JP4783995B2 - Blast furnace operation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a blast furnace operating method for predicting the amount of blast furnace residue and the amount of residue and managing the amount of residue.
[0002]
[Prior art]
In the blast furnace, the amount of residue and the amount of residue (collectively referred to as the amount of residue) have a significant impact on operations. The amount of residue, the amount of residue, that is, when the amount of liquid increases to the vicinity of the tuyere, the effective volume of gas flow around the tuyere decreases, the blast pressure rises, the charge drops irregularly, and the furnace condition It has been regarded as a more important management index than before.
[0003]
Conventionally, the amount of blast furnace residue and the amount of residue are determined by checking the number of times the worker has charged raw materials such as coke and ore charged in the blast furnace from the previous discharge time to the current discharge time. Obtain the calculated hot metal production amount and the calculated hot metal production amount per charge of the product (hereinafter simply referred to as charge), and charge the calculated hot metal production amount and the calculated hot metal production amount per charge. By multiplying the number of times, the current theoretical output and theoretical output are calculated, and the actual output from the previous output time to the current output time using the hot metal pot, the load cell of the hot metal pot or the level meter. The actual output amount was obtained, and the difference between these was used as the residual amount and the residual amount.
[0004]
In the actual amount of dredging, if there is a water granulation facility, calculate the amount of dredging from the specific gravity of the water granulated lees and the volume of the water granulated lees produced. The amount of slag was obtained by visually checking the hot metal.
[0005]
Also, the amount of catch received, the amount of yield sent from the received amount measurement means, and the cumulative change of the amount of yield disclosed in JP-A-3-215609 and JP-A-3-223409 (hereinafter referred to as actual results). (Referred to as output amount / actual output amount) and the average number of times main raw materials are charged in the past fixed time considering changes in air volume and fuel ratio, the weight of each main raw material, Fe content, etc. Grasping the amount of residue (residual amount = theoretical amount of output-actual amount of output) Quantity, residue amount = theoretical output amount-actual output amount).
[0006]
In addition, in the method disclosed in Japanese Patent Laid-Open No. 5-125414, after the start of dredging from the tap outlet, the cumulative predicted amount of hot metal generated in the blast furnace furnace and the cumulative output discharged from the tap outlet are displayed. The amount of residue in the furnace is sequentially determined from the amount of dredging, and the predicted decrease rate of the in-furnace residue is sequentially determined based on the average predicted extraction rate calculated from the generation rate of hot metal generated in the blast furnace and the past extraction rate pattern. The output end prediction time is sequentially obtained from the amount of residue in the furnace and the predicted decrease rate of the residue in the furnace.
[0007]
Here, the amount of hot metal To in the blast furnace is calculated by To = T + Vot (T: estimated value of the amount of storage before start of discharge, Vo: hot metal production rate, t: elapsed time from the start of start) The estimated value T of the previous storage amount is the accumulated charge weight (theoretical output amount, theoretical output amount) charged into the blast furnace and the accumulated weight of the hot metal and hot metal output from the outlet (actual output Estimated from the difference between the amount of drought and actual output.
[0008]
Further, in the method disclosed in Japanese Patent Application Laid-Open No. 9-3512, the amount of residue in the furnace is obtained over time during the tapping from one tapping port, and is compared with a preset residue management value each time. Then, the magnitude relationship is obtained, and furthermore, the magnitude of the hot metal production rate in the blast furnace furnace is compared by obtaining the magnitude, and the magnitude relation and the magnitude relation of the residual amount in the furnace are determined in the subsequent furnaces. Predicts changes in the amount of residue.
[0009]
Here, the residual amount in the furnace means the theoretical output amount and the theoretical output amount obtained from the amount of raw material charged in a predetermined period before the present time. The actual amount of residue in the furnace obtained by subtracting the actual output amount and the actual output amount from the present time to a predetermined period before the current amount.
