KR950010238B1 - Method of dragout thickness with blast f'ce wall - Google Patents

Abstract

The method for measuring the thickness of sticked materials improves the effeciency of the blast furnace operation by detecting growth or detachment of the sticked materials quantitatively. The measuring method comprises: (A) obtaining the correlationship between the sticked materials thickness and the thermacouple temperature; and (B) applying the measured thermocouple temperature of the blast furnace to the correlationship and calculating the thickness of the sticked materials.

Description

Method of measuring thickness of blast furnace furnace wall

1 is a schematic cross-sectional view showing a state in which the attachment is attached to the blast furnace wall edge.

2 is a graph showing the correlation between the furnace wall thickness and the thermocouple temperature according to the present invention.

3 is a graph showing the changes in the temperature of the furnace wall thermocouple in the chamber.

4 is a graph showing the change in deposit thickness with time variation measured according to the present invention.

The present invention relates to a method for measuring the thickness of the deposit formed on the furnace gyro, blast furnace furnace wall, and more specifically, from the correlation between the thickness of the deposit and the thermocouple temperature using temperature information of the thermocouple installed on the furnace wall. By quantitatively detecting the thickness of the deposit, it is possible to quantitatively grasp the growth or dropping of the deposit formed on the furnace wall, and to measure the thickness of the deposit on the blast furnace wall to facilitate the management of the furnace body and the blast furnace operation. It is about a method.

Generally, as shown in FIG. 1, ore powder, coke powder 4, a rolled material, etc. which remain in a furnace adhere to the blast furnace wall edge 2, and the deposit 3 is formed. These deposits affect the distribution of the gas in the furnace and the stability of the furnace, and thus detect the furnace wall deposits. As a conventional method for detecting such an attachment, there is a direct method by perforation, which is impossible to detect during operation, and there is a problem of damage to the furnace body.

Accordingly, Japanese Patent Publication No. 57-39288 proposes a method for determining the dropping of a deposit from a temperature change in which the furnace wall temperature measured by using a plurality of thermometers installed in the furnace stack is rapidly rising. 6888 proposes a method for determining the formation of deposits when the periodicity is lost by continuously measuring the temperature fluctuating periodically in response to the charging cycle of coke and ore.

However, in the prior art as described above, the temperature change of the thermocouple embedded in the furnace wall edge provides information for determining the formation and dropping of the deposit formed on the furnace wall edge, but it is possible to know how much the attachment is generated or dropped. There was a big problem of not being.

The present invention is to improve the conventional problems as described above, the object of the present invention is to quantitatively detect the thickness of the deposit from the correlation between the thickness of the deposit and the thermocouple temperature by using the temperature information of the thermocouple installed on the furnace wall edge. By doing so, it is possible to quantitatively grasp the growth or dropping of the deposits formed on the furnace wall, thereby providing a method for measuring the thickness of the blast furnace furnace wall that can smoothly perform the furnace management and blast furnace operation.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated.

The present invention comprises the steps of obtaining the maximum value (Tmax) and the minimum value (Tmin) of the furnace temperature using past actual measurement data; Obtaining a correlation between the thermocouple temperature and the deposit thickness for each of the maximum value Tmax and the minimum value Tmin of the furnace temperature obtained above; Continuously measure the thermocouple temperature (Tc) using a thermocouple, observe the change over time of the thermocouple temperature, it is determined that the furnace wall attachment is formed when the thermocouple temperature decreases, the furnace wall attachment thickness (Lo) at this time Setting zero to zero; The maximum thickness Tcmax and minimum value of the thermocouple temperature are substituted by substituting the above-described deposit thickness Lo for the correlation between the thermocouple temperature and the deposit thickness for the maximum value Tmax and the minimum value Tmin of the furnace temperature. Calculating Tcmin); Calculating the deposit thickness Lo as the deposit thickness L when the measured thermocouple temperature is between the maximum value Tcmax and the minimum value Tcmin of the obtained thermocouple temperature; If the measured thermocouple temperature (Tc) is higher than the maximum value (Tcmax) of the thermocouple temperature obtained above, substitute the thermocouple temperature and the thickness of the deposit with respect to the maximum value (Tmax) of the furnace temperature obtained above. Calculating the thickness L; If the measured thermocouple temperature (Tc) is lower than the minimum value (Tcmin) of the obtained thermocouple temperature (Tcmin), by substituting the correlation between the thermocouple temperature and the deposit thickness to the minimum value (Tmin) of the furnace temperature obtained above Calculating the thickness L; And obtaining the maximum value Tcmax and the minimum value Tcmin of the thermocouple temperature with respect to the deposit thickness L calculated above, and then calculating the deposit thickness L through the subsequent steps described above. It relates to a method for measuring the thickness of the blast furnace furnace wall.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail.

In order to measure the deposit thickness of the blast furnace wall according to the present invention, first, the maximum value (Tmax) and the minimum value (Tmin) of the temperature in the furnace are obtained using past actual measurement data.

The temperature in the furnace can be measured by inserting a temperature sensor, Sonde, into the furnace.

Next, the correlation between the thermocouple temperature and the deposit thickness of the furnace wall is obtained for each of the maximum value Tmax and the minimum value Tmin of the furnace temperature determined above using past actual measurement data.

The correlation between the thermocouple temperature and the furnace wall edge and thickness is determined by the general thermal conductivity analysis method by changing the thickness (L) of the lead by a small thickness (dL), and then at the thermocouple position according to the lead thickness. It is obtained by showing the temperature of.

