) according to the programmed contents.

Subsequently, the second, third and third thermocouples are theoretically calculated using the heat flow amount Q, equations (2) and (3), and then the first, second and third thermocouples 25, 26 and 27 are replaced. Check the adequacy of the measured temperature.

Next, the calculated thermal conductivity value of the stamping material layer 11 is derived using the relationship between the heat flow amount Q and the temperature T ₂ , T ₃ of the formula (3).

Finally, the degree of degradation of the stamping material layer is quantitatively determined by comparing the calculated thermal conductivity value with the correlation between the theoretical thermal conductivity line and the degree of degradation of the stamp layer in the stamp layer of the side wall portion as shown in FIG.

Hereinafter will be described the operation of the degradation state continuous detection method of the bottom portion stamping material of the present invention configured as described above.

In the present invention, the calculated thermal conductivity of the stamp material layer 11 is the temperature T ₂ and the stamp material layer 11 measured through the second thermocouple 26 representing the temperature at the interface between the carbon lead 10 and the stamp material layer 11. And the temperature T ₃ measured through the third thermocouple 27 representing the temperature between the shell 12 and the shell 12.

Quantitative evaluation of the deterioration of the stamp material layer is made by comparing the calculated thermal conductivity values with the theoretical thermal conductivity curves.

In particular, when a large amount of space is formed in the stamp material layer 11 due to deterioration of the stamp material layer, the heat transfer capacity from the stamp material layer to the outer shell 12 is lowered, thereby lowering the cooling ability of the furnace sidewall portion by the coolant flowing through the surface of the bottom shell. The temperature T ₁ , T ₂ measured through the first and second thermocouples 25 and 26 increases and the temperature T ₃ measured through the third thermocouple 27 decreases.

In addition, the first and second thermocouples 25 and 26 installed in the carbon edge 10 inside the side wall of the furnace have the second and third thermocouples 26 and 27 not only in calculating the residual thickness of the carbon edge but also in the heat transfer conditions. It was also useful as a means of confirming the reliability of the measured temperature.

Therefore, according to the present invention as described above, since the deterioration state of the nosed side wall portion stamping material layer can be quantitatively detected during normal operation, the deterioration state of the nosing stamping material layer can be monitored in time series under normal operating conditions, Operators can easily detect changes in cooling conditions during normal operation to best manage the cooling conditions of the side wall of the furnace.In addition, the sidewall carbon lead can be prematurely coped with erosion and abrasion from the increase in heat load of the side wall due to the decrease in the cooling capacity of the furnace. It is possible to obtain useful effects, such as ensuring the integrity of the furnace bottom edge and extending the life of the blast furnace.

Claims (1)

In the furnace side wall part of the blast furnace, the first thermocouple is installed at the carbon edge and the middle part, the second thermocouple is installed at the contact portion between the carbon edge and the outside and the inside of the stamping layer, and the third thermocouple is installed at the contact surface between the outside of the stamping layer and the inner surface of the steel shell, These thermocouples measure the temperature, The thermal conductivity of the stamp material layer is obtained by using the relationship between the heat flow rate and the temperature measured through the second and third thermocouples. A method of continuously detecting deterioration of a stamping material of a bottom portion of a stamping material, characterized in that the deterioration degree of the stamping material layer is determined by comparing a calculated thermal conductivity value of the stamping material layer with a theoretical thermal conductivity line in the bottom wall side layer.