[0010]
[Problems to be solved by the invention]
In all the above-mentioned conventional techniques, there is always a predetermined number of charges in the furnace (that is, the stock level in the blast furnace is constant), and “one charge is always discharged if one charge is charged”. The amount of residue in the blast furnace and the amount of residue are estimated based on the concept or assumption.
[0011]
6 and 7 illustrate this relationship.
In FIG. 6, the black triangle mark represents the charging of the raw material into the blast furnace furnace, and “−” represents the output to and out of the blast furnace furnace. In this figure, the amount of residue and the amount of residue are not shown.
[0012]
In the conventional technology, the number of times of charging in a certain period of time (the area surrounded by the dotted line in the figure) is multiplied by the calculated hot metal production amount and the calculated hot metal production amount (the number of charging times x the calculated hot metal production amount, the charging amount). Times x calculated hot metal production amount), which is the theoretical output and theoretical output. In addition, the actual output amount and the actual output amount that are output and output during a certain period of time (the range enclosed by the dotted line in the figure) are used. In other words, the relationship is as follows.
[0013]
Residual amount = Theoretical output amount-Actual output amount Residual amount = Theoretical output amount-Actual output amount In this way, a certain amount of time is taken, and the results of charging within this time range. And calculating the amount of residue and the amount of residue using the output and the actual output, it means that “stock level in the blast furnace is constant:“ If 1 charge is charged, 1 charge is always discharged. It is the same as the concept of “Iku”.
[0014]
On the other hand, in FIG. 7, it is considered that the raw material (A) is sequentially fed into the blast furnace from the top, and the oldest same (A) is discharged as pig iron and soot from the lower part of the furnace.
Here, “charge” refers to the charge of the smallest unit in charge of charging the raw material into the blast furnace, and is generally called a charge that is a batch or a collection of batches. However, in this specification, it will be referred to as “charge” hereinafter.
[0015]
Therefore, the subject of this invention is solving the following subjects in the above prior art.
<Problem 1>
In the method for managing residue in blast furnace operation disclosed in the prior art, residue management is performed once every 40 minutes in order to grasp the amount of residue and the amount of residue by manual calculation by the operator. In the meantime, it is only possible to roughly predict the amount of residue and residue by visually checking the output and the state of output, causing a delay in grasping the lack of hot metal squeezing, and the timing of action such as lap output and wind reduction May delay the furnace condition.
<Problem 2>
In the method for managing residues in a blast furnace operation disclosed in JP-A-3-215609, JP-A-3-223409, JP-A-5-125414, and JP-A-9-3512, the scale is actually reduced. Stop the charging in the furnace or lengthen the charging interval, such as during operation (operation with a reduced amount of furnace interior compared to normal operation) or when there is a resting wind. There are cases where the level of goods is lowered, and the above assumptions do not fit the actual situation.
[0016]
FIG. 8 illustrates this relationship. As shown in FIG. 8, in the above assumption, the theoretical output amount <the actual output amount, and the theoretical output amount <the actual output amount. It is often experienced that the amount of residue and the amount of residue obtained in this way often become negative.
[0017]
Also, each time, the same volume, weight, and fuel ratio of the charge is not always charged, and the same raw material that has entered (charged) into the furnace leaves the furnace (outlet). Assuming that the mass balance in the furnace is not faithfully reproduced, the amount of residue in the furnace is different from the actual situation, and the accuracy of the residue Can not be managed.
[0018]
FIG. 9 is a schematic diagram showing the above-described state in a mode corresponding to FIG. 7 described above. As shown in the figure, the properties of the input raw material each time are (A), (B), (C), ( Since it is different from D), it is clear from now on that it is not appropriate for the same raw material to be discharged as hot metal and hot metal when the raw material is input.
