JP4157089B2 - Hot metal supply method to converter - Google Patents

Description

  The present invention relates to a hot metal supply method to a converter.

As is well known, the hot metal produced in the blast furnace is transferred to a converter process in which the components of the hot metal are adjusted after being loaded into a kneading car (torpit car) or a blast furnace pan. Further, in the kneading car or blast furnace pan, the auxiliary raw material is introduced into the hot metal charged therein to perform dephosphorization, desiliconization, and desulfurization to preliminarily perform hot metal component adjustment processing ( Hot metal pretreatment process).
In the converter process, molten iron is charged into the converter, dephosphorization and decarburization are performed by adding auxiliary materials and blowing oxygen to produce molten steel with a predetermined phosphorus concentration and carbon concentration. Like to do. The molten steel obtained in the converter process is then formed into a slab or the like through a continuous casting process, and steel products such as thick plates and thin plates are manufactured by rolling the slab (rolling step).

In order to increase the production volume of steel products, it is important to pay attention to the blast furnace process and increase the amount of hot metal discharged from the blast furnace, but the production capacity in other processes, for example, the hot metal pretreatment process, is important. It is also important to raise. Techniques for improving the production capacity of each process are disclosed in Patent Documents 1 to 3, for example.
Patent Document 1 focuses on the blast furnace process and considers the operating status (distribution status) of the hot metal transport container between the blast furnace and the steelmaking factory to verify the balance of the storage amount between the blast furnace and the steelmaking factory. Techniques for preventing steel failure are disclosed.

Patent Document 2 pays attention to the hot metal preliminary process, and has a plurality of process patterns for processing an object to be processed in lot units, and in the hot metal preliminary process line that executes the processes according to the plurality of process patterns in parallel, the payout process A physical distribution simulation method capable of setting an in-process amount at a proper value is disclosed.
Patent Document 3 discloses a logistics planning technique that focuses on the rolling process and focuses on the flow (distribution) of the rolled material until the heating furnace is charged, and considers the improvement of the production amount in the slab rolling process.
On the other hand, regarding the converter process, it is the processing capacity of the converter itself and the hot metal supply capacity to the converter that are related to the molten steel production capacity. If a plurality of converters are operated simultaneously, the processing capacity of the converter exceeds the hot metal supply capacity to the converter, and the hot metal supply capacity to the converter becomes rate-limiting. In other words, how efficiently and quickly the hot metal supply to the converter is performed is very important.

Patent Document 4 discloses a distribution technology for efficiently handling a ladle in a part of the converter process in order to improve the hot metal supply capacity to the converter. The converter equipment disclosed in this document has one crane, two ladles, one transport cart for conveying the ladle, and a ladle set device between the two converters. The ladle setting device is arranged so as to straddle the traveling rail, and operates to receive the empty ladle from the crane and lower the ladle and mount it on the transport cart.
As a result, two ladles can be used alternately for one transport cart, and even if one ladle is being charged into the decarburization converter, the other ladle can be used. The pan can be quickly moved to the outlet of the dephosphorization converter.
JP 2003-82407 A (pages 4 to 8) JP 2002-62924 A (pages 3 to 5) JP-A-10-272505 (pages 3 to 7) Japanese Patent No. 3503938 (pages 4 to 5, FIG. 5)

Usually, a converter facility has a plurality of converters, a plurality of ladle for charging molten iron into these converters, and a "dispensing station" (for dispensing) 3), and the ladle charged with molten iron is transferred between multiple converters and stations by a crane as shown in Fig. 3 (a). Just paying attention, it presents a complicated form of logistics.
The inventor of the present application examined in detail the operating conditions of the ladle and the crane on the basis of the Gantt chart of FIG. 3 (a) and the like in order to find a method for improving the molten steel production capacity in the converter process. As a result, there is a crane play time / waiting time such as “when the hot metal is dispensed to the ladle 103, the crane 104A is in a waiting state over the dispensing station 106A” (FIG. 3A). Of S part) was found to be a problem.

