METHOD FOR DETECTING FLUCTUATION OF SOLIDIFIED LAYER AND METHOD FOR OPERATING BLAST FURNACE

Abstract

A method for detecting a fluctuation of a solidified layer, and a method for operating a blast furnace by employing the relevant method. In the method for detecting a fluctuation of a solidified layer, the fluctuation of the solidified layer in the lower part of a blast furnace is detected by using the amount of heat supplied to pig iron in the lower part of the blast furnace and the amount of heat in the pig iron tapped in a predetermined period.

Claims

1. A method for detecting a fluctuation of a solidified layer, the method comprising: detecting a fluctuation of a solidified layer in a lower part of a blast furnace using an amount of heat supplied to pig iron in the lower part of the blast furnace and an amount of heat in the pig iron tapped in a predetermined period.

2. The method for detecting a fluctuation of a solidified layer according to claim 1, further comprising: determining that the solidified layer has grown when expression (1) below is satisfied:
α×T.sub.Q>a×T.sub.pig+b  (1); and determining that the solidified layer has decreased when expression (2) is satisfied:
α×T.sub.Q<a×T.sub.pig+b  (2) where in the expressions (1) and (2), above: α is a ratio in which heat supplied to the lower part of the blast furnace in a steady state where the solidified layer does not increase or decrease is transferred to the pig iron, T.sub.Q is a furnace heat index (MJ/t-pig) that is an index of an amount of heat supplied to the lower part of the blast furnace, T.sub.pig is a temperature (° C.) of the pig iron tapped, and a and b are each a constant determined by a component concentration of the pig iron tapped.

3. The method for detecting a fluctuation of a solidified layer according to claim 1, wherein the predetermined period is a period from an end of a previous tapping of pig iron to an end of a current tapping of pig iron.

4. A method for operating a blast furnace, the method comprising: detecting a fluctuation of a solidified layer in a lower part of a blast furnace by employing the method for detecting a fluctuation of a solidified layer according to claim 1; and promoting melting of the solidified layer when the solidified layer has grown, and promoting growth of the solidified layer when the solidified layer has decreased.

5. The method for detecting a fluctuation of a solidified layer according to claim 2, wherein the predetermined period is a period from an end of a previous tapping of pig iron to an end of a current tapping of pig iron.

6. A method for operating a blast furnace, the method comprising: detecting a fluctuation of a solidified layer in a lower part of a blast furnace by employing the method for detecting a fluctuation of a solidified layer according to claim 2; and promoting melting of the solidified layer when the solidified layer has grown, and promoting growth of the solidified layer when the solidified layer has decreased.

7. A method for operating a blast furnace, the method comprising: detecting a fluctuation of a solidified layer in a lower part of a blast furnace by employing the method for detecting a fluctuation of a solidified layer according to claim 3; and promoting melting of the solidified layer when the solidified layer has grown, and promoting growth of the solidified layer when the solidified layer has decreased.

8. A method for operating a blast furnace, the method comprising: detecting a fluctuation of a solidified layer in a lower part of a blast furnace by employing the method for detecting a fluctuation of a solidified layer according to claim 5; and promoting melting of the solidified layer when the solidified layer has grown, and promoting growth of the solidified layer when the solidified layer has decreased.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0011] FIG. 1 illustrates the relationship between the pig-iron temperature and the furnace heat index T.sub.Q during steady-state operation.

[0012] FIG. 2 illustrates a fluctuation in W.sub.x/W.sub.prod versus the elapsed days.

[0013] FIG. 3 illustrates the fluctuation of furnace bottom temperature versus the elapsed days.

DETAILED DESCRIPTION

[0014] Disclosed embodiments will be described below. Pig iron produced in a blast furnace is mainly heated by heat generated by sensible heat of a hot blast and combustion of a carbonaceous material in the lower part of the blast furnace. Endothermic reactions, such as a solution loss reaction and a reduction reaction of moisture contained in the hot blast at tuyere tips, also occur in the lower part of the blast furnace. Heat loss also occurs due to heat transfer to the stave in the lower part of the furnace as the heat transfer to the furnace wall. These amounts of heat do not contribute to the heating of the pig iron. Thus, there is considered to be a certain relationship between the heat balance and the pig-iron temperature in the lower part of the blast furnace in the steady state where the solidified layer does not vary.

[0015] One of the indices of the amount of heat supplied to the lower part of the blast furnace is a furnace heat index T.sub.Q (MJ/t-pig) disclosed in Patent Literature 2. T.sub.Q is expressed by expression (3).

T.sub.Q=Q.sub.1+Q.sub.2−(Q.sub.3+Q.sub.4+Q.sub.5+Q.sub.6)  (3)

[0016] In expression (3) above, Q.sub.1 is the heat of combustion (MJ/t-pig) of coke at the tuyere tips. Q.sub.1 can be calculated by dividing the amount of heat generated by coke combustion, which is calculated from the amount of oxygen blown into the blast furnace through the tuyeres per unit time, by the amount of pig iron produced in that unit time.