[0019]
[Means for Solving the Problems]
Here, the present inventor, by individualizing the charging materials, constantly monitoring how far the charging materials are currently staying in the blast furnace furnace, about the charges actually staying in the furnace Focusing on the fact that the theoretical output and the theoretical output can be obtained, the remaining amount can be managed more appropriately, and therefore the theoretical volume value and actual volume value in the furnace are considered. As a result, it was found that it was possible to know how much of the charged raw material stayed in the furnace, and the present invention was completed.
[0020]
Here, the present invention is as follows.
(1) In the blast furnace operation method for managing residue during blast furnace operation,
Each time a raw material is charged into the blast furnace furnace, a calculation that is calculated based on the raw material type and weight of the charged material in the smallest unit. Store hot metal production and calculated hot metal production as "latest charge information",
By converting the volume from the "oldest charge information" to the "latest charge information" in order from the smallest unit charge in the furnace, the total amount in the furnace is added to the furnace. The theoretical volume value of the existing charge is obtained, and the “charge level in the blast furnace” immediately after the charge is measured, and the total volume of the charge existing in the blast furnace is determined from that level. Volume value) and calculating the difference between the actual volume value and the theoretical volume value (actual volume value−theoretical volume value),
If this value is negative, the charge present in the blast furnace furnace will be the furnace from the “oldest charge information” for each charge in the smallest management unit until the value is positively converted. By calculating the total amount of hot metal generated and the amount of hot metal generated for each charge information in the minimum management unit that has been discharged, the theoretical amount of heat generated and the Calculating the amount of output,
When the above value is positive, it is assumed that no charge in the smallest unit of management is discharged outside the furnace, the theoretical output = 0, the theoretical output = 0, and
The actual output amount and the actual output amount are obtained, and the residual amount in the blast furnace is determined by the difference between the theoretical output amount and the actual output amount (residual amount = theoretical output amount-actual output amount). A method of operating a blast furnace, characterized in that the amount is calculated from a difference between a theoretical output amount and an actual output amount (residual amount = theoretical output amount−actual output amount).
[0021]
(2) Every time the theoretical output, theoretical output, actual output, actual output, or actual output is calculated, the residual amount or residual amount is calculated by calculating the residual amount or residual amount. The method of operating a blast furnace as described in (1) above, wherein
[0022]
Thus, according to the present invention, in the blast furnace operation method, the load cell or level meter for measuring the weight in the pot, the conveyor scale for weighing the water slag, the charge information (fuel ratio, weight in the blast furnace) , Volume, volume of charge in the furnace after charging, etc.), and blast furnace internal charge tracking can be used to predict and manage the amount of blast furnace residue or residue with higher accuracy than before. .
[0023]
Here, when the amount of residue and the amount of residue increase, the liquid material increases in the tuyere direction (upward), the effective volume of gas flowing around the tuyere decreases, the blast pressure rises, The descending of the admission becomes irregular and causes the furnace condition to deteriorate. Therefore, the residue amount or residue amount is managed to be zero.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic explanatory view briefly explaining the method according to the present invention.
The hot metal discharged from the blast furnace 1 flows through the hot metal 2 and is separated into hot metal and hot metal. The hot metal flows through the hot metal 3 and is received by the hot metal pan 4, while the hot metal flows through the hot metal 5 and reaches the water granulation facility 6, thereby producing water granulated iron. The produced water mash is transported by a belt conveyor 7 to a hopper (not shown).
[0025]
In the above-described equipment, a microwave level meter 8 is provided on the hot metal ladle 4, and a load cell 9 is provided below the hot metal ladle 4, and the hot metal weight 12 in the hot metal ladle at regular intervals. , 13 are transmitted to the arithmetic unit 15. In addition, a conveyor scale 10 is provided on the belt conveyor 7 in order to weigh the produced water slag, and the hot metal weight 14 is transmitted to the arithmetic unit 15 at regular time intervals. Furthermore, when charging the raw material into the blast furnace, the charging of the minimum unit for the management, that is, the charging level value in the blast furnace immediately after charging, the minimum Charge information 11 such as the fuel ratio, charge weight, volume, etc. of the charge of the unit is transmitted to the arithmetic unit 15.
