KR101008064B1 - An apparatus for detecting drop of inner adherents of a hot furnace - Google Patents

Abstract

The present invention relates to a furnace attachment drop detection device of the blast furnace to enable the driver to take appropriate measures in advance by foreseeing and detecting the fall of the furnace wall attachment, which is one of the abnormal conditions of the blast furnace in the blast furnace.

The present invention, in the furnace furnace attachment detection detection device of the blast furnace equipped with a plurality of flue thermometers for detecting the blast furnace furnace temperature and a plurality of drain thermometers for detecting the drainage temperature of the furnace cooling water, each of the blast furnace thermometer according to the cycle set in the For the detected temperature values T and the plurality of drainage thermometers according to the set periods, the detected temperature values A and F are respectively detected between the current period and the nth time period. First and second storage units respectively storing; Among the detected temperature values A and F stored in the first and third storage units, an average value B of the detected temperature values between the m-th time period and the n-th time period, respectively, is obtained. First and second average calculation units for calculating the respective average values; The difference value between each temperature value (T) (E) detected in the current period for each of the smoke thermometer and each drain thermometer, the average value (B) of the first average calculation unit, and the average value (G) of the second average calculation unit (C) first and second calculating units for calculating (H), respectively; First and second comparison units for comparing the resultant temperature values C and H in the first and third calculators with sizes of the first and second preset temperature values D and I, respectively; And each of the resultant temperature values C and H is respectively set for the at least one flue thermometer and the at least one drainage thermometer as a result of the comparison in the first and third comparison units. If the temperature value (D) (I) or more includes the first and second wall determination judging to determine the occurrence of the wall.

According to the present invention, by judging whether or not the wall force generation, such as the fall of the furnace wall attachments in the blast furnace can be judged regularly, it is possible to reduce the misjudgment rate due to the determination of wall rock occurrence, it is possible to accurately predict whether the occurrence of wall rock in advance, so that in advance in the appropriate action in case of abnormality It can be taken and can stabilize the yellowing.

Blast furnace, attachment, dropout, smoke thermometer, drain thermometer, wall rack

Description

AN APPARATUS FOR DETECTING DROP OF INNER ADHERENTS OF A HOT FURNACE}

1 is a position view of a conventional blast furnace operation detection member.

2 (a) is a plan view of the blast furnace inside of FIG.

FIG. 2 (b) is a schematic view of the blast furnace inner wall unfolded after virtually cutting at a 180 ° point in FIG. 2 (a).

3 is a functional block diagram of the configuration of the furnace attachment drop detection device according to an embodiment of the present invention.

Figure 4 is a functional block diagram according to another embodiment of the configuration of the furnace attachment drop detection device of the present invention.

Figure 5 is a functional block diagram according to another embodiment of the configuration of the furnace attachment drop detection device of the present invention.

 Description of protection for the main parts of the drawing

s11 to s48: ductility thermometer a11 to a84: drainage thermometer

301,307,314: 1,2,3 storage unit 302,308,313,314: 1,2,3,4 average calculation unit

303,309,316: 1,2,3 calculation unit 304,310,317: 1,2,3 comparison unit

305,311: First and second wall panel decision part 306,312: First and second OR gate

The present invention relates to an apparatus for detecting a dropout attachment in a blast furnace, and more particularly, to predict and detect a dropout of a furnace wall attachment, which is one of abnormal conditions of a blast furnace, so that the driver can take appropriate measures in advance. The present invention relates to an apparatus for detecting attachment failure of a blast furnace.

The blast furnace is charged with iron ore and coke in alternating succession, and blows hot air of high temperature (1100 ℃) to melt it at a constant pressure (for example, 2.6 Kg / ㎠ for the first blast furnace). The difference in the rate at which ore melts, that is, the rate of reduction melting, is caused by various variables such as the fusion state of the internal melt and the direction of gas flow in the furnace. A phenomenon in which the deposit (for example, the fusion of the ore) instantly falls off (called 'walling') occurs. When wall occurs, it causes fluctuations in wind pressure and deterioration of the furnace.

In order to determine such a wall condition, the driver generally monitors the fluctuations of various operation indexes in the furnace to determine the flow of the gas in the furnace, the condition of the yellowing and the occurrence of wall rock. A detection member for detecting such various operation indices is shown in FIG.