[0017] Q.sub.2 is the blast sensible heat (MJ/t-pig) input into the blast furnace by the blast from the tuyeres. Q.sub.2 can be calculated by finding the amount of heat input into the blast furnace by the blast per unit time from the measured blast flow rate and blast temperature per unit time, and dividing this value by the amount of pig iron produced in the unit time.

[0018] Q.sub.3 is heat of the solution loss reaction (MJ/t-pig). The amount of carbon consumed by the furnace reaction in the unit time can be calculated from the difference between the amount of carbon burnt by the blast per unit time and the amount of carbon emitted, the amount of carbon emitted being determined from the analytical value of CO and CO.sub.2 gas concentrations in the upper part of the blast furnace. The heat of the solution loss reaction can be calculated from the amount of carbon consumed. Q.sub.3 can be calculated by dividing this heat of reaction by the amount of pig iron produced in the unit time.

[0019] Q.sub.4 is the heat of decomposition of moisture (MJ/t-pig), the moisture being mainly contained in the blast. Q.sub.4 can be calculated by dividing the heat of decomposition per unit time, obtained from the measured value of moisture in the blast, by the amount of pig iron produced in the unit time. Q.sub.5 is the amount of transition of heat flux (MJ/t-pig) through cooling water. Q.sub.5 can be calculated by calculating the amount of heat transfer per unit time to the cooling water based on the amount of cooling water and the temperature difference of the cooling water between the inlet and outlet sides of the blast furnace body, and dividing the amount of heat transfer by the amount of pig iron produced in the unit time. Q.sub.6 is the heat of decomposition of the reducing material injected from the tuyeres in unit time. Q.sub.6 can be calculated by dividing the relevant heat of decomposition by the amount of pig iron produced in the unit of time.

[0020] Instead of T.sub.Q calculated by expression (3), the amount of heat described below may be used as an index of the amount of heat supplied to the lower part of the blast furnace: Sensible heat carried by a gas moving from the lower part to the upper part of the blast furnace is subtracted from T.sub.Q. Sensible heat brought by coke and ore materials supplied from the upper part to the lower part of the blast furnace is added thereto. The resulting amount of heat is proportionally divided into pig iron and molten slag. The amount of heat supplied to the pig iron calculated by this method may be used. The sensible heat carried by the gas can be calculated by multiplying the temperature difference between the estimated temperature of the gas burnt in front of the tuyeres and the reference temperature representing the upper end of the lower part of the blast furnace by the specific heat of the gas in the blast furnace. The sensible heat of the raw material supplied to the lower part of the blast furnace can be calculated by multiplying the temperature difference between a temperature of 1,450° C. to 1,500° C., which is estimated to be a temperature at the lower end of the cohesive zone, and the above reference temperature by the specific heat of the raw material. The value obtained by these processes is distributed to the melt present in the lower part of the blast furnace; thus, a value obtained by multiplying the relevant value by the ratio of the specific heat of the pig iron out of the sum considering the mass ratio of the specific heats of the pig iron and slag can be regarded as the amount of heat supplied to the pig iron. The reference temperature described above is in the range of 800° C. to 1,200° C., preferably 900° C. to 1,000° C.

[0021] FIG. 1 illustrates the relationship between the pig-iron temperature and the furnace heat index T.sub.Q during the steady state. The horizontal axis in FIG. 1 is the furnace heat index T.sub.Q (difference from reference T.sub.Q) (MJ/t-pig), and the vertical axis is the pig-iron temperature (difference from the reference pig-iron temperature) (° C.). The steady state is a state of blast furnace operation when the difference in mass between the calculated amount of pig iron and slag calculated from the amount of raw materials charged into the blast furnace per day and the actual amount of pig iron and slag tapped from the blast furnace on that day is within 5 mass %. Hereinafter, a blast furnace operation in a steady state may be referred to as a steady-state operation. The pig-iron temperature in the following description is an average value of the pig-iron temperatures on that day. In FIG. 1, however, an intermediate value of the pig-iron temperature is defined as a reference pig-iron temperature (1,500° C., in the example illustrated in FIG. 1), and the pig-iron temperature is indicated as a difference from the reference pig-iron temperature.

[0022] As illustrated in FIG. 1, in the steady state, there is a correlation between the furnace heat index T.sub.Q and the pig-iron temperature. Accordingly, when α is defined as a ratio at which heat supplied to the lower part of the blast furnace in the steady state is transferred to the pig iron, the relationship of expression (4) below is established.