[0026]
Using the blast furnace interior entry tracking constructed in the arithmetic unit 15, the amount of residue or residue is calculated from the molten iron weights 12, 13, the molten metal weight 14, and the charging information 11, and the result is displayed on the CRT 16.
[0027]
Here, the blast furnace operation method according to the present invention, more specifically, the residue management method in the blast furnace operation will be described separately for each step as follows.
a. Loading information storage process:
Each time a raw material in the minimum unit for charging is charged into the blast furnace furnace, the weight of various raw materials in the charged material in the smallest unit, and the amount charged by component The preset hot metal components and the calculated hot metal production amount calculated from the hot metal components and the calculated hot metal production amount are stored as “latest charge information”.
[0028]
Here, various raw materials include coke, sintering, ore, pellets, auxiliary raw materials, and the like, and mean all raw materials charged into a blast furnace for producing hot metal and hot metal.
b. Process for obtaining actual volume value and theoretical volume value:
A volume conversion factor is set for each of the charged raw materials, and the volume from the "oldest charge information" to "latest charge information" in order from among the smallest management charge present in the furnace. The theoretical volume value of the charge existing in the furnace at that time is obtained by converting the volume based on the conversion coefficient and summing up.
[0029]
The theoretical volume value is calculated from the charged weight (ton) of each charge in terms of bulk density (ton / m ³ ). In this case, the charge is melted in the furnace and is in a solid-liquid mixed state. If two constants are provided, one is the bulk density conversion constant and the other is the bulk density conversion constant for the charge that exists in the solid state, and the volume of the solid-liquid mixed state charge and the volume of the solid state charge are obtained respectively. The theoretical volume value that better corresponds to the actual furnace situation can be obtained.
[0030]
Specifically, first, from the cohesive zone shape obtained from the in-furnace situation model prepared by analyzing the in-furnace furnace situation in advance, the melted solid-liquid of the charge existing in the furnace Determine the calculated volume of the charge in the mixed state.
[0031]
Next, using the bulk density conversion constant, the theoretical volume value when the solid-liquid mixed state is obtained in order from the oldest charge existing in the furnace is obtained.
When the sum of the volume values is equal to or greater than the volume of the solid-liquid mixed state calculated based on the model, the subsequent charge (theoretical volume when the solid-liquid mixed state has been reached in order until then is obtained. The theoretical volume is determined using the bulk density conversion constant for the solid state charge from the charge one layer above the final charge.
[0032]
At the same time, the “charge level in the blast furnace” immediately after charging is measured, and the total volume (actual volume value) of the charge existing in the blast furnace is obtained from this level.
When charging the raw material into the blast furnace, for example, the actual volume value of the furnace interior charge at the time when the charge for one charge is completed is measured by a sounding level meter (weight type from the top of the furnace to the top surface of the furnace interior interior. The level of the furnace interior charge is obtained by using a level meter that hangs down and measures the upper surface position), and the total volume of the charge is obtained based on this.
[0033]
Based on these data, the difference between the actual volume value and the theoretical volume value (actual volume value−theoretical volume value) is calculated.
c. Theoretical output and theoretical output calculation process:
When this (actual volume value−theoretical volume value) value is negative, the charge existing in the blast furnace is “maximum” for each charge in the smallest unit of management until the value changes to positive. It is assumed that the "old charge information" has been discharged to the outside of the furnace in sequence, and the calculated hot metal production amount and calculated hot metal production amount for each charge information of the minimum management unit discharged are summed up respectively. By calculating the theoretical output amount and the theoretical output amount.
[0034]
Here, the calculated hot metal production amount P and the calculated hot metal production amount S for each charge are the charge weight, volume, and charge amount by component for each charge, preset components in the hot metal, components in the hot metal, etc. Calculate from
[0035]
When the above value is positive, the theoretical output and the theoretical output are zero.
d. Residue amount and residue calculation process:
In order to obtain the residual amount and the residual amount, it is necessary to first obtain the actual output amount and the actual output amount.
[0036]
The actual amount of hot metal measured at any time by means of detecting the hot metal weight in the hot metal ladle or the means of detecting the hot metal level, and the weight of the hot metal in the hot metal ladle or the weight of the water granulated iron produced by the water granulator It is possible to obtain from the actual output amount measured at any time by means for detecting the level or means for detecting the level.
[0037]
The amount of blast furnace residue is the difference between the theoretical output and the actual output (residual amount = theoretical output-actual output), and the residual is the difference between the theoretical output and the actual output. It can be calculated as a difference (residual amount = theoretical output amount−actual output amount).
[0038]
At this time, the remaining amount or the remaining amount is calculated every time the theoretical output amount, the theoretical output amount, the actual output amount or the actual output amount is calculated as described above. You may make it do.
[0039]
FIG. 2 is a schematic explanatory diagram of blast furnace interior entry tracking.
In the figure, from charge 1 to N, the raw materials are sequentially charged into the blast furnace, and the amount of hot metal (P) and soot (S) produced is calculated for each.
[0040]
As already described, according to the present invention, the actual volume value and the theoretical volume value are compared, and when “actual volume value ≧ theoretical volume value”, it is assumed that the charge is not discharged outside the furnace theoretically. The theoretical output amount and the theoretical output amount at that time are set to zero.
[0041]
On the other hand, when “actual volume value <theoretical volume value”, it is assumed that the oldest charge existing in the furnace (the charge located in the lowest layer of the furnace) was discharged outside the furnace, and “actual volume value ≧ theoretical” Assuming that the oldest ones were discharged to the outside of the furnace until the "volume value" condition, the calculated amount of hot metal and the amount of hot metal generated in charge units were summed up for all discharged charges. And the theoretical output.
[0042]
Moreover, in FIG. 1, the hot metal weight in the hot metal ladle at a certain time interval from the microwave level meter 8 on the hot metal ladle 4 or the load cell 9 below the hot metal ladle 4 (herein referred to as an actual amount of molten iron) Then, the hot metal weight (herein referred to as the actual output amount) is calculated at constant time intervals from the conveyor scale 10 of the belt conveyor 7 that weighs the produced water crushed slag.
[0043]
By calculating the theoretical output amount and the actual output amount, or the difference between the theoretical output amount and the actual output amount, the residual amount or the residual amount is calculated (residual amount = theoretical output amount−actual output amount). Amount of waste, amount of residue = theoretical output-actual output).
[0044]
Next, the function and effect of the present invention will be described more specifically based on examples.
[0045]
【Example】
FIG. 3 shows a flowchart describing in detail the method of the present invention.
When the raw material is charged into the blast furnace, the amount of residue and the amount of residue are obtained through the steps S1 to S13 in FIG. 3 as described below.
[0046]
S1: The calculated hot metal production amount Pn and the calculated hot metal production amount Sn of the charged charge are calculated and added as the latest charge.
S2: The actual volume value of the charge in the blast furnace is obtained from the measured value of the sounding level meter.
[0047]
S3: From the model calculation result, calculate the volume of the charge in a solid-liquid mixed state.
S4: Calculate the theoretical volume value of the solid-liquid mixed state from the oldest charge in the furnace until the volume of the charge in the solid-liquid mixed state is reached.
[0048]
S5: The theoretical volume value of the solid state is calculated from the charge one layer above the charge that has reached the volume of the charge in the solid-liquid mixed state to the latest charge.
S6: The theoretical volume value in the solid-liquid mixed state and the theoretical volume value in the solid state are summed to calculate the theoretical volume value.
[0049]
S7: The discharged volume is zero, and the theoretical volume value is subtracted from the actual volume value.
S8: Determine whether (actual volume value-theoretical volume value) is positive or negative.
S9: If the value is negative, discharge the oldest charge until positive.
[0050]
S10: Calculate the sum ΣPi of the calculated hot metal production amount of the discharged charge and the sum ΣSi of the calculated hot metal production amount of the discharged charge, which are the theoretical output amount and the theoretical output amount, respectively.
[0051]
S11: On the other hand, the hot metal weights 12 and 13 in the hot metal ladle 4 are taken in to obtain the actual amount of hot metal.
S12: In addition, the hot metal weight 14 is obtained by weighing the water crushed slag, and the result is the actual output amount.
[0052]
S13: The theoretical output amount thus obtained minus the actual output amount is used as the residual amount.
Similarly, the theoretical output amount−the actual output amount is used as the residual amount.
This example was performed according to the above flowchart under the following preconditions.
[0053]
(a) The blast furnace body is assumed to be cylindrical with a radius of 7m and a height of 20m.
(B) The bulk density conversion constant for solid state charge is coke C: 0.5 (ton / m ³ ) and ore O: 2 (ton / m ³ ), and the bulk density conversion constant for solid-liquid mixed state charge is coke C. : 0.5 (ton / m ³ ), Ore O: 6 (ton / m ³ ).
(C) The volume of the furnace interior charge in the solid-liquid mixed state obtained from the cohesive zone shape obtained from the in-furnace situation model is 280 (m ³ ).
(D) The state of tracking in the blast furnace interior at this point is shown in FIG.
[0054]
Here, the calculated hot metal production amount P and the calculated hot metal production amount S of the charge unit are calculated from the component-by-component charging weight and the preset ratio of the components in the hot metal and the components in the hot metal.
[0055]
In this example, it is assumed that there are 6 charges in the solid-liquid mixed state and 7 charges in the solid state.
[Charge 1] 20 (ton) /0.5 (ton / m ³ ) +65 (ton) / 6 (ton / m ³ ) = 50.8 (m ³ )
[Charge 2] 18 (ton) /0.5 (ton / m ³ ) +61 (ton) / 6 (ton / m ³ ) = 46.2 (m ³ )
[Charge 3] 22 (ton) /0.5 (ton / m ³ ) +66 (ton) / 6 (ton / m ³ ) = 55.0 (m ³ )
[Charge 4] 19 (ton) /0.5 (ton / m ³ ) +65 (ton) / 6 (ton / m ³ ) = 48.8 (m ³ )
[Charge 5] 19 (ton) /0.5 (ton / m ³ ) +63 (ton) / 6 (ton / m ³ ) = 48.5 (m ³ )
[Charge 6] 18 (ton) /0.5 (ton / m ³ ) +64 (ton) / 6 (ton / m ³ ) = 46.7 (m ³ )
Volume from [Charge 1] to [Charge 6] = 296 (m ³ ) ≥ 280 (m ³ )
[Charge 7] 16 (ton) /0.5 (ton / m ³ ) +62 (ton) / 2 (ton / m ³ ) = 63.0 (m ³ )
[Charge 8] 16 (ton) /0.5 (ton / m ³ ) +62 (ton) / 2 (ton / m ³ ) = 63.0 (m ³ )
[Charge 9] 18 (ton) /0.5 (ton / m ³ ) +61 (ton) / 2 (ton / m ³ ) = 66.5 (m ³ )
[Charge 10] 18 (ton) /0.5 (ton / m ³ ) +64 (ton) / 2 (ton / m ³ ) = 68.0 (m ³ )
[Charge 11] 21 (ton) /0.5 (ton / m ³ ) +65 (ton) / 2 (ton / m ³ ) = 74.5 (m ³ )
[Charge 12] 23 (ton) /0.5 (ton / m ³ ) +66 (ton) / 2 (ton / m ³ ) = 79.0 (m ³ )
[Charge 13] 18 (ton) /0.5 (ton / m ³ ) +64 (ton) / 2 (ton / m ³ ) = 68.0 (m ³ )
Volume from [Charge 7] to [Charge 13] = 482 (m ³ )
Now, assuming that 1 charge [Coke C: 16 (ton) ore O: 62 (ton)] was newly charged from this state, the level of the charge in the blast furnace was measured by the sounding level meter. Suppose that it is 5.5 (m) from the bottom.
[0056]
Then, the actual volume value of the charge in the furnace becomes “7 (m) × 7 (m) × π × 5.5 (m) ≈846 (m ³ )” from the measured value of the sounding level meter.
The theoretical volume value in the blast furnace is the sum of the charge 296 (m ³ ) in the solid-liquid mixture state, the charge 482 (m ³ ) in the solid state, and the newly charged charge 63.0 (m ³ ). 841 (m ³ ).
[0057]
That is, “actual volume value ≧ theoretical volume value”, and it is logically assumed that no charge is discharged outside the furnace [theoretical output amount 0 (ton), theoretical output amount 0 (ton)].
Next, it is assumed that 1 charge [Coke C: 23 (tons) ore O: 66 (tons)] is newly charged, and the level of the charge in the blast furnace at that time is measured from the bottom of the furnace. Suppose it was at 5.6 (m).
[0058]
Then, the actual volume value of the charge in the furnace becomes “7 (m) × 7 (m) × π × 5.6 (m) ≈862 (m ³ )” from the measured value of the sounding level meter.
The theoretical volume values in the blast furnace are: charge 296 (m ³ ) in the solid-liquid mixture state, charge 482 (m ³ ) in the solid state, charge 63.0 (m ³ ) charged last time, charge charged this time This is the sum of 79.0 (m ³ ) and is 920 (m ³ ).
[0059]
That is, “actual volume value <theoretical volume value”, and it is assumed that the oldest charge (charge located in the lowest layer of the furnace) that is logically present in the furnace is discharged outside the furnace, and “actual volume value ≧ theoretical” It is assumed that the oldest thing was discharged out of the furnace until the “volume value” condition was met. Here, if the charge 1 is discharged outside the furnace, the condition of “actual volume value ≧ theoretical volume value” is satisfied.
[0060]
When the sum of the calculated hot metal production amount P and the calculated hot metal production amount S of all the charges discharged out of the furnace is calculated, only the charge 1 is discharged, and the theoretical output amount is shown in FIG. 43 (ton), the theoretical output is 13 (ton).
[0061]
Every time the charging of raw materials into the blast furnace is completed (charge unit), the theoretical output and theoretical output are calculated using blast furnace interior input tracking.
Also, a conveyor belt conveyor that weighs the weight of the hot metal in the hot metal ladle (actual output) from the load level below the hot metal ladle or the load cell below the hot metal ladle The hot metal weight (actual output amount) is calculated from the scale at regular time intervals.
[0062]
Based on the above calculation results, the residual amount in the blast furnace (theoretical output amount-actual output amount) and the residual amount (theoretical output amount-actual output amount) are calculated in real time and displayed on the CRT. .
[0063]
These results are shown graphically in FIGS. 5 (a) to (f).
In FIGS. 5 (a) to (f), the black triangle mark represents the charging of the raw material into the blast furnace.
The actual volume value and the theoretical volume value are calculated at the raw material charging timing, and if the charge is discharged outside the furnace, the theoretical output amount and the theoretical output amount are calculated.
[0064]
The vertical bar in the graph of FIG. 5 (a) represents the theoretical output, and the vertical bar in the graph of FIG. 5 (d) represents the theoretical output.
In addition, at the time of brewing and brewing, the weight of the hot metal in the hot metal ladle and the weight of the water crushed iron (hot metal weight) produced by the water granulation equipment are measured.
[0065]
The horizontal bars of the graphs in Fig. 5 (b) and Fig. 5 (e) represent the output and output, and the graph rising to the right in the figure shows the actual output amount at one output and output. Represents the integrated value of the output.
[0066]
The graphs in Fig. 5 (c) and Fig. 5 (f) are calculated from the difference between the theoretical output and output (vertical bar) and the actual output and output (upward graph). The amount of residue and the amount of residue are shown, respectively.
[0067]
Since the theoretical output amount and the theoretical output amount are generated together at the charging timing, the residual amount and the residual amount rapidly increase at the charging timing. The actual output amount and the actual output amount are gradually accumulated between actual output and output, so the residual amount and residual amount gradually decrease between output and output time. is doing.
[0068]
【The invention's effect】
According to the present invention, the amount of residue in the blast furnace and the prediction accuracy of the amount of residue are improved, and it is possible to grasp in real time, and actions such as lapping and wind reduction can be performed accurately, and stable operation of the blast furnace can be achieved. Realized.
[Brief description of the drawings]
FIG. 1 is a schematic explanatory diagram briefly explaining the present invention.
FIG. 2 is an explanatory view schematically showing blast furnace interior entry tracking.
FIG. 3 is a flowchart describing in detail the method of the present invention.
FIG. 4 is an explanatory view showing the status of blast furnace interior entry tracking, which is an embodiment of the present invention.
FIGS. 5A to 5F are graphs showing the results of Examples.
FIG. 6 is an explanatory diagram briefly explaining a conventional method.
FIG. 7 is an explanatory diagram briefly explaining a conventional method.
FIG. 8 is an explanatory diagram for simply explaining the assignment in the conventional method.
FIG. 9 is an explanatory diagram for simply explaining the assignment in the conventional method.
[Explanation of symbols]
1: Blast furnace, 2: Chief
3: Hot metal 4: Hot metal pan
5: Hot metal 6: Granulation equipment
7: Belt conveyor 8: Level meter
9: Load cell 10: Conveyor scale
11: Charging information (charging amount, fuel ratio, etc.)
12: Hot metal weight (level meter)
13: Hot metal weight (load cell)
14: Hot metal weight (conveyor scale)
15: Arithmetic unit
16: CRT

Claims (2)

In the blast furnace operation method for managing the residue during blast furnace operation,
Each time a raw material is charged into the blast furnace furnace, a calculation that is calculated based on the raw material type and weight of the charged material in the smallest unit. Store hot metal production and calculated hot metal production as "latest charge information",
By converting the volume from the "oldest charge information" to the "latest charge information" in order from the smallest unit charge in the furnace, the total amount in the furnace is added to the furnace. The theoretical volume value of the existing charge is obtained, and the “charge level in the blast furnace” immediately after the charge is measured, and the total volume of the charge existing in the blast furnace is determined from that level. Volume value) and calculating the difference between the actual volume value and the theoretical volume value (actual volume value−theoretical volume value),
If this value is negative, the charge present in the blast furnace furnace will be the furnace from the “oldest charge information” for each charge in the smallest management unit until the value is positively converted. By calculating the total amount of hot metal generated and the amount of hot metal generated for each charge information in the minimum management unit that has been discharged, the theoretical amount of heat generated and the Calculating the amount of output,
When the above value is positive, it is assumed that no charge in the smallest unit of management is discharged outside the furnace, the theoretical output = 0, the theoretical output = 0, and
The actual output amount and the actual output amount are obtained, and the residual amount at this time is determined from the difference between the theoretical output amount and the actual output amount (residual amount = theoretical output amount-actual output amount). A blast furnace operating method characterized in that the residue is managed by calculating the difference from the theoretical output amount and the actual output amount (residual amount = theoretical output amount−actual output amount). Each time the theoretical output amount, the theoretical output amount, the actual output amount or the actual output amount is calculated, the residual amount is managed by calculating the residual amount or the residual amount. The blast furnace operating method according to claim 1.

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