1 is a position view of a conventional blast furnace operation detection member. As illustrated in FIG. 1, a wind pressure detector 12 that detects a wind pressure of hot air supplied into the blast furnace 10, and a plurality of smoke thermometers 110 to 140 that measure the temperature of the refractory bricks, ie, the edibles, which are built in the blast furnace. ), Using a plurality of drain thermometers (210 ~ 280) for measuring the drainage temperature of the cooling water for the cooling of the furnace body to detect the operation index, such as wind pressure change, flue temperature change, and drainage temperature change of the coolant. The duct heating thermometer (110 ~ 140) is composed of four stages (110, 120, 130, 140) up and down, each stage has eight thermometers (110: s11 ~ s18, 120: s21 ~ 28, 130: s31 ~ 38, in the circumferential direction of the blast furnace) 140: s41 to 48 are installed so that a total of 32 (= 4 x 8) duct thermometers 110 to 140 measure the duct temperature at each position in the circumferential direction of the blast furnace 10, respectively. In addition, the drain thermometer (210 ~ 280) is composed of eight stages (210,220,230,240,250,260,270,280) up and down, each stage has four thermometers (210: a11 ~ a14, 220: a21 ~ 24, 230: a31 ~ in the circumferential direction of the blast furnace) 34, 240: a41 ~ 44, 250: a51 ~ 54, 260: a61 ~ 64, 270: a71 ~ 74,280: a81 ~ 84 are installed, so 32 drain thermometers (210 ~ 280) are installed on the circumference of the blast furnace 10. Measure the drainage temperature of the coolant at each position in the direction.

FIG. 2 (a) is a plan view of the blast furnace inside of FIG. 1, which briefly illustrates the position of the eddy furnace thermometers s11 to 48. As shown in FIG. As shown in Figure 2 (a), a total of 32 smoke swivel thermometers (s11 ~ 48) are preferably arranged symmetrically in the circumferential direction of the blast furnace 10, which consists of four stages each up and down. FIG. 2 (b) shows the blast furnace inner wall unfolded after virtually cutting the blast furnace at a point of 180 ° in FIG. 2 (a). 2 (b) shows the positions of the ductility thermometers s11 to s48 and the drainage thermometers a11 to a84.                         

As described above, in order to detect the operation index during the blast furnace operation, the edging thermometer and the drainage thermometer are arranged as shown in FIGS. 1, 2 (a) and 2 (b), respectively, to change the duct temperature of the furnace wall and the drainage of the cooling water. The temperature change was detected, and the driver monitors the fluctuations of the detected work index as a whole to arbitrarily determine the bleeding state and the dropout of the inside of the furnace.

However, in the case of such conventional wall detection, there is no standard to quantitatively determine whether or not the occurrence of wall rock is determined by the driver's own experience, so that the wrong decision rate is high and the measures caused by such error cause the instability of the yellowing. There was a problem. Therefore, in the art, it is necessary to detect a dropout in the furnace in advance by using the operation index detected by the plurality of smoke thermometers and drainage thermometers as described above, but to accurately predict the need for an apparatus.

The present invention, as described above, is to solve the problem that the misjudgment rate increases due to the driver's experience in determining whether or not the wallbreak occurs during the blast furnace operation, thereby causing instability in the yellowing, If the difference between the current detected temperature value and the average temperature value from 1 hour ago to 2 hours ago is higher than the first set value among any of the temperature values detected at the intervals set by the thermometer and the drainage thermometer, it is detected as a wall fault. When the difference between the average temperature value of the smoke vortex thermometer and the average temperature value from 1 hour ago to 2 hours ago is more than the second set value, it detects that it is a wall lock, thereby providing an apparatus for detecting the attachment of the furnace in which the occurrence of wall rock is quantitatively determined. The purpose is.