α×T.sub.Q×W.sub.prod=Q.sub.pig×W.sub.drain  (4)

[0023] In expression (4), W.sub.prod (t-pig) is the amount (t) of pig iron produced in the blast furnace in the time t from the end of the previous tapping to the end of the current tapping, and W.sub.drain is the amount (t) of pig iron currently tapped from the blast furnace. Q.sub.pig (MJ/t-pig) is the amount of heat of the pig iron at the pig-iron temperature T.sub.pig (° C.) and can be calculated by expression (5) below.

Q.sub.pig=a×T.sub.pig+b  (5)

[0024] In expression (5) above, a and b are each a constant determined by the component concentration of tapped pig iron. The values of the constants “a” and “b” corresponding to pig irons having various component concentrations are obtained in advance. For example, in the case of pig iron having a carbon concentration of 4 to 5 mass %, a=0.84, and b=84.

[0025] Letting the amount of pig iron melted or solidified in the blast furnace in the time t be w.sub.x (t.sub.pig), W.sub.drain can be calculated by expression (6) below.

W.sub.drain=W.sub.prodW.sub.x  (6)

[0026] In expression (6) above, W.sub.x is the amount of solidified material (t-pig). When the solidified material is dissolved, W.sub.x is a positive value. When the solidified material is solidified, W.sub.x is a negative value. When expressions (5) and (6) are substituted into expression (4), expression (4) is represented by expression (7) below.

α×T.sub.Q×W.sub.prod=(a×T.sub.pig+b)×(W.sub.prod+W.sub.x  (7)

[0027] Modification of expression (7) above leads to expression (8) below.

W.sub.x/W.sub.prod=[α×T.sub.Q/(α×T.sub.pig+b)]−1  (8)

[0028] During the steady-state operation, heat supplied to the lower part of the furnace is transferred to pig iron at a constant ratio α, the relationship of expression (9) is established.

α×T.sub.Q=Q.sub.pig=a×T.sub.pig+b  (9)

[0029] When the relationship of expression (9) is substituted into expression (8) above, the expression can be expanded as presented in expression (10). That is, W.sub.x=0 during the steady-state operation.

W.sub.x/W.sub.prod=[α×T.sub.Q/(a×T.sub.pig+b)]−1=1−1=0  (10)

[0030] Under this assumption, there is no increase or decrease in the solidified layer during the steady-state operation. Thus, the pig-iron temperature and the T.sub.Q value when the actual amount of pig iron produced roughly matches the amount of pig iron expected from the amount of raw materials charged are substituted into expression (9), so that it is possible to obtain the a value, which is the ratio at which heat supplied to the lower part of the blast furnace is transferred to the pig iron in the steady state.

[0031] When the solidified layer has decreased by melting, the right side of expression (8) is positive, and expression (8) is represented by expression (1) below.

α×T.sub.Q>a×T.sub.pig+b  (1)

[0032] Expression (1) indicates that when the solidified layer is melted and decreased, pig iron having a low temperature is tapped, compared with the case of the steady-state operation, with respect to the amount of heat supplied to the lower part of the blast furnace. In the method for detecting the fluctuation of a solidified layer according to the present embodiment, this relationship is used to determine that when the amount of heat (α×T.sub.Q) supplied to pig iron in the lower part of the blast furnace is larger than the amount of heat (a×T.sub.pig+b) of the pig iron tapped, the amount of heat corresponding to the difference therebetween is used for melting the solidified layer, and the solidified layer in the lower part of the blast furnace is decreased.

[0033] On the other hand, when the solidified layer has grown, expression (8) is negative. Thus, expression (8) is represented by expression (2) below.

α×T.sub.Q<a×T.sub.pig+b  (2)

[0034] Expression (2) indicates that when the solidified layer grows, pig iron having a high amount of heat is tapped, compared with the case of the steady-state operation, with respect to the amount of heat supplied to the lower part of the blast furnace. In the method for detecting the fluctuation of a solidified layer according to the present embodiment, this relationship is used to determine that when the amount of heat (α×T.sub.Q) supplied to pig iron in the lower part of the blast furnace has been smaller than the amount of heat (a×T.sub.pig+b) of the pig iron tapped, the amount of heat corresponding to the difference therebetween has been used for solidifying the solidified layer, and the solidified layer in the lower part of the blast furnace has grown.

[0035] As described above, in the method for detecting the fluctuation of a solidified layer according to the present embodiment, the fluctuation of the solidified layer in the lower part of the blast furnace is detected using the amount of heat (α×T.sub.Q) supplied to pig iron in the lower part of the blast furnace and the amount of heat (a×T.sub.pig+b) of the pig iron tapped in a predetermined period. Specifically, the amount of heat (α×T.sub.Q) supplied to pig iron in the lower part of the blast furnace and the amount of heat (a×T.sub.pig+b) of the pig iron tapped are calculated. When (α×T.sub.Q) and (a×T.sub.pig+b) satisfy expression (1), the solidified layer is determined to have decreased in the predetermined period. When (α×T.sub.Q) and (a×T.sub.pig+b) satisfy expression (2), the solidified layer is determined to have grown in the predetermined period. This enables early detection of the fluctuation of the solidified layer during the blast furnace operation and allows the blast furnace operation to maintain the solidified layer in the lower part of the blast furnace in an appropriate state.