Of course, in the present invention, the correlation between the thermocouple temperature and the thickness of the furnace wall deposit is not obtained only by the above method.

Next, the thermocouple temperature Tc is continuously measured with a thermocouple.

It is determined that the furnace wall attachment is formed when the thermocouple temperature decreases by observing the change over time of the thermocouple temperature continuously measured, and the furnace wall attachment thickness Lo at this time is set to zero.

Next, the above-described furnace wall deposit thickness Lo is substituted into the thermocouple temperature by substituting the correlation between the thermocouple temperature Tc and the furnace wall deposit thickness for each of the maximum value Tmax and minimum value Tmin of the furnace temperature obtained above. The maximum value Tcmax and minimum value Tcmin of are computed.

Next, when the measured thermocouple temperature Tc is between the maximum value Tcmax and the minimum value Tcmin of the thermocouple temperature obtained as described above, the above-described furnace wall deposit thickness Lo is converted into the furnace wall deposit thickness L. do.

Next, in the case where the thermocouple temperature Tc measured as described above is higher than the maximum value Tcmax of the thermocouple temperature obtained above, the correlation between the thermocouple temperature and the furnace wall attachment thickness with respect to the maximum value Tmax of the furnace temperature obtained above. It substitutes into and calculates furnace wall deposit thickness L. FIG.

On the other hand, if the thermocouple temperature (Tc) measured as described above is lower than the minimum value (Tcmin) of the thermocouple temperature obtained above, the correlation between the thermocouple temperature and the thickness of the furnace wall attachment to the minimum value (Tmin) of the furnace temperature obtained above. Substituting to calculate the furnace wall deposit thickness (L).

Next, the maximum value (Tcmax) and the minimum value (Tcmim) of the thermocouple temperature with respect to the furnace wall deposit thickness (L) calculated above are obtained, and then the furnace wall deposit thickness (L) is measured through the above-described steps.

Hereinafter, the present invention will be described in detail through examples.

EXAMPLE

The change in the thickness of the furnace wall deposits with time in the belly portion of the blast furnace having a furnace wall thickness of 600 mm was measured according to the present invention method.

The furnace temperature of the blast furnace used in this experiment was the maximum value (Tmax) of 1200 ℃, the minimum value (Tmin) of 800 ℃.

In this experiment, the correlation between the thermocouple temperature and the furnace wall thickness for each of the maximum (Tmax) and minimum (Tmin) of the furnace temperature is shown in FIG. And the maximum value (Tcmax) and minimum value (Tcmin) of the thermocouple temperature between 0-1 days were 120 degreeC and 91 degreeC, respectively.

And the thermocouple temperature (Tc) was measured as in FIG. Substituting the thermocouple temperature values up to 0-1 in Fig. 2 to obtain the furnace wall thickness, the results are shown in Fig. 4, and this process was repeated up to 15 days. Was measured.

As shown in Figure 4, it is possible to know quantitatively how much of the wall attachment is produced and dropped.

As described above, according to the method for measuring the deposit thickness of the blast furnace furnace wall according to the present invention, the thickness of the deposit is quantitatively detected from the correlation between the deposit thickness and the thermocouple temperature by using the temperature information of the thermocouple installed on the furnace wall edge. In addition, it is possible to quantitatively grasp the growth or dropping of the deposits formed on the furnace wall, thereby managing the furnace body and blast furnace operation smoothly, and has an excellent effect of further extending the life of the blast furnace.

Claims (1)

Obtaining maximum (Tmax) and minimum (Tmin) of the furnace temperature using past actual measurement data; Obtaining a correlation between the thermocouple temperature and the deposit thickness for each of the maximum (Tmax) and minimum (Tmin) values of the furnace temperature obtained above; continuously measuring the thermocouple temperature (Tc) using a thermocouple, and measuring the time of the thermocouple temperature. Determining the change in the thermocouple temperature to determine when the furnace wall deposits are formed, and setting the furnace wall deposit thickness Lo at this time to zero (Zero); The maximum thickness Tcmax and minimum value of the thermocouple temperature are substituted by substituting the above-described deposit thickness Lo for the correlation between the thermocouple temperature and the deposit thickness for the maximum value Tmax and the minimum value Tmin of the furnace temperature. Calculating Tcmin); Calculating the deposit thickness (Lo) as the deposit thickness (L) when the measured thermocouple temperature is between the maximum value (Tcmax) and the minimum value (Tcmin) of the obtained thermocouple temperature; If the measured thermocouple temperature (Tc) is higher than the maximum value (Tcmax) of the thermocouple temperature determined as described above, substitute the deposit by substituting the correlation between the thermocouple temperature and the deposit thickness for the maximum value (Tmax) of the furnace temperature obtained above. Calculating the thickness L; If the measured thermocouple temperature (Tc) is lower than the minimum value (Tcmin) of the obtained thermocouple temperature (Tcmin), by substituting the correlation between the thermocouple temperature and the deposit thickness to the minimum value (Tmin) of the furnace temperature obtained above Calculating the thickness L; And obtaining the maximum value (Tcmax) and the minimum value (Tcmin) of the thermocouple temperature with respect to the deposit thickness (L) calculated above, and then calculating the deposit thickness (L) through the subsequent steps described above. Method of measuring the thickness of the blast furnace wall.