The furnace attachment drop detection device of the blast furnace according to the present invention for achieving the above object, the blast furnace attachment detection of the blast furnace installed a plurality of smoke thermometers for detecting the blast furnace furnace temperature and a plurality of drain thermometers for detecting the drainage temperature of the furnace cooling water. In the device,

Between the current value from the current period and the nth time period for each of the temperature value T detected according to the periods set in the plurality of smoke thermometers and the temperature value E detected in the plurality of drainage thermometers according to the set periods, respectively. First and second storage units for storing the detected temperature values A and F, respectively; Average value (B) of the detected temperature values between the m-th time period before the mth time period to the nth (n> m) time period from the current period among the detection temperature values A and F stored in the first and second storage units, respectively. First and second average calculation unit for calculating (G), respectively; The difference value between each temperature value (T) (E) detected in the current period for each of the smoke thermometer and each drain thermometer, the average value (B) of the first average calculation unit, and the average value (G) of the second average calculation unit (C) first and second calculating units for calculating (H), respectively; First and second comparison units for comparing the resultant temperature values C and H in the first and second calculators with sizes of the first and second preset temperature values D and I, respectively; And each of the resultant temperature values C and H is respectively set for the at least one flue thermometer and the at least one drainage thermometer as a result of the comparison in the first and second comparators. If it is more than the temperature value (D) (I), it includes the 1st and 2nd wall deciding part judged as a wall-break generation, respectively.

Here, in one embodiment of the present invention, the apparatus for detecting a drop in the furnace of the blast furnace, the third average calculation unit for calculating the average value (Q) of the temperature value (T) detected each time in the plurality of smoke thermometers; A third storage unit for storing an average value R between the current period and the nth time period before the average value Q each time calculated by the third average calculation unit 313; A fourth average calculating unit configured to calculate an average value S of the average value R stored between the m-th time period to the nth time-period period from the current period among the average values R stored in the third storage unit; A third calculating unit calculating a difference value U of the average value S calculated by the fourth average calculating unit from the average value T calculated in the current period by the third average calculating unit; And comparing the magnitude of the difference value U calculated by the third calculating unit with a preset third set temperature value W, and if the difference value U is equal to or greater than the third set temperature value W, walling occurs. The third comparison unit may further include a notification.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail the present invention. In the accompanying drawings of the present invention, components having substantially the same configuration and function will use the same reference numerals.

3 is a functional block diagram of the configuration of the furnace attachment drop detection device according to an embodiment of the present invention. As shown in FIG. 3, the apparatus for detecting attachment dropout of a blast furnace according to an embodiment of the present invention uses a plurality of smoke thermometers 110 to 140 shown in FIG. 1. Since the arrangement and function of the duct thermometers 110 to 140: s11 to s48 applied to the furnace attachment drop detection device of the blast furnace according to the present invention are the same as described above, the description thereof will be omitted.                     

In addition, in FIG. 3, the process of detecting the drop out of the furnace attachment, that is, the occurrence of wall rock, is illustrated for the eight ductile thermometers s11 to 18 positioned in the first stage 110. The same applies to the eight smoke thermometers s21 to 28, s31 to 38, and s41 to 48 located at 120, 130 and 140, respectively. Therefore, in FIG. 3, only eight smoke thermometers s11 to 18 located in the first stage 110 will be described.

Referring to FIG. 3, the temperature values T11 to T18 respectively detected from the eight smoke thermometers s11 to s18 installed in the first stage 110 may correspond to the corresponding analog / digital (A / D) converters 111. Through each input to the sensing device 300 according to the present invention. The sensing device 300 includes a microprocessor and a predetermined memory device. Preferably, the first storage unit 301 includes a first storage unit 301, a first average calculation unit 302, a first operation unit 303, a first comparison unit 304, and a first wall decision unit 305.

Each of the smoke thermometers s11 to s18 detects the temperature T at the smoke of the furnace body (shaft) at a set cycle. Preferably, the temperature is detected once per minute. However, such a cycle may of course vary depending on the working conditions. Each temperature value T detected according to the set period in each of the smoke thermometers s11 to s18 is input to the first storage unit 301 via each A / D converter 111. The first storage unit 301 stores the detected temperature value T from the current cycle to the set time, for example, two hours ago, for each smoke thermometer s11 to s18. In other words, the first storage unit 301 stores the temperature values detected for each of the smoke thermometers s11 to 18 during the period from the current cycle to the period two hours before. For example, when the temperature is detected once per minute in each of the smoke thermometers s11 to 18, the temperature is detected 60 times for 1 hour and 120 times for 2 hours. In this case, the first storage unit 301 stores 120 detection temperature values (A). The set time may also vary depending on the working conditions. The first storage unit 301 stores the detected temperature value A in a first-in first-out (FIFO) manner. More specifically, when a new detection temperature value is input from each of the smoke thermometers s11 to s18, the first storage unit 301 first detects the detected temperature value for each smoke thermometer s11 to s18. Deletes and stores the newly input detection temperature value. Therefore, the first storage unit 301 always stores a certain number of detected temperature values A even after elapse of time.