[0036] The predetermined period for calculating (α×T.sub.Q) and (a×T.sub.pig+b) is preferably a period from the end of the previous tapping of pig iron to the end of the current tapping of pig iron. Each time pig iron is tapped, the temperature and composition values of the pig iron are measured. Thus, T.sub.pig (° C.) can be determined using these values. The constants a and b can be determined using the component values. The predetermined period is not limited to the period from the end of the previous tapping of pig iron to the end of the current tapping of pig iron as long as “α×T.sub.Q” and “a×T.sub.pig+b” in the period can be determined. For example, the T.sub.pig values of pig irons tapped in a given period from the end of any given tapping of pig iron to the end of any given tapping of pig iron are weighted-averaged on the basis of the amounts of pig irons tapped. The T.sub.Q values in the period are weighted-averaged in the same manner. The resulting values may be used as values in the given period.

[0037] When the solidified layer is determined to have grown by the method for detecting the fluctuation of a solidified layer, a blast furnace operation method is implemented to promote the melting of the solidified layer by increasing the target amount of heat input and increasing the amount of heat supplied to the lower part of the blast furnace. The operation to increase the amount of heat supplied to the lower part of the blast furnace may be performed by increasing the heat of combustion of coke per ton of pig iron as given in Q.sub.1 above or by increasing the blast sensible heat per ton of pig iron as given in Q.sub.2 above.

[0038] When the solidified layer is determined to have decreased by the method for detecting the fluctuation of a solidified layer, a blast furnace operation method is implemented to promote the growth of the solidified layer by decreasing the target amount of heat input and decreasing the amount of heat supplied to the lower part of the blast furnace or increasing the amount of heat transfer from the lower part of the blast furnace. The operation to decrease the amount of heat supplied to the lower part of the blast furnace may be performed by increasing the heat loss given in Q.sub.5. This suppresses the fluctuation of the solidified layer in the lower part of the blast furnace and achieves a stable blast furnace operation.

Examples

[0039] An example in which a fluctuation in W.sub.x/W.sub.prod and a fluctuation in furnace bottom temperature were examined in a blast furnace operation using a blast furnace having an inner capacity of 5,000 m.sup.3 will be described below. FIG. 2 illustrates a fluctuation in W.sub.x/W.sub.prod with respect to the elapsed days. In FIG. 2, the horizontal axis is the elapsed days (days), and the vertical axis is W.sub.x/W.sub.prod.

[0040] As illustrated in FIG. 2, W.sub.x/W.sub.prod decreased on day 5. The decrease in W.sub.x/W.sub.prod indicates that W.sub.x/W.sub.prod has been negative and thus expression (2) above is satisfied. Accordingly, it is possible to detect the fact that the solidified layer in the lower part of the blast furnace has grown on day 5.

[0041] W.sub.x/W.sub.prod increased on day 8. The increase in W.sub.x/W.sub.prod indicates that W.sub.x/W.sub.prod has been positive and thus expression (1) above is satisfied. Accordingly, it is possible to detect the fact that the solidified layer in the lower part of the blast furnace has decreased on day 8.

[0042] FIG. 3 illustrates the fluctuation of the furnace bottom temperature versus the elapsed days in the same blast furnace operation. In FIG. 3, the horizontal axis is the elapsed days (days), and the vertical axis is the furnace bottom temperature (° C.). The furnace bottom temperature is the value of a thermometer installed in the middle portion of the hearth of the blast furnace bottom.

[0043] As illustrated in FIG. 3, the furnace bottom temperature decreased on day 6. This decrease in furnace bottom temperature is thought to be due to the growth of the solidified layer at the furnace bottom, thereby decreasing the amount of heat transferred from the inside of the furnace to the furnace bottom. That is, it is understood that the detection of the fluctuation of the solidified layer using the furnace bottom temperature is later than the detection using the amount of heat supplied to the lower part of the blast furnace and the temperature of pig iron tapped. From these results, it was confirmed that the implementation of the method for detecting the fluctuation of a solidified layer can detect the increase or decrease of the solidified layer in the lower part of the blast furnace at an early stage. When the solidified layer in the lower part of the blast furnace is determined to have grown on the basis of the detection, an operation for promoting the melting of the solidified layer is performed, and when the solidified layer in the lower part of the blast furnace is determined to have decreased, a blast furnace operation for promoting the growth of the solidified layer is performed. It can be seen that this suppresses the fluctuation of the solidified layer in the lower part of the blast furnace and achieves a stable blast furnace operation.