JP2000001711A - Desulfurization of molten iron and desulfurizing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and a device with which the desulfurization of molten iron can be executed in a short time with a mechanical stirring method while restraining the necessary cost in equipment. SOLUTION: This desulfurization is executed by charging a desulfurizing agent into molten iron in a molten iron ladle and stirring it with an impeller. The impeller is approached to the molten iron surface while rotating it at a low speed, since the impeller dips into the molten iron (time t1), the rotating speed of the impeller is raised, slag on the molten iron is distributed to near the outer periphery of the ladle and in this state, the desulfurizing agent is charged onto the exposed molten iron surface in the vicinity of the center part of the ladle (time t2-t3). The charged desulfurizing agent and the molten iron are stirred with the impeller rotated at a high speed on and after the time t3 in the state of dipping the whole impeller into the molten iron. Thereafter, the rotation of the impeller is decelerated and stopped and the impeller in the stopping state is dipped into the molten iron until the molten iron becomes still (time t5-t6).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot metal desulfurization method and a hot metal desulfurization apparatus for removing sulfur (S) from hot metal contained in a container such as a hot metal ladle.

[0002]

2. Description of the Related Art In a steel mill, hot metal is generally desulfurized for the purpose of efficiently performing a steelmaking process. For desulfurization, lime (CaO) or soda ash (Na ₂ CO ₃ )
This is done by putting a desulfurizing agent into the hot metal, such as an injection method in which the desulfurizing agent is blown through a lance dipped in the hot metal, or a mechanical stirring method in which the hot metal and the desulfurizing agent are stirred by an impeller (rotating blade). Widely known. In the injection method, the injected desulfurizing agent often floats without reacting,
The mechanical stirring method has an advantage that the hot metal and the desulfurizing agent are sufficiently mixed to promote the desulfurization reaction.

The prior art relating to the mechanical stirring method is disclosed in JP-B-42-12343 and JP-A-4-99212.
No., etc. In the former technique, the impeller is rotated at 150 to 300 rpm with an outer diameter of 1/10 to 1/3 of the inner diameter of the hot metal pot. Such a small-diameter impeller should be used to efficiently entrain the desulfurizing agent in the hot metal surface into the hot metal and promote desulfurization efficiently, reduce the power required for stirring, and suppress the wear on the inner wall surface of the hot metal pot. He says that it is better to rotate at a very high speed. In the latter, two stages of impellers are provided on one shaft, and a pressurized gas outlet is formed in each stage of the impeller. By jetting a desulfurizing agent into the hot metal together with the pressurized gas from the jet port of each impeller, the hot metal can be strongly stirred to promote desulfurization. Regarding the mechanical stirring method, besides the above,
It is also described in 166908. According to the publication,
Stirring the hot metal by rotating the impeller forward and backward is said to be preferable in terms of accelerating desulfurization and suppressing impeller wear.

[0004]

Since the desulfurization of hot metal is performed prior to steelmaking, in order not to delay the start of the steelmaking process, the desulfurization of hot metal in a hot metal pot must be performed before the steelmaking process. It must be completely completed before the process is completed. For example, a steelmaking process using a converter is normally performed in about 40 minutes at a time, so hot metal desulfurization, which is the preceding process, is not completed in about 40 minutes or less in a single hot metal ladle as well. This delays the start of the next steelmaking process and lowers productivity. Therefore, in recent steelworks where the steelmaking process has been accelerated, it is required to reduce the required time for the hot metal desulfurization process.

[0005] As for the steelmaking process, in recent years, there has been an example in which a first converter for dephosphorizing hot metal and a second converter for decarburization thereafter are used in order. If such a process is adopted, the duration of hot metal in the first converter is about half of the normal converter usage time (about 20 minutes), and the desulfurization in the hot metal pot is about half of the conventional level. It must be completed in time.

[0006] However, the conventional hot metal desulfurization means cannot sufficiently cope with the above-mentioned demands for speeding up in recent steel works. In other words,
The technique described in Japanese Patent No. 2343 uses an impeller having a smaller diameter than the inner diameter of the hot metal pot, so it is difficult to give a high stirring flow to the entire hot metal in the hot pot, and when starting stirring, etc. It takes time to accelerate hot metal. In other words, in the case of this technology, a steady (that is, high-speed rotation) stirring state must be maintained for a long time in order to obtain a required desulfurization rate (sulfur content), Since a long acceleration time is required, it is difficult to sufficiently desulfurize the hot metal in the pot in a short time.

[0007] The technique described in Japanese Patent Application Laid-Open No. 4-99212 adds a stirring effect of a pressurized gas to the stirring effect of an impeller, so that an effect of promoting desulfurization can be expected. However, the configuration is complicated, for example, a two-stage impeller is provided on the shaft and a gas ejection port is formed in each impeller. The impeller immersed in hot metal is a consumable and must be manufactured in large numbers. Therefore, if the configuration of the impeller is complicated, considerable cost is required.