The first average calculation unit 302 detects a period between one hour before and two hours before the current period among the detected temperature values A stored in the first storage unit 301 for each of the smoke thermometers s11 to s18. The average value B with respect to a temperature value is computed.

The first calculator 303 subtracts the average value B of the detected temperature values of the corresponding smoke thermometers s11 to s18 from the temperature value T detected in the current period for each of the smoke thermometers s11 to s18 (C). Calculate That is, the average value of the detected temperature value during the period of 1 hour before to 2 hours calculated for each of the corresponding smoke thermometers (s11 to s18) from the detected temperature value (T) in the current cycle for each smoke thermometer (s11 to s18). Calculate the value (C) minus (B). For example, in the case of the first smoke thermometer (s11), the average value of the detected temperature values for the period 1 hour to 2 hours before the current cycle is B11, and the temperature detected at the present time by the first smoke thermometer (s11). Assuming that the value is T11, the first calculator 303 calculates (T11-B11).                     

The first comparison unit 304 compares the calculated result value C and the first set temperature value D of the first calculation unit 303 for each of the smoke thermometers s11 to s18, and outputs a comparison result. (O1 ~ o8) The first set temperature value D is set by the driver for each of the smoke thermometers s11 to s18. The first comparison unit 304 is a difference between the temperature value (T) detected in the current period for each smoke thermometer (s11 to s18) and the average value (B) of the temperature value detected between the period 1 hour ago and 2 hours ago. It is determined whether (C) is greater than the first set temperature value (D). In other words, it is to determine how much the temperature value T detected at the present time varies with the average value B of the temperature values detected between one hour ago and two hours ago. Here, as described above, the difference value C between the detected temperature value T in the current period and the detected temperature value between the period of 1 hour and 2 hours before the current period is set to the set value ( The reason for the comparison with D) is that since the gas, liquid and solid coexist in the blast furnace, the result is about 1 hour to 2 hours after taking any action. This is to check how much the current detection temperature value fluctuates with respect to the average value of the detection temperature in the previous period.

The first comparison unit 304 compares each of the smoke thermometers s11 to s18 and outputs the result to the first wall-making determination unit 305 (o1 to o8). The first wall deciding portion 305 includes an OR gate 306. As a result of the comparison of the first comparison unit 304, the first wall decision unit 305 sets the result value C of the first calculation unit 303 to the first setting unit 303 with respect to each of the edible thermometers s11 to s18. If any one of the flue thermometers s11 to s18 larger than the temperature value D exists, it is determined that the wall is generated and outputs it to the driver. By adjusting the first set temperature value (D) it is possible to detect the wall-breaking in advance. That is, the occurrence of the wall rock can be predicted in advance by adjusting the first set temperature value D so as to detect the sign of the wall rock occurrence in advance.

Figure 4 is a functional block diagram according to another embodiment of the configuration of the furnace attachment drop detection device of the present invention. As shown in FIG. 4, the apparatus for detecting a drop attachment in a furnace according to another embodiment of the present invention uses a plurality of drain thermometers 210 to 280 shown in FIG. 1. The arrangement and function of the drainage thermometers 210 to 280: a11 to a84 applied to the furnace attachment drop detection device of the blast furnace according to the present invention are the same as described above, and thus the description thereof will be omitted.

In FIG. 4, the process of detecting wall leakage occurs for the four drain thermometers a11 to 14 located in the first stage 210, but these processes are respectively located in the second to eighth stages 210 to 280. The same applies to the two drain thermometers (a21 to 24, a31 to 34, a41 to 44, a51 to 54, a61 to 64, a71 to 74, a81 to 84). Therefore, in FIG. 4, only four drainage thermometers a11 to 14 located in the first stage 210 will be described.