It has been clarified that reducing the play time and waiting time of cranes as much as possible leads to improved crane operating conditions and increased hot metal supply capacity to the converter.
However, the technique of Patent Document 4 described above pays attention only to a part of the converter process, and it is difficult to solve the above problems and greatly improve the hot metal supply capacity to the converter. In order to efficiently supply hot metal to the converter, it is important to move the ladle efficiently throughout the converter process. To that end, the operating status of the crane should be as good as possible. is required.

On the other hand, it is very difficult to apply the physical distribution technology of Patent Documents 1 to 3 to the converter equipment.
Therefore, in view of the above problems, the present invention provides a hot metal supply method to a converter that can efficiently supply hot metal to the converter by reducing the play time and waiting time of the crane as much as possible. For the purpose.

In order to achieve the above object, the present invention takes the following technical means.
That is, technical means for solving the problems in the present invention include a converter, a ladle for charging molten iron into the converter, a plurality of dispensing stations for discharging molten metal to the ladle, and the dispensing A converter facility having a crane for handling the ladle in a predetermined cycle to carry the ladle into or out of the station, and when the crane arrives at the dispensing station, the ladle disposed at the dispensing station The hot metal is supplied to the converter while handling the ladle with a crane so that the number becomes “the number of payout stations −1”.

In order to efficiently supply hot metal to the converter, it is important to move the ladle efficiently throughout the converter process. To that end, the operating status of the crane should be as good as possible. is required.
In other words, the crane places an empty ladle on the dispensing station, the molten iron is dispensed to the ladle, the ladle charged with the molten iron is transported to the converter, and the molten iron is then transferred to the converter. The cycle from loading and re-feeding the emptied ladle to the dispensing station is one cycle of the crane, and the cycle time of the crane is the cycle time of the crane. The operational status of the crane will be improved, and the hot metal supply capacity to the converter will be improved.

In order to shorten the cycle time of the crane, it is indispensable to minimize the play time and waiting time of the crane at each station such as the dispensing station. When it is placed, it is recommended to operate it as “go to take the next ladle immediately”.
Looking at such a situation as a whole, “There is always one empty station (empty place) where the ladle can be placed in the dispensing station. Because there is a ladle, there will be another empty station immediately. " When this is considered from the payout station side, the ladle is handled while handling the ladle with a crane so that the number of ladles placed at the payout station is “total number of payout stations—1”. It means to supply hot metal.

In this way, the dispensing station is always ready to accept the next ladle, and the crane with the ladle placed in the empty station can handle the adjacent ladle without waiting. Therefore, the ladle can be distributed very efficiently, and the hot metal can be supplied to the converter efficiently.
Further, technical means for solving the problems in the present invention include a converter, a ladle for charging molten iron into the converter, and a plurality of desulfurization stations in which desulfurization treatment is performed on the molten iron in the ladle. A converter facility having a crane for handling the ladle in a predetermined cycle to carry the ladle into or out of the desulfurization station, and when the crane arrives at the desulfurization station, the ladle disposed at the desulfurization station. The hot metal is supplied to the converter while handling the ladle with a crane so that the number of pots becomes “the number of desulfurization stations −1”.

This technical means applies the idea applied to the dispensing station to the desulfurization station.
According to this technical means, as in the case of the dispensing station, the desulfurization station is always ready to receive the next ladle, and the crane with the ladle placed in the empty station immediately closes the adjacent ladle. Since it can be handled, hot metal supply to the converter can be performed efficiently.
Preferably, the converter, the ladle for charging the molten iron into the converter, a plurality of dispensing stations where the molten metal is discharged to the ladle, and the desulfurization treatment for the molten metal in the ladle are performed. A desulfurization station and a converter for handling the ladle in a predetermined cycle to carry the ladle into and out of the payout station and the desulfurization station, and when the crane arrives at the payout station, The number of ladles arranged at the payout station is “number of payout stations−1”, and when the crane arrives at the desulfurization station, the number of ladles arranged at the desulfurization station is “desulfurization station”. The ladle is handled in the converter while handling the ladle with a crane so that It may be supplied.