In the technique disclosed in Japanese Patent Application Laid-Open No. S61-166908, the rotation of the hot metal is temporarily stopped every time the rotation direction of the impeller is changed, which is disadvantageous in terms of time (the time required for desulfurization increases). There is. In addition, if the rotation direction of the impeller is rapidly changed, there arises a problem that the hot metal undulates and overflows from the container, and the rotational driving force of the impeller becomes enormous. No specific means for avoiding such inconvenience is described in the publication.

An object of the present invention is to provide a method and an apparatus for desulfurizing hot metal which can smoothly perform hot metal desulfurization by a mechanical stirring method in a short period of time while suppressing required equipment costs. .

[0010]

According to a first aspect of the present invention, there is provided a method for desulfurizing hot metal in a container such as a hot metal ladle by adding a desulfurizing agent and stirring the molten metal with an impeller. Method, in which the impeller is brought close to the hot metal surface from above while rotating at a low speed, and when the impeller enters the hot metal, the rotation speed of the impeller is increased to increase the slag (also called slag or slag) on the hot metal. ) Is distributed near the outer periphery of the container, and in that state, a desulfurizing agent is charged onto the hot metal surface exposed near the center of the container, and the charged desulfurizing agent and hot metal are rotated at a high speed at a position where the entire hot metal is immersed in the hot metal. The impeller is stirred, and then the rotation of the impeller is reduced and stopped, and the stopped impeller is immersed in the hot metal until the hot metal calms down. Note that the terms “low speed” and “high speed” refer to a relative speed relationship between the two,
For example, it does not mean that the rotational speed is higher or lower than that of the conventional desulfurization method.

According to such a desulfurization method, desulfurization of the hot metal in the vessel can be completed in a shorter time than before. The reason is as follows.

A) As described above, the impeller is rotated before being immersed in the hot metal. By doing so, the time required for the acceleration of the impeller is reduced to some extent by the time required for the desulfurization step, rather than starting to rotate the impeller after being immersed in the hot metal. The effect is great when the impeller is large (especially one having a large inertia due to a large outer diameter).

B) As described above, the slag on the hot metal is distributed toward the outer periphery of the container, and the desulfurizing agent is injected onto the exposed hot metal surface. It is preferable to add the desulfurizing agent as soon as possible so that the desulfurization reaction starts earlier.However, even if the desulfurizing agent is added while the floating slag covers the entire upper surface of the hot metal, the desulfurizing agent is blocked by the slag. Hard to contact with hot metal. In this regard, in the above method, first, the slag is sorted out, and a desulfurizing agent is injected onto the exposed hot metal surface. In this way, the entire amount of the desulfurizing agent immediately and effectively comes into contact with the hot metal to start the reaction, and as a result, sufficient desulfurization can be achieved in a short time.
The slag distribution described above does not mix the hot metal and the slag but statically distributes them by centrifugal force without disturbing the positional relationship between the two layers separated from each other. If you use
It can be easily realized by rotating it at a relatively low speed.

C) Conventionally (for example, the aforementioned Japanese Patent Publication No. Sho 42)
This is because an impeller having a larger outer diameter can be used. With such a large-diameter impeller, as long as it is completely immersed in the hot metal and provides sufficient rotational driving force (torque), the hot metal can be brought into a steady stirring state in a shorter time than with a small-diameter impeller. Can be accelerated. Also, if a large-diameter impeller is completely immersed in hot metal, the desulfurization process can be accelerated because most of the hot metal in the vessel can be agitated even if the rotation speed in a steady stirring state is set lower than before. be able to. Moreover, increasing the diameter of the impeller does not lead to a significant increase in cost (for example, as compared with the case of the above-mentioned Japanese Patent Application Laid-Open No. 4-99212). Therefore, this desulfurization method enables desulfurization of hot metal in a short time without causing a significant increase in cost. The effect of using an impeller with a large outer diameter can be improved because the acceleration time is reduced as in a) above, and without rotating at high speed as in b). By enabling the desulfurizing agent to be effectively introduced into the hot metal, and by gradually decelerating and stopping the impeller rotated at a high speed in the above, even when using an impeller with a large outer diameter, the hot metal undulates. Was made gentle.

D) In the above, the stopped impeller is immersed in the hot metal until the hot metal calms down.
Normally, the rotation of the hot metal in the vessel decelerates later than the deceleration of the impeller, and usually continues to rotate slowly even when the impeller stops. In such a case, if the impeller in the stopped state is immersed in the hot metal as it is, the rotation of the hot metal can be stopped in a short time. When the hot metal comes to rest quickly, the probe for temperature measurement and sampling, which is generally made of a paper tube, can be smoothly inserted into the hot metal without being bent by the flow of the hot metal, and the desulfurization treatment of the hot metal can be performed. It can be completed in a short time. The effect of stopping the hot metal is more remarkable when the impeller is large.