Referring to FIG. 4, the temperature values P detected from the four drainage thermometers a11 to s14 installed in the first stage 210 are provided in the present invention through the respective analog / digital (A / D) converters 211. Input to the sensing device 300 according to each. The sensing device 300 includes a microprocessor and a predetermined memory device. Preferably, the second storage unit 307 includes a second storage unit 307, a second average calculation unit 308, a third operation unit 309, a second comparison unit 310, and a second wall decision unit 311.

Each component shown in FIG. 4 is functionally the same as compared to each component shown in FIG. More specifically, the second storage unit 307, the second average calculation unit 308, the second operation unit 309, the second comparison unit 310, and the second wall determination unit illustrated in FIG. 4 ( 311 may include a first storage unit 301, a first average calculation unit 302, a first calculation unit 403, a first comparison unit 304, and a first wall decision unit 405 shown in FIG. 3, respectively. Performs the same function. However, if there is a difference, in the case of FIG. 3, the temperature value T detected by the eight smoke thermometers s11 to s18 installed at each of the four stages detects the occurrence of wall rock, but in the case of FIG. Detects wall occurrence by processing the temperature values (E) detected by the four drainage thermometers (a11 to a14) installed at each stage of.

Referring back to FIG. 4, each of the drainage thermometers a11 to a14 detects temperature values E11 to E14 in the cooling water of the furnace body (shaft), respectively. Preferably, the temperature is detected once per minute. Each temperature value E detected according to the set period in each of the drain thermometers a11 to a14 is input to the second storage unit 307 via the corresponding A / D converter 211. The second storage unit 307 stores the detected temperature value F for each of the drain thermometers a11 to a14 from a current period to a set time, for example, up to two hours ago. Similar to the second storage unit 301 of FIG. 3, the second storage unit 307 stores the detection temperature value F in a first-in first-out (FIFO) manner, so that a constant number of detection temperature values always exist even after elapse of time. Stored.

The second average calculation unit 308 detects a period between one cycle before the current cycle and two hours before the current cycle among the detected temperature values F stored in the second storage unit 307 for each of the drain thermometers a11 to a14. The average value G with respect to a temperature value is computed.                     

The second calculation unit 309 is a period of 1 hour ago to 2 hours ago calculated for each of the drain thermometers a11 to a14 from the detected temperature value E in the current cycle for each of the drain thermometers a11 to a14. Calculate the value (H) by subtracting the average value (G) of the detected temperature values.

The second comparison unit 310 compares the calculated result value H and the second set temperature value I of the second operation unit 309 for each of the drain thermometers a11 to a14 and outputs the result. (y1 ~ y4). The second comparison unit 310 is a mean value (G) of the temperature value (E) detected in the current cycle for each of the drain thermometer (a11 ~ a14) and the temperature value detected between the cycle of 1 hour ago to 2 hours ago It is determined whether the difference H is greater than the second set temperature value I. This is to determine how much the temperature value E detected in the current cycle is fluctuated compared to the average value G of the temperature values detected between the period 1 hour ago and the period 2 hours ago. The second comparison unit 310 compares each of the drain thermometers a11 to a14 and outputs the comparison result to the second wall determination unit 311 (y1 to y4). The second wall deciding portion 311 includes an OR gate 312. As a result of the comparison of the second comparison unit 310, the second wall decision unit 311 sets the result value H of the second operation unit 309 to the second drainage units a11 to a14. If any one of the drain thermometers a11 to a14 larger than the temperature value I exists, it is determined that the wall is generated and outputs it to the driver.

As described above, it is possible to detect in advance whether or not the wall is generated by using the detected temperature values E detected by the four drainage thermometers a11 to a14 installed at each stage. The detection of wall occurrence occurred in FIG. 4 is equally applied to the other stages 220, 230, 240, 250, 260, 270 and 280. That is, the same applies to the drain thermometers a21 to 24, a31 to 34, a41 to 44, a51 to 54, a61 to 64, a71 to 74, a81 to 84 at each stage. Therefore, the description of the wall occurrence detection process in the second to eighth steps will be omitted.

Figure 5 is a functional block diagram according to another embodiment of the configuration of the furnace attachment drop detection device of the present invention. As illustrated in FIG. 5, the apparatus for detecting dropout of the furnace in the blast furnace of the present invention uses a plurality of smoke thermometers 110 to 140 shown in FIG. 1. The arrangement and function of the ductility thermometers 110 to 140: s11 to s48 are the same as described above, and thus description thereof is omitted. In addition, in FIG. 5, the wall crack occurrence detection process is illustrated for the eight smoke thermometers s11 to 18 located in the first stage 110, but these processes are respectively located in the second, third, and fourth stages 120, 130, and 140. The same applies to dog smoke thermometers (s21 to 28, s31 to 38, and s41 to 48). Therefore, in FIG. 5, only eight smoke thermometers s11 to 18 positioned in the first stage 110 will be described.

Referring to FIG. 5, the temperature values T11 to T18 detected from the eight smoke thermometers s11 to s18 respectively installed in the first stage 110 may correspond to the corresponding analog / digital (A / D) converters 111. Through each input to the sensing device 300 according to the present invention. The sensing device 300 includes a microprocessor and a predetermined memory device. Preferably, a third average calculation unit 313, a third storage unit 314, a fourth average calculation unit 315, a third operation unit 316, and a third comparison unit 317 are included.

Referring to FIG. 5, the third average calculation unit 313 calculates an average value Q of the detected temperature values E11 to E18 according to a period set by each of the smoke thermometers s11 to s18. In more detail, each of the smoke thermometers s11 to s18 respectively detects the temperature at the set period. The third average calculation unit 313 receives the detected temperature values E11 to E18 in this way and calculates an average value Q according to the set period.

The third storage unit 314 is arranged between the periods of two hours before the current period, among the average values Q of the detected temperature values of the respective edible thermometers s11 to s18 calculated by the third average calculation unit 313 every cycle. The average value R of the calculated detection temperature values is stored. In other words, the third storage unit 314 stores the average value R of the temperature values detected for each period by the smoke thermometers s11 to 18 during the period from the current cycle to the period two hours before. For example, when detecting the temperature once per minute in each of the smoke thermometers s11 to 18, the third average calculation unit 313 calculates the average value Q of the detected temperature value 60 times for one hour. For 2 hours, the average value Q of the detected temperature value is calculated 120 times. In this case, the third storage unit 314 stores 120 average values (R). The third storage unit 314 also stores the average value R in a first-in first-out (FIFO) manner. That is, when the average value Q of the new detection temperature value is input from the third average calculation unit 313, the third storage unit 314 deletes the average value Q of the initially stored detection temperature value and inputs the new value. The average value Q of the detected detection temperature value is stored. Therefore, even if time passes, the third storage unit 314 always stores the average value R of a predetermined number of detected temperature values.

The fourth average calculating unit 315 calculates an average value S of the average value R between a period of 1 hour before and 2 hours before the current period among the average values R stored in the third storage unit 314. do.                     

The third calculation unit 316 may calculate the period 1 to 2 hours ago calculated by the fourth average calculation unit 315 from the average value Q of the detected temperature values of the current period calculated by the third average calculation unit 313. The value (U) is calculated by subtracting the average value (S) from the average value (R) of the detected temperature values between time periods. In other words, the total detected temperature of the smoke thermometers s11 to s18 stored for the period of 2 hours before the current cycle from the average value Q of the total detected temperature values of the smoke thermometers s11 to s18 in the current cycle. The value (U) is calculated by subtracting the average value (S) of the average value (R) stored for the period 1 hour ago to the period 2 hours before the average value (R) of the value.

The third comparison unit 317 compares the calculated result value U and the second set temperature value W of the third operation unit 316 to the result value U of the third operation unit 316. It is determined whether it is larger than the second set temperature value (W). This is because the average value Q of the temperature value detected by the softening thermometers s11 to s18 in the current cycle is compared with the average value S of the average detection temperature value R between the cycle of 1 hour ago and the cycle of 2 hours ago. It is to determine whether there is a change. As a result of the comparison of the third comparison unit 316, if the result value U of the third operation unit 316 is greater than the second set temperature value W, it is determined that wall-break occurs.

As described above, it is possible to detect in advance whether or not the wall is generated by using the detection temperature values T11 to T18 respectively detected by the eight smoke thermometers s11 to s18 installed at each stage. The detection process of the occurrence of the wall illustrated in FIG. 5 is equally applied to the other stages 120, 130, and 140. In other words, the same applies to the smoke pedometers s21 to s28, s31 to 38, and s41 to s48 at each stage. Therefore, the description of the procedure for detecting wall occurrence in the second, third, and fourth stages is omitted.

In the detailed description and drawings of the present invention, the furnace attachment drop detection device according to the present invention is limited to the flue thermometer installed in four stages in eight stages and the drainage thermometer installed in eight stages in four stages in the blast furnace. Although disclosed, this has described an embodiment of the present invention, the position and number of the edometer and the drain thermometer of the present invention may be variously changed. In addition, the set temperature value for determining whether the attachment inside the furnace is removed may also be changed by the driver according to the operation index of the blast furnace condition, the gas flow in the furnace.

Accordingly, the scope of the present invention should be determined by the appended claims rather than by the foregoing description.

According to the present invention, by judging whether the wall force generated, such as the fall of the furnace wall attachments in the blast furnace can be determined in a sequential manner, it is possible to reduce the error rate caused by the determination of the wall.

In addition, it is possible to accurately predict whether or not the occurrence of wall cracks in advance, in case of abnormality of the bleeding can take appropriate action in advance to stabilize the aging.

Claims (6)

In the furnace blast furnace attachment detection device is provided with a plurality of flue thermometers for detecting the blast furnace furnace temperature and a plurality of drain thermometers for detecting the drainage temperature of the furnace cooling water, For each temperature value T detected in accordance with the cycles set in the plurality of smoke thermometers and the temperature value E detected in the plurality of drainage thermometers in accordance with the set cycles, the period n times before the current period, respectively First and second storage units 301 and 307 for storing the temperature values A and F detected therebetween, respectively; Detection between the m-th time period and the n-th (n> m) time-period period from the current period among the detection temperature values A and F stored in the first and second storage units 301 and 307, respectively. First and second average calculation units 302 and 308 for calculating average values B and G of temperature values, respectively; Each temperature value T (E) detected in the current cycle for each of the smoke thermometer and each drain thermometer, the average value B of the first average calculator 302, and the second average calculator 308 First and second arithmetic units 303 and 309 for calculating the difference value C and H of the mean value of G, respectively; First and second comparisons of the resultant temperature values C and H in the first and second calculation units 303 and 309 with the magnitudes of the first and second preset temperature values D and I, respectively. Second comparator 304 and 310; As a result of each comparison in the first and second comparators 304 and 310, the resultant temperature values C and H for the at least one ductility thermometer and the at least one drainage thermometer are the first values. And first and second wall deciding portions 305 and 311 which are respectively determined to be wall fault occurrences when the second set temperature value (D) (I) is equal to or higher than the second set temperature value (D) (I). The method of claim 1, A third average calculating unit 313 for calculating an average value Q of the temperature values T detected each time in the plurality of smoke thermometers; A third storage unit (314) for storing an average value (R) between the current period and the nth time-period period among the average values (Q) calculated each time by the third average calculation unit (313); A fourth average calculation that calculates an average value S of the average value R stored between the mth time period to the nth time period from the current period among the average values R stored in the third storage unit 314 Part 315; A third calculating unit calculating the difference value U of the average value S calculated by the fourth average calculating unit 315 from the average value T calculated by the third average calculating unit 313 in the current period ( 316); And When the difference value (U) is greater than or equal to the third set temperature value (W) by comparing the difference value (U) calculated by the third calculation unit (316) with a preset third set temperature value (W) A third comparison unit 317 for notifying occurrence of the occurrence; In the furnace attachment drop detection device of the blast furnace, characterized in that it further comprises a. The method of claim 1 or 2, wherein the first to third storage unit, Apparatus for detecting the fall of the furnace attachment, characterized in that for storing the temperature value in a first-in first-out (FIFO) method according to the set period. The method according to claim 1 or 2, Wherein n is 1.5 ~ 2.5, m is 0.5 ~ 1.5 in the furnace furnace attachment drop detection device, characterized in that. The method of claim 4, wherein The n, m is 2 and 1, respectively, characterized in that the furnace attachment dropout detection device of the blast furnace. The method according to claim 1, wherein the first to second wall deciding portion, Intra furnace attachment drop detection device characterized in that it comprises an OR gate.

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