More preferably, a converter, a ladle for charging molten iron into the converter, a plurality of discharge stations for discharging molten iron to the ladle, and a plurality of desulfurization treatments for molten iron in the ladle. A desulfurization station, a plurality of dehumidification stations for removing slag in the ladle, and the ladle is handled in a predetermined cycle to carry the ladle into or out of the discharge station, desulfurization station and demolition station When the crane arrives at the payout station, the number of ladles placed at the payout station is "number of payout stations-1" and the crane arrives at the desulfurization station. when the, number of ladle being disposed in the desulfurization station is "desulfurization station It is -1 ", and, when the crane has arrived skimming station, as the number of ladle disposed on skimming station is" skimming station number -1 ", ladle crane It is advisable to supply hot metal to the converter while handling the above.

  According to these technical means, in the converter equipment that performs the desulfurization treatment, each of the discharge station, the desulfurization station, and the dehumidification station is always in a state of accepting the next ladle, and the empty station is loaded. Since the crane with the ladle can handle the ladle next to it immediately, the ladle logistics is very efficient and the hot metal supply to the converter can be efficiently performed. Become.

  ADVANTAGE OF THE INVENTION According to this invention, in a converter process, hot metal supply to a converter can be performed efficiently.

Hereinafter, an embodiment of a hot metal supply method to a converter according to the present invention will be described with reference to the drawings.
FIG. 1 shows an outline when the converter equipment 1 is viewed from the front, and FIG. 2 shows a schematic plan view of the converter equipment 1.
As shown in FIG. 1, the converter facility 1 of the present embodiment conveys the three converters 2, a ladle 3 (hot metal ladle) that supplies hot metal to these converters 2, and the ladle 3. And two cranes 4. Furthermore, two “dispensing stations 6 (dispensing pits)”, which are places where the hot metal is transferred from the kneading wheel 5 to the ladle 3 after the ladle 3 is placed, are provided.

According to the present invention, when the cranes 4A and 4B arrive at the dispensing stations 6A and 6B in the converter 1 as described above, the number of ladles 3 arranged in the dispensing stations 6A and 6B is “dispensing”. The ladle 3 is supplied to the converter 2 while handling the ladle 3 with the cranes 4A and 4B so that the number of stations is "1". That is, the number of ladles 3 arranged in the two payout stations 6A and 6B is set to be the number of payout stations−1 = 2-1 = 1. By doing so, one ladle 3 is placed on either one of the payout stations 6A or 6B, and is in a state waiting for payout or being in a state where hot metal is being discharged from the kneading vehicle 5. At the same time, the other payout station 6B or 6A is empty.

Hereinafter, the details of the converter facility 1 according to the present embodiment will be described.
A traveling rail 7 is provided on the upper side of the converter facility 1 so as to run through the converter facility 1, and two cranes 4 described later travel on the traveling rail 7. . The payout stations 6A and 6B are provided on one side of the traveling rail 7 (left side in FIG. 2) so as to be aligned in the direction of the traveling rail 7, and 3 on the other side of the traveling rail 7 (right side in FIG. 2). The basic converters (converter 2A to converter 2C) are arranged in the direction of the traveling rail 7. Note that the vertical direction in the following description is the same as the vertical direction in FIG.

As shown in FIG. 2, for the convenience of explanation, the traveling rail 7 is divided into seven sections. Dispensing stations 6A and 6B are provided so as to correspond to the lower side of the traveling rail 7 corresponding to the partition numbers 1 and 2, and below the traveling rail 7 corresponding to the partition numbers 4, 5, and 6. In addition, converters 2A, 2B, and 2C are provided on the side of the traveling rail 7. The crane 4A moves from the partition numbers 0 to 6, and the crane 4B moves from the partition numbers 1 to 7. One delimiter number corresponds to the width of one crane.
In addition, at the position of the partition number 0 and above the payout station 6A, the “scraping station 9A” is a place where the slag floating on the upper surface of the hot metal in the ladle 3 is scraped out by the sword 8A (slag dragger). Is provided. Similarly, a throat oyster 8B is arranged at the position of the delimiter number 3 to form a removal station 9B.

That is, two payout stations 6 that are adjacent to each other in the moving direction of the crane 4 are provided, and the removal stations 9 are provided on both sides in the moving direction of the payout stations 6, respectively. Two cranes 4A and 4B can exist simultaneously.
On the traveling rail 7, two cranes 4A and 4B are provided. Specifically, the crane body 10 travels on the traveling rail 7, and a suspended rope 11 (wire) extends downward from the crane body 10, and the tip of the suspended rope 11 The ladle 3 is suspended by a hook 12 provided on the top. The ladle 3 is lifted upward by winding the suspended rope 11 around the crane body 10, and the ladle 3 is paid out when the crane body 10 travels on the traveling rail 7. It is freely transferred between the station 6 and the converter 2.

The outline of ladle movement in the converter 1 is as follows.
First, after the kneading wheel 5 arrives at the converter 1, hot metal is poured from the kneading wheel 5 into the ladle 3 placed on the payout stations 6 </ b> A and 6 </ b> B. The ladle 3 charged with hot metal is lifted up by the cranes 4A and 4B, moved to the removal stations 9A and 9B above the discharge stations 6A and 6B and adjacent to the discharge stations 6A and 6B. 8B, the slag floating on the upper surface of the hot metal is scraped off.
The ladle 3 from which the slag has been scraped is transferred to one of the three converters 2A, 2B, 2C by the cranes 4A, 4B, tilting the converter 2, and tilting the ladle 3 The hot metal is charged into the converter 2.

In the converter 2 charged with hot metal, a lance is inserted from the furnace port of the converter 2 and brought close to the upper surface of the hot metal, and oxygen gas is blown at the same time. To start. At the same time, the slag forming and iron oxide Fe _x O _y or the like coolant such as lime CaO, i.e. the auxiliary raw material input. Phosphorus in the hot metal reacts with the charged oxygen and shifts to the slag phase, and starts laminating above the hot metal (dephosphorization). Furthermore, the carbon in the hot metal reacts with oxygen and CO. It is discharged as gas (decarburization). By this blowing process, molten steel having a predetermined phosphorus and carbon concentration can be obtained.

When the blowing process in the converter 2 starts, the empty ladle 3 is returned again to the discharge stations 6A and 6B by the cranes 4A and 4B, and the molten iron is again ready to be discharged.
FIG. 3 shows the movement of the cranes 4A and 4B and the accompanying movements when the number of ladles 3 arranged in the payout stations 6A and 6B is one and the total number of ladles 3 is three. A Gantt chart showing details of the movement (logistics) of the ladle 3 is shown.
FIG. 3A is a Gantt chart in the conventional converter facility 101 shown in FIG. In the conventional converter apparatus 101, the removal stations 109A and 109B are provided above the discharge stations 106A and 106B, and the discharge stations 106A and 106B and the removal stations 109A and 109B are the same in plan view. The point existing at the partition number position is greatly different from the present converter facility 1. In addition, in the conventional example, the operating number of ladles 103 is two.

Regarding the movement of the cranes 104A and 104B, first, the crane 104A grips the empty ladle 103 and installs it in the dispensing station 106A (pit A). Thereafter, hot metal is discharged from the kneading wheel 105 to the ladle 103, and component measurement and temperature measurement are performed. Then, the ladle 103 is suspended by the crane 104A, lifted upward, and transferred to the removal station 109A.
At this time, the ladle 103 that has been suspended by the crane 104B is arranged at the dehulling station 109B, and the slag in the ladle 103 is scraped out by the throat oyster 108B. Thereafter, the ladle 103 of the crane 104B is transferred to the position of the converter 102A, and the hot metal is charged into the converter 102A. After the hot metal charging is completed, the ladle 103 that has been emptied is transported and installed in the payout station 106B, and the hot metal discharge starts. At this time, the crane 104B is in a waiting state over the dispensing station 106B.

Under the situation where the hot metal discharge at the discharge station 106B has progressed to some extent, the removal of the ladle 103 suspended from the crane 104A is completed. The hot metal is charged into the converter 102B from the ladle 103. At this time, in order to smoothly move the crane 104A, the crane 104B is moved to the front of the converter 102C at the same time.
The ladle 103 that has been charged into the converter 102B is moved again to the position of the discharge station 106A by the crane 104A and installed, and one cycle of the crane 104A is completed.

At this time, the crane 104B that has been withdrawn before the converter 102C (separation number 6) moves to the upper side of the dispensing station 106B, and lifts the ladle 103 for which the component measurement and the temperature measurement are completed again. This completes one cycle of the crane 104B.
In the present embodiment, the ladle 103, the crane 104, and the payout station 106 always correspond to each other, and it is always the fixed crane 104 that holds a certain ladle 103, and the ladle 103 is always the same payout station. 106. It can be seen from FIG. 3A that the time required for one cycle of the crane 104, that is, the cycle time, is 33 minutes.

Considering the number of ladles placed on the dispensing station 6, as can be seen from FIG. 3A, the number of ladles is 0 or 1, and the ladle 3 is arranged at the dispensing station 6 at all. There is a situation that does not exist.
On the other hand, FIG. 3 (b) shows the movement of the crane 4 of this embodiment and the movement (distribution) of the three ladles 3 associated therewith.
Regarding the movement of the crane 4, the crane 4 </ b> A first installs the empty ladle 3 on the dispensing station 6 </ b> B. Thereafter, the ladle moves to the dispensing station 6A, and the ladle 3 in which the hot metal component measurement and the temperature measurement are completed is lifted up and transferred to the demolition station 9A. In this removal station 9A, the ladle 3 is in a suspended state, and the slag in the ladle 3 is scraped out by the throat oyster 8A.

At that time, the crane 4B is suspending another ladle 3, and the ladle 3 is disposed in the dehulling station 9B, and the slag is removed by the blade 8B. When such removal is completed, the crane 4B moves to the front of the converter 2A, and the hot metal is charged from the ladle 3 into the converter 2A. The ladle 3 that has been emptied after the hot metal charging is completed is transported and installed in the discharge station 6A while being suspended by the crane 4B, and the discharge of the hot metal starts.
The situation where the ladle 3 is installed on the payout station 6A is indicated by the P part in the Gantt chart, which means that the R ′ part in FIG. Looking at the situation of part P from another point of view, the crane station 9A and the payout station 6A are separated by one crane in plan view, so that the crane 4 can be located at both stations simultaneously. This means that the removal of the hot metal and the discharge of the hot metal are performed in parallel, and the hot metal supply process is efficiently advanced. Case C in FIG. 7 corresponds to this situation, and since the conventional crane (case A) has a cycle time of 33 minutes / time, the removal station 9A and the dispensing station 6A are separated from each other. The crane cycle is shortened to 29 minutes / time.

Thereafter, the crane 4B does not wait for the hot metal discharge of the ladle 3 in the payout station 6A to be completed, but hangs the ladle 3 in the adjacent payout station 6B filled with hot metal. Meanwhile, the crane 4A waits at the position of the demolition station 9A in order to wait for this lifting.
The crane 4B that lifts the ladle 3 of the payout station 6B is best if it moves to the removal station 9B as it is, but it is necessary to move the ladle 3 in the removal station 9A before the converter 2A. Therefore, it once moves to the front of the converter 2C (escapes).

  The crane 4A moves to the front of the converter 2B so as to follow the crane 4B, and the hot metal is charged into the converter 2B. The ladle 3 which has been emptied and is emptied is always installed in the dispensing station 6 (in this case, the dispensing station 6B) in which one ladle is empty, and the next hot metal is charged (Fig. 3 (b) Q part). Immediately thereafter, the crane 4 </ b> A hangs the ladle 3 after the completion of the hot metal charging disposed in the dispensing station 6 </ b> A without waiting for the hot metal charging to the ladle 3 to end. This completes one cycle of the crane 4B. In the case of the present embodiment, it can be seen that the time (cycle time) required for one cycle of the crane 4 is 29 minutes from FIG. The crane 4B that had escaped before the converter 2B (separation number 5) moved to the removal station 9B adjacent to the crane 4A when the crane 4A moved to the discharge station 6B. To do.

Considering the number of ladles placed in the dispensing station 6, as can be seen from FIG. 3 (b), when the cranes 4A and 4B arrive at the dispensing stations 6A and 6B, the number of ladles is one. Yes, the number of payout stations is -1 = 2-1 = 1.
As described above, the payout stations 6A and 6B are always ready to receive the next ladle 3, and the crane 4 with the ladle 3 placed in the empty station has no waiting time. 3 can be handled, the ladle 3 can be distributed very efficiently, and the hot metal supply to the converter 2 can be performed efficiently.

In addition, in this embodiment, in order to further reduce the cycle time of the crane 4, the converter facility 1 is provided with a standby station 13 for repairing the ladle 3 and collecting metal.
In addition, a crane is prepared so that one ladle 3 is prepared separately from the number of ladles 3 in operation, and both of them are operated together, and any one of the ladles 3 is arranged at the standby station 13. 4 is operated. In the ladle 3 arranged in the standby station 13, metal and slag adhering to the ladle 3 are periodically removed.

  That is, in order to improve the hot metal supply capability to the converter 2, it is preferable to increase the number of ladles 3 that supply hot metal. However, by increasing the number of operating ladle 3, the circulation time per ladle is extended, and metal and slag are deposited on the slag line of ladle 3. Therefore, in order to perform the converter operation smoothly in response to this, it is preferable to further increase the number of ladles 3 in operation and provide a standby station 13 on which the increased ladle 3 is placed. With regard to the ladle 3 placed at the standby station 13, the bullion and slag are periodically removed, so that the ladles 3 that can be used stably without any bullion or slag are reliably secured. Will be able to.

  However, the ladle 3 in the standby station 13 is an empty ladle that has not received hot metal inside. If the state of the empty pan continues for a long time, the temperature of the refractory inside the ladle 3 decreases, When the hot metal is subjected to hot metal, metal adhesion will occur and stable operation will become difficult. ”“ Heat loss will increase and the temperature of the hot metal charged into the converter 2 will decrease. ”“ Refractory material will be charged. Inconveniences such as “thermal expansion and peeling due to hot metal” occur. Therefore, in the case of the present embodiment, by inserting a burner or the like into the ladle 3 in the standby station 13 to generate a flame, the ladle 3 is heated after taking the bullion and the above problem occurs. I try to prevent. Case D in Fig. 7 corresponds to this situation. In this case, the number of ladles is set to the number of payout pits + 1, and another ladle is used, for a total of 4 ladles. ing.

4 and 5 show a second embodiment of the converter facility.
The converter equipment 1 has a desulfurization station 14A and a desulfurization station 14B, and the desulfurization station 14A and the desulfurization station 14B are respectively arranged on the side of the traveling rail 7 at the positions 1 and 2 of the traveling rail 7. Has been. In addition, the front blades are arranged at the position of the partition number 0 to form the removal station 9, and two converters 2A and 2B are provided. Other configurations are substantially the same as those in the first embodiment.
The ladle 3 is moved in the converter facility 1 after the kneading vehicle 5 arrives at the converter facility 1 and then from the kneading vehicle 5 to the ladle 3 placed on the dispensing stations 6A and 6B. Is poured. The ladle 3 charged with hot metal is transferred to the desulfurization stations 14A and 14B, and by adding auxiliary materials such as CaO to the hot metal at the desulfurization station 14, the sulfur S in the hot metal is transferred to the slag layer. The sulfur component (S) in the hot metal is predetermined. In each of the desulfurization stations 14A and 14B, throat oysters 8A and 8B for scraping out the slag generated by the desulfurization process are installed, and the generated slag is scraped out.

The ladle 3 in which the hot metal after the desulfurization treatment is charged is transferred by the cranes 4A and 4B to any one of the converters 2A and 2B, and the converter 2 is tilted and the ladle 3 is tilted. Then, the hot metal is discharged into the converter 2.
In the present embodiment, the ladle 3 is handled by the cranes 4A and 4B so that the number of the ladles 3 arranged in the desulfurization stations 14A and 14B becomes “total number of desulfurization stations−1”. In other words, the idea for using the crane 4 most efficiently applied to the dispensing station 6 is applied to the desulfurization station 14.

  Specifically, one ladle 3 is disposed on one of the two desulfurization stations 14A or 14B (the number of desulfurization stations −1 = 2-1 = 1), and the desulfurization process is waiting or the desulfurization process is being performed. Yes. At the same time, the other desulfurization station 14B or 14A is always empty. Therefore, since the cranes 4A and 4B can immediately hold the ladle 3 adjacent to the ladle 14B or 14A after installing the ladle 3 in either the desulfurization station 14A or 14B, the logistics of the ladle 3 It is performed very efficiently, and the hot metal supply to the converter 2 can be performed efficiently.

FIG. 6 shows a Gantt chart corresponding to the desulfurization process of the converter facility 1 described above. The operating number of ladle 3 is three.
In this Gantt chart, for example, paying attention to part P, the crane 4A moves to the dispensing station 6A immediately after placing the ladle 3 charged with hot metal in the desulfurization station 14B, without waiting, and dispenses. The ladle 3 that is finished is hung.
Further, paying attention to the portion Q, the crane 4B hangs the ladle 3 where the roasting 8 of the desulfurization station 14B has ended immediately after installing the empty ladle 3 in the dispensing station 6B. Paying attention to the R portion, the crane 4B lifts the ladle 3 after the completion of the desulfurization treatment in the desulfurization station 14A immediately after the empty ladle 3 is installed in the payout station 6B.

  On the other hand, paying attention to the S part and the T part of the Gantt chart, the number of operating ladles 3 is also set to “number of payout stations + 1 = 2 + 1 = 3”, so the first ladle 3 is placed in the desulfurization station 14A. When the molten iron is disposed and the hot metal is being processed from the second ladle 3 to the converter 2, it is removed from the third ladle 3 by the front blade 8F. Processing is performed. Thus, since the three ladles 3 are operating in parallel, the hot metal can be supplied to the converter 2 very efficiently. Case B in FIG. 7 corresponds to this situation, and three ladles are used with the number of ladles as the number of payout pits + 1. As a result, the crane cycle is shortened to 31 minutes / time while the conventional (case A) cycle time is 33 minutes / time.

In addition, the hot metal supply method to the converter of this invention is not limited to the said embodiment.
That is, the first embodiment and the second embodiment are simultaneously operated, and the number of ladles 3 arranged in the payout stations 6A and 6B is one (= the number of payout stations-1), and further, the desulfurization station 14A. When the ladle 3 is handled by the cranes 4A and 4B and the hot metal is supplied to the converter 2 so that the number of ladles 3 arranged in 14B is one (= desulfurization station number -1). Good.
By doing so, both the dispensing stations 6A and 6B and the desulfurization stations 14A and 14B are always in a state of receiving the next ladle 3, and the cranes 4A and 4B are adjacent to each other after the ladle 3 is installed. Thus, the ladle 3 can be gripped immediately, so that the distribution of the ladle 3 is performed very efficiently, and the hot metal supply to the converter 2 can be efficiently performed.

Further, the converter 2 may be any one of a top blowing converter, a bottom blowing converter, and an top bottom blowing converter, and performs a so-called double slag method in which dephosphorization and decarburization are performed in one converter. It can also be applied to converter facilities.
Moreover, the converter equipment 1 should just have at least 1 of the discharge station 6, the removal station 9, the waiting | standby station 13, and the desulfurization station 14, In that case, the operating number of the ladle 3 is "each station. −1 ”may be used as the sum. For example, when the converter facility 1 has only the payout station 6, the operating number of the ladle 3 may be set as “payout station-1”. When the converter equipment 1 has the discharge station 6 and the desulfurization station 14, the operating number of the ladle 3 may be “discharge station-1” + “desulfurization station-1”.

It is a front schematic diagram of the converter equipment concerning a 1st embodiment. It is a plane schematic diagram of the converter equipment concerning a 1st embodiment. It is the Gantt chart in the converter equipment concerning 1st Embodiment, (a) is a prior art example, (b) is a thing of 1st Embodiment. It is a plane schematic diagram of the converter equipment concerning a 2nd embodiment. It is a plane schematic diagram of the converter equipment concerning a 2nd embodiment. It is a part of desulfurization process Gantt chart in the converter equipment of 2nd Embodiment. It is the figure by which the operation performance in each embodiment was shown. It is the plane schematic of the converter equipment in a prior art example.

Explanation of symbols

1 Converter facilities 2 Converters (2A-2C)
3 Ladle 4 Crane (4A, 4B)
5 Chaos vehicle 6 Dispensing station (6A, 6B)
9 Removal station (9A, 9B)
14 Desulfurization station (14A, 14B)

Claims (4)

A converter, a ladle for charging molten iron into the converter, a plurality of dispensing stations where the molten iron is discharged to the ladle, and a ladle for carrying the ladle into or out of the dispensing station Converter with a crane handling in the cycle of
When the crane arrives at the dispensing station, the ladle is handled with the ladle while handling the ladle so that the number of ladles arranged at the dispensing station is “number of dispensing stations −1”. A hot metal supply method to a converter, characterized by supplying the hot metal. A converter, a ladle for charging molten iron into the converter, a plurality of desulfurization stations where desulfurization treatment is performed on the molten iron in the ladle, and a ladle to carry in or out the ladle from the desulfurization station A converter with a crane that handles the
When the crane arrives at the desulfurization station, the ladle is handled while handling the ladle so that the number of ladles arranged at the desulfurization station is “desulfurization station number −1”. A hot metal supply method to a converter, characterized by supplying the hot metal. A converter, a ladle for charging hot metal into the converter, a plurality of discharge stations for discharging hot metal to the ladle, and a plurality of desulfurization stations for performing desulfurization treatment on the hot metal in the ladle A converter having a crane for handling the ladle in a predetermined cycle in order to carry the ladle into or out of the discharge station and the desulfurization station,
When the crane arrives at the payout station, the number of ladles placed at the payout station is “number of payout stations−1”, and when the crane arrives at the desulfurization station, it is placed at the desulfurization station. A hot metal supply method to a converter, characterized in that hot metal is supplied to the converter while handling the ladle with a crane so that the number of ladles is "desulfurization station number -1". A converter, a ladle for charging hot metal into the converter, a plurality of discharge stations for discharging hot metal to the ladle, and a plurality of desulfurization stations for performing desulfurization treatment on the hot metal in the ladle A plurality of dehumidifying stations for removing slag in the ladle, and a crane for handling the ladle in a predetermined cycle so as to carry the ladle into or out of the discharging station, the desulfurization station and the dehumidifying station. Converter equipment,
When the crane arrives at the payout station, the number of ladles placed at the payout station is “number of payout stations−1”, and when the crane arrives at the desulfurization station, it is placed at the desulfurization station. The number of ladles that are disposed is “desulfurization station number −1”, and when the crane arrives at the removal station, the number of ladles that are arranged in the removal station is “the number of removal stations”. The hot metal supply method to the converter is characterized in that the hot metal is supplied to the converter while handling the ladle with a crane so as to be "-1".

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