A method of desulfurizing hot metal according to a second aspect is characterized in that the impeller rotated at high speed is decelerated and stopped as described above, and then temporarily reversed.

Although the hot metal normally continues to rotate as described above even after the impeller has decelerated and stopped, depending on the state of rotation, it may be better to temporarily reverse the impeller in this way. By rotating the impeller for a while in the direction opposite to the rotating direction of the hot metal, the hot metal can be stopped more quickly. As described above, if the hot metal is quickly suppressed, the temperature measurement and sampling can be performed quickly, and the desulfurization treatment can be completed in a short time.

According to a third aspect of the present invention, there is provided a method for desulfurizing hot metal in addition to the above, in which 30 to 50% of the inner diameter of the
Use the one with the outer diameter of
It is also characterized in that the rotation speed is 50 rpm and the high-speed rotation is 70 to 150 rpm. When desulfurization of hot metal is performed by using an impeller having a larger outer diameter as compared with the conventional one in this way, the following effects are obtained.

First, although the impeller is immersed in the hot metal surface while rotating the impeller as described above, even at the moment of the immersion, the hot metal and slag do not scatter around.
In order to reduce the time required for accelerating the impeller, it is better to rotate the impeller at a high speed from the point of approaching the hot metal, but then a part of the impeller (lower end)
Hot metal and slag may be scattered when only hot metal (again slag) is immersed in the surface. However, when the impeller is rotated at the low speed (10 to 50 rpm) as described above, there is no such inconvenience.

The impeller having an outer diameter as large as 30 to 50% of the inner diameter of the container is 70 to 150 in the above.
By rotating at a speed of rpm (although "high-speed rotation" is lower than the conventional speed), a sufficient stirring effect is brought about and the desulfurization reaction is promoted. This is because the outer diameter of the impeller with respect to the container is large, so that an effective stirring flow is formed with respect to most of the hot metal in the container, thereby actively contacting the hot metal and the desulfurizing agent to promote the desulfurization reaction. Moreover, at such a rotational speed, it is possible to prevent the hot metal from overflowing or scattering from the container except when an extremely large amount of hot metal is contained in the container.

The impeller having such a large outer diameter has the effect of quickly stopping the hot metal when it is immersed in the hot metal in a stopped state or reversed in the above. This is because a large impeller against the rotating flow causes a great resistance to the flow of the hot metal.

According to a fourth aspect of the present invention, there is provided a hot metal desulfurization apparatus, in which an AC motor (such as an induction motor) is used together with a primary frequency control device (such as an inverter or a cycloconverter) as a rotation driving means of an impeller to realize the above desulfurization method. ) Is provided.

In order to realize the above hot metal desulfurization method,
It is necessary to change the rotation speed of the impeller at least between the low speed and the high speed. In order to accelerate the impeller rotating at low speed in hot metal in a short time,
It is also required to apply a high torque to the impeller from a low speed state. In order to meet such a demand, this desulfurization apparatus having the above-described rotary drive means is preferable.

That is, in the AC motor to which the control device of the primary frequency is connected, the frequency of the power supply can be changed widely by the device, so that the rotation speed can be changed steplessly and smoothly over a wide range. is there. Further, a constant torque output can be generated by changing the voltage in proportion to the frequency, so that high torque can be exhibited even at low speed rotation. for that reason,
It is easy to change the rotation speed of the impeller as described in the above and to make such a speed change quickly. In addition, if the AC motor has a primary frequency control device, it is easy to reverse the rotation direction.

When selecting a motor other than the above, for example, a motor whose rotation speed can be changed by pole number conversion or the like, a motor having a large frame number (that is, a large motor) is required to satisfy the required torque at low speed. become. Also, when a hydraulic motor is used, a considerable amount of oil is required, and the hydraulic supply device becomes large. Under such circumstances, it can be said that the desulfurization apparatus configured as described above is an extremely preferable means for performing hot metal desulfurization in a short time while suppressing the equipment cost.

[0026]

1 to 4 show an embodiment of the present invention. FIG. 2 is a side view generally showing the hot metal pot 30 and the apparatus 1 for desulfurizing the hot metal 35 placed therein. FIG. 1 shows a hot metal 3 by the apparatus 1 of FIG.
Rotation speed (rotation speed) of impeller 2 when performing desulfurization of No. 5
FIG. 3 is a graph showing the relationship between the desulfurization treatment time and the ultimate value of the sulfur content in the hot metal 35 in the case of the apparatus 1 in FIG. 2, and FIG. 4 is a graph showing the relationship between the rotation speed of the impeller 2 and the load torque of the motor 21 in FIG. The hot metal pot 30 shown in FIG.
Has a capacity enough to receive about 250 tons of hot metal 35 at one time and to desulfurize it.

The apparatus 1 shown in FIG. 2 has an impeller 2
Is immersed in hot metal 35 in hot metal pot 30 and rotated, and is configured as follows. That is, the cage 10 is placed directly above the hot metal ladle 30 so that it can be raised and lowered.
Is provided. A pulley 11 is provided at an upper part of the cage 10,
A wire (not shown) is wound around it from above.
A plurality of guide wheels 12 are arranged on the side of the cage 10 and are arranged along a guide track (not shown) that extends vertically. Therefore, by winding or unwinding the wire wound around the pulley 11, the cage 10 vertically moves up and down along the guide track. The apparatus 1 has such a cage 10 holding the impeller 2 and its rotary drive means 20.

The rotation driving means 20 includes an AC motor (cage-shaped induction motor) 21 mounted on the cage 10 and a reduction gear 2
3 and the output shaft 2 connected to it and extending downward
4 and the like, and the shaft 3 of the impeller 2 is connected below the output shaft 24 via the joint 4. Since the impeller 2 and its shaft 3 are immersed in hot metal at a high temperature, a ceramic material having excellent heat resistance and the like is attached to the outside. Outer diameter d of impeller 2 in device 1
(For example, about 1.5 m) is the inner diameter D of the hot metal pot 30 (the inner diameter near the upper surface 35 a of the hot metal 35. For example, about 3.7 m).
And one impeller 2 is used until the outer diameter d is worn down to about 35% of the inner diameter D due to contact with hot metal or the like.

The major feature of the rotation driving means 20 is that
That is, the inverter 22 is provided in the power supply unit of the motor 21 described above. The inverter 22 is a primary-frequency control device that temporarily converts commercial power into direct current and converts the commercial power into alternating-current power of an arbitrary frequency and supplies it to the motor 21. In the example of FIG. 2, a transistor inverter is used. If this is used, so-called VVVF (Variable Voltage V)
By controlling the ariable frequency, a squirrel-cage induction motor having a simple structure can be used as the motor 21, but the rotation speed can be arbitrarily changed over a wide range and the output torque can be kept constant. .

The hot metal 35 placed in the hot metal pot 30 and conveyed to a predetermined desulfurization position (the position in FIG. 2) is desulfurized by using the above-described apparatus 1 as follows.
When the hot metal pot 30 containing the hot metal 35 is transported to a predetermined position as shown in FIG. 2, the motor 21 is started and kept at a low speed.
The cage 10 is lowered as it is. Impeller 2 is about 1
While rotating at a low speed of 5 rpm, it approaches the hot metal surface 35a from above as shown in FIG. In FIG. 1, the rotation speed of 15 rpm from the left of time 0 (zero) indicates that the motor 21 is started before the cage 10 starts to be lowered (the time is set to 0). Since the impeller 2 having a large outer diameter is used, the rotation is started early so that the time required for the acceleration does not delay the desulfurization treatment.

When the lower end of the impeller 2 reaches the height of FIG. 2B and comes into contact with the hot metal surface 35a (time t ₁ ), the rotation speed of the impeller 2 is increased to a medium speed. In this example, the rotation speed is 45 rpm as shown in FIG.
The speed is increased at a rate of about 1.5 rpm per second until the speed is reached, and these are controlled by the speed control of the motor 21 by the inverter 22. With such a medium speed rotation, when the impeller 2 is above the hot metal 35 (for example, when the upper portion is still above the hot metal surface 35a)
Also, the hot metal 35 is not scattered from the hot metal pot 30 to the outside. While rotating at that speed, impeller 2
If the slag is kept at a deep position in the hot metal 35 (the height of (C) in FIG. 2) for several tens of seconds, the layered slag floating on the hot metal surface 35a becomes closer to the outer periphery of the hot metal pot 30 by the action of centrifugal force. Near the center (around the shaft 3 of the impeller 2)
The hot metal surface 35a without slag is exposed. Then the hot metal surface 35a is exposed, introducing a desulfurizing agent (such as lime or soda ash) from an upper opening of the hot metal pan 30 towards it (time t ₂ ~t _3). Since the desulfurizing agent directly enters the hot metal 35 without coming into contact with the slag layer, the desulfurization reaction starts simultaneously with the charging.

When the addition of the desulfurizing agent is completed (time t ₃ ), the impeller 2 is rotated at a high speed. In this example, the high-speed rotation is set at 135 rpm as shown in FIG. 1, and the speed is increased by about 1.5 rpm per second until reaching this value. Of course, this point is also controlled by controlling the speed of the motor 21 by the inverter 22. And during this time,
The position of the impeller 2 is the height (hot metal surface 35) of FIG.
(a height from a to 0.9 m from the upper end of the impeller 2). The impeller 2 has a large outer diameter and a small width (vertical dimension) (for example, about 1
m), so even if rotated at such a relatively low speed,
The hot metal 35 can be quickly accelerated, and a sufficient stirring flow can be given to almost the entire hot metal 35 in the hot metal pot 30.
Therefore, the high-speed stirring for a predetermined time (approximately 7 and a half minutes as shown in FIG. 1) causes the previously added desulfurizing agent to quickly diffuse into the hot metal 35 and the desulfurization reaction to proceed rapidly.

The rotation of the impeller 2 is reduced and stopped (time t ₅ ) from the time when a predetermined stirring time has elapsed (time t ₄ ). The deceleration is also performed by the inverter 21 and the motor 21.
, The speed is reduced by about 1.5 rpm per second. Since the rotation of the hot metal 35 is slower than the deceleration of the impeller 2, the impeller 2 receives torque from the motor 21 in the reverse direction during the period. Even if the rotation speed of the impeller 2 is set to zero, the hot metal 35 in the hot metal pot 30 is still rotating slowly.
After stopping, it is rotated in the reverse direction for several tens of seconds at the position (C) described above, and then stopped again (time t).
₆ ). When the impeller 2 having a large outer diameter is reversely rotated in this way, the hot metal 35 in the hot metal pot 30 can be quickly stopped. Depending on the rotational state of the molten iron at time t _5, the impeller 2 may keep while stopped without reverse. When the hot metal 35 is substantially stationary, a probe (not shown) or the like is inserted into the hot metal 35 from the hot metal surface 35a, and temperature measurement and sampling of the hot metal 35 are performed. If the result of the temperature measurement and sampling is good, it means that desulfurization of the hot metal 35 of the hot metal pot 30 has been completed. Therefore, the impeller 2 is raised to a height higher than (A) in FIG. To the steelmaking process (converter, etc.).

According to the above procedure, the desulfurization of the hot metal 35 in one hot metal pot 30 is performed for about 1 hour as shown in FIG.
It can be finished in 3 minutes. Therefore, for example, even in the case where steelmaking is performed using the first and second two converters (not shown) in series (described above), charging of hot metal into the first converter is delayed. Can be repeated without.

For the stirring described above, the rotation speed and rotation time of the impeller 2 are determined based on the graph shown in FIG. FIG. 3 illustrates a case where the hot metal 35 in the hot metal pot 30 is desulfurized by the apparatus 1 described above.
5 is a graph showing a relationship between a stirring time at a high speed rotation and a reached value of a sulfur content in the hot metal 35 in FIG. “135 rpm” and “150 rpm” in the drawing indicate the rotation speed of the impeller 2. In the above example, 3000 ppm before desulfurization
(0.3%) Sulfur content in hot metal 35 around 25ppm
(0.0025%).
Accordingly, the rotation speed of the impeller 2 is set to 135 rpm, and the high-speed rotation time is set to about 7.5 minutes. If the impeller 2 having the same size and shape is rotated at 150 rpm, the rotation time can be less than 6 minutes according to FIG.

Since the resistance of the hot metal 35 acts as a load on the impeller 2 rotating in the hot metal 35, the motor 21 needs to generate a considerable torque. FIG. 4 shows the relationship between the rotation speed of the impeller 2 in the hot metal 35 and the load torque of the motor 21 to be applied to the impeller 2 to maintain the rotation speed. First, when the impeller 2 is used under the above-described conditions, the relationship shown by the solid line in the figure is obtained. Until the relationship between the rotation speed and the load torque becomes substantially linear and the rotation speed of the impeller 2 is set to 145 rpm or more, the load torque is equal to or less than the rated output torque of the motor 21 (the two-dot chain line in FIG. 4). It can be seen that it is kept. By the control by the inverter 22, the rated output torque of the motor 21 is controlled to be constant irrespective of the rotation speed (excluding a low-speed range (30 rpm or less) not shown in the figure). The torque required to accelerate the impeller 2 is approximately 1.5 rpm per second as described above.
m, about 4 kg
m and small.

As the impeller 2 is used repeatedly, the outer ceramic material is worn and the outer diameter is reduced. When the outer diameter is reduced, the load received by the impeller 2 from the hot metal 35 is reduced. Therefore, it is preferable to maintain the stirring effect of the hot metal 35 by further increasing the rotation speed of the impeller 2 in the above-described manner. The diagram shown by the broken line in FIG. 4 indicates that when the outer diameter d decreases and the ratio (d / D) to the inner diameter D of the hot metal pot 30 becomes about 35% (that is, when the impeller 2 immediately before replacement is used). 4) shows the relationship between the load torque of the motor 21 and the rotation speed of the impeller 2. Since the load torque is low even at the same rotation speed, even if the rotation speed of the impeller 2 is about 150 rpm or more, the motor 21
It does not exceed the rated torque. The fact that the rotation speed of the impeller 2 can be adjusted in accordance with the degree of wear and the stirring effect of the hot metal 35 can be maintained is also an advantage of the speed control function of the inverter 22.

[0038]

The method for desulfurizing hot metal according to claim 1 has the following effects. A) Since the impeller is rotated before being immersed in the hot metal, the time required for desulfurization is reduced by the time required for accelerating the impeller when the outer diameter of the impeller is large.

B) Since the slag on the hot metal is distributed near the outer periphery of the container and the desulfurizing agent is put on the exposed hot metal surface, the entire amount of the desulfurizing agent immediately and effectively starts reacting with the hot metal. At the end of desulfurization. This procedure can be easily realized by using an impeller having a large outer diameter.

C) Since an impeller having a larger outer diameter can be used than before, hot metal can be accelerated in a short time, and most of the hot metal can be stirred even if the rotation speed is set lower than before, so that desulfurization treatment is promoted. It is possible.

D) After the stirring, the stopped impeller is immersed in the hot metal so that the hot metal calms down quickly, so that temperature measurement and sampling with a probe are performed quickly to complete the desulfurization treatment of the hot metal in a short time. Can be done.

E) As described above, shortening the desulfurization time of hot metal also promotes speeding up of the steel making process in an integrated steel mill.

F) Almost no increase in equipment cost.

In the case of the method for desulfurizing hot metal according to the second aspect, g) the impeller is temporarily reversed after the stirring is completed.
Depending on the rotating state of the hot metal after stirring, the hot metal can be stopped more quickly and the desulfurization treatment can be shortened.

In the method for desulfurizing hot metal according to the third aspect, particularly, h) the hot metal or slag is scattered around even at the moment of immersion, despite being immersed in the hot metal surface while rotating the impeller. There is no.

I) An effective stirring flow is formed in the hot metal in the container without the hot metal overflowing or scattering from the container, and the desulfurization reaction of the hot metal is sufficiently promoted.

J) Since the impeller has a large outer diameter, the impregnated hot metal can be quickly stopped by immersing it in the stopped or inverted state in hot metal, thereby shortening the time required for desulfurization.

In the desulfurization apparatus for hot metal described in claim 4,
K) The AC motor connected to the primary frequency control device can change the rotation speed over a wide range and generate an output with constant torque characteristics. It is possible to

L) There is also an effect that the equipment cost can be reduced as compared with the case where another type of electric motor or hydraulic motor adopting pole number conversion or the like is used.

M) There is also an advantage that the rotation speed is adjusted according to the degree of wear of the impeller, so that the effect of stirring the hot metal can be stably maintained.

[Brief description of the drawings]

FIG. 1 shows an embodiment of the invention, and FIG. 1 is a diagram showing a temporal change in the rotation speed of an impeller 2 when desulfurizing hot metal 35 by the apparatus 1 in FIG.

FIG. 2 is a side view generally showing a hot metal pot 30 and an apparatus 1 for desulfurizing hot metal 35 placed therein.

FIG. 3 is a graph showing the relationship between the desulfurization treatment time and the ultimate value of the sulfur content in the hot metal 35 when the hot metal 35 is desulfurized by the apparatus 1 of FIG.

FIG. 4 shows the rotation speed of the impeller 2 and the motor 2 in the hot metal 35.
6 is a graph showing a relationship with No. 1 load torque.

[Explanation of symbols]

 2 impeller 20 rotation drive means 21 AC motor 22 inverter (control device of primary frequency) 30 hot metal pot (vessel) 35 hot metal

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[Procedure amendment]

[Submission date] April 16, 1999 (1999.4.1
6)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0010

[Correction method] Change

[Correction contents]

[0010]

According to a first aspect of the present invention, there is provided a method for desulfurizing hot metal in a container such as a hot metal ladle by adding a desulfurizing agent and stirring the molten metal with an impeller. Desulfurization method),
It has an outer diameter of 30-50% of the inner diameter of the container as an impeller
Using shall, the impeller from above while being allowed <br/> the low-speed rotation of 10~50rpm close to the hot metal surfaces, impeller on hot metal by increasing the rotational speed of the impeller from when entering the molten iron The slag (also called slag or slag) is distributed near the outer periphery of the container, and in that state, a desulfurizing agent is put on the hot metal surface exposed near the center of the container. Agitated by an impeller that rotates at a high speed of 70 to 150 rpm at a position where the hot metal is immersed, and then the rotation of the impeller is reduced and stopped, and the impeller in a stopped state is immersed in the hot metal until the hot metal calms down. I do. Note that the terms “low speed” and “high speed” refer to a relative speed relationship between the two,
For example, it does not mean that the rotational speed is higher or lower than that of the conventional desulfurization method.

[Procedure amendment 3]

[Document name to be amended] Statement

[Correction target item name] 0012

[Correction method] Change

[Correction contents]

A) As described above, the impeller is rotated before being immersed in the hot metal. By doing so, the time required for the acceleration of the impeller is reduced to some extent by the time required for the desulfurization step, rather than starting to rotate the impeller after being immersed in the hot metal. The effect is great because the impeller is large (especially one having a large moment of inertia due to its large outer diameter).

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0013

[Correction method] Change

[Correction contents]

B) As described above, the slag on the hot metal is distributed toward the outer periphery of the container, and the desulfurizing agent is injected onto the exposed hot metal surface. It is preferable to add the desulfurizing agent as soon as possible so that the desulfurization reaction starts earlier.However, even if the desulfurizing agent is added while the floating slag covers the entire upper surface of the hot metal, the desulfurizing agent is blocked by the slag. Hard to contact with hot metal. In this regard, in the above method, first, the slag is sorted out, and a desulfurizing agent is injected onto the exposed hot metal surface. In this way, the entire amount of the desulfurizing agent immediately and effectively comes into contact with the hot metal to start the reaction, and as a result, sufficient desulfurization can be achieved in a short time.
Incidentally, the distribution of the slag as described above, rather than stir the hot metal and slag, because it is intended to allocate statically by centrifugal force without disturbing the positional relationship between separated in layers, the outer diameter as described above Large impeller etc.
It can be easily realized by using it and rotating it at a relatively low speed.

[Procedure amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0014

[Correction method] Change

[Correction contents]

C) Conventionally (for example, the aforementioned Japanese Patent Publication No. Sho 42)
This is because an impeller having a large outer diameter is used . With such a large-diameter impeller, as long as it is completely immersed in the hot metal and gives sufficient rotational driving force (torque), compared to a small-diameter impeller,
Hot metal can be accelerated to a steady stirring state in a short time. Also, if a large-diameter impeller is completely immersed in hot metal, the desulfurization process can be accelerated because most of the hot metal in the vessel can be agitated even if the rotation speed in a steady stirring state is set lower than before. be able to. Moreover, increasing the diameter of the impeller does not lead to a significant increase in cost (for example, as compared with the case of the above-mentioned Japanese Patent Application Laid-Open No. 4-99212). Therefore, this desulfurization method enables desulfurization of hot metal in a short time without causing a significant increase in cost. The effect of using an impeller with a large outer diameter can be improved because the acceleration time is reduced as in a) above, and without rotating at high speed as in b). By enabling the desulfurizing agent to be effectively introduced into the hot metal, and by gradually decelerating and stopping the impeller rotated at a high speed in the above, even when using an impeller with a large outer diameter, the hot metal undulates. Was to be calm-
based on.

[Procedure amendment 6]

[Document name to be amended] Statement

[Correction target item name] 0015

[Correction method] Change

[Correction contents]

D) In the above, the stopped impeller is immersed in the hot metal until the hot metal calms down.
Normally, the rotation of the hot metal in the vessel decelerates later than the deceleration of the impeller, and usually continues to rotate slowly even when the impeller stops. In such a case, if the impeller in the stopped state is immersed in the hot metal as it is, the rotation of the hot metal can be stopped in a short time. When the hot metal comes to rest quickly, the probe for temperature measurement and sampling, which is generally made of a paper cylinder, can be smoothly inserted into the hot metal without being bent by the flow of the hot metal, and the desulfurization treatment of the hot metal can be performed. It can be completed in a short time. The effect of stopping the hot metal is more remarkable when the impeller is large. The desulfurization method of claim 1 has the following
There is also an action like First, as described above
Although it is immersed in the hot metal while rotating the impeller,
Hot metal and slag scatter around even at the moment of immersion
There is no. In the sense of reducing the time required to accelerate the impeller
Is rotated at a high speed from the point when the impeller approaches the hot metal.
It is better to turn it over, but then, a part of the impeller
Only the lower end was immersed in the hot metal (against slag)
Hot metal and slag may be scattered in some cases. But,
Rotate the impeller at the low speed (10-50 rpm) as described above.
There is no such inconvenience when it is turned over. Container
Impeller with a large outside diameter of 30-50% of the inside diameter
In the above, a speed of 70 to 150 rpm ("high
Rotation at a lower speed than before)
This provides a sufficient stirring effect and promotes the desulfurization reaction.
Proceed. Due to the large outer diameter of the impeller with respect to the container,
Creates an effective agitated flow for most of the hot metal in the vessel
Then, active contact between hot metal and desulfurizing agent is carried out to
Because it promotes Moreover, the rotation speed of that level
Except when extremely hot metal is contained in the container
To prevent hot metal from overflowing and scattering from the container
Can be Also, the impeller with such a large outer diameter is
In the stop state (or reverse as in claim 2 below)
Hot metal in a hot rolled state.
It has the effect of stopping immediately. Large against rotating flow
Kin impeller has great resistance to hot metal flow
Because.

[Procedure amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0018

[Correction method] Change

[Correction contents]

The method for desulfurizing hot metal according to claim 3 is characterized in that
Distribute the slag on the hot metal as shown
When the impeller enters the hot metal,
It is characterized in that it is maintained at a medium speed which has been raised from above.

[Procedure amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0019

[Correction method] Change

[Correction contents]

As described above, medium-speed rotation that does not reach high-speed rotation
Slag on the hot metal surface can be distributed closer to the outer periphery
In addition, when the impeller is on top of the hot metal,
This has the effect of preventing the pig from scattering from the hot metal pot to the outside.

[Procedure amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0020

[Correction method] Deleted

[Procedure amendment 10]

[Document name to be amended] Statement

[Correction target item name] 0021

[Correction method] Deleted

[Procedure amendment 11]

[Document name to be amended] Statement

[Correction target item name] 0038

[Correction method] Change

[Correction contents]

[0038]

The method for desulfurizing hot metal according to claim 1 has the following effects. A) Since the impeller is rotated before being immersed in the hot metal, the time required for desulfurization is reduced by the time required for accelerating the impeller, despite the large outer diameter of the impeller.

[Procedure amendment 12]

[Document name to be amended] Statement

[Correction target item name] 0040

[Correction method] Change

[Correction contents]

[0040] c) To use a larger impeller outside diameter than conventional, upon which can be accelerated in a short time hot metal, to promote the desulfurization process because it stirred most of the molten iron be set conventionally low rotational speed It is possible.

[Procedure amendment 13]

[Document name to be amended] Statement

[Correction target item name] 0041

[Correction method] Change

[Correction contents]

D) After the stirring, the stopped impeller is immersed in the hot metal so that the hot metal calms down quickly, so that temperature measurement and sampling with a probe are performed quickly to complete the desulfurization treatment of the hot metal in a short time. Can be done. I
This effect is remarkable because the outer diameter of the impeller is large.

[Procedure amendment 14]

[Document name to be amended] Statement

[Correction target item name] 0043

[Correction method] Change

[Correction contents]

F) Almost no increase in equipment cost. g) Rotate the impeller on the hot metal surface while rotating
Hot metal and slag scatter around even at the moment of immersion
Nothing. h) Do not allow hot metal to overflow or scatter from the container.
And an effective stirring flow is formed in the hot metal in the vessel,
The desulfurization reaction of the hot metal is sufficiently promoted.

[Procedure amendment 15]

[Document name to be amended] Statement

[Correction target item name] 0044

[Correction method] Change

[Correction contents]

In the method for desulfurizing hot metal according to the second aspect, further, i) the impeller is temporarily reversed after the completion of the stirring.
Depending on the rotating state of the hot metal after stirring, the hot metal can be stopped more quickly and the desulfurization treatment can be shortened.

[Procedure amendment 16]

[Document name to be amended] Statement

[Correction target item name] 0045

[Correction method] Change

[Correction contents]

In the case of the method for desulfurizing hot metal according to the third aspect , in particular, j) the method of distributing the slag on the pig surface toward the outer periphery also has
When the impeller is on top of the hot metal,
Especially preferred.

[Procedure amendment 17]

[Document name to be amended] Statement

[Correction target item name] 0046

[Correction method] Deleted

[Procedure amendment 18]

[Document name to be amended] Statement

[Correction target item name] 0047

[Correction method] Deleted

Continued on the front page (72) Inventor Satoshi Tatsuta 3-1-1 Higashikawasakicho, Chuo-ku, Kobe Kawasaki Heavy Industries, Ltd. Kobe Plant (72) Inventor Sumio Sato 3-1-1 Higashikawasakicho, Chuo-ku, Kobe-shi No. Kawasaki Heavy Industries, Ltd. Kobe Plant F-term (reference) 4K014 AA02 AC01 AC08

Claims (4)

[Claims] 1. A method for desulfurizing hot metal in a container by adding a desulfurizing agent and stirring with an impeller, wherein the impeller is brought close to the hot metal surface from above while rotating at a low speed, and the impeller enters the hot metal. From when the impeller rotation speed was increased and the slag on the hot metal was distributed to the outer periphery of the vessel,
In this state, a desulfurizing agent is charged onto the hot metal surface exposed near the center of the vessel, and the charged desulfurizing agent and hot metal are stirred by an impeller that rotates at high speed at a position where the entire hot metal is immersed in the hot metal. A method for desulfurizing hot metal, comprising reducing the rotation speed and stopping, and immersing the impeller in a stopped state in the hot metal until the hot metal calms down. 2. The method for desulfurizing hot metal according to claim 1, wherein the impeller rotated at a high speed is decelerated and stopped as described above, and then the impeller is temporarily reversed. 3. The impeller has an inner diameter of 30 to 50 as an impeller.
% Of the outer diameter, and the above low speed rotation is 10
The hot metal desulfurization method according to claim 1 or 2, wherein the high-speed rotation is set to 70 to 150 rpm. 4. A hot metal desulfurization method according to claim 1, wherein an AC motor is provided together with a primary frequency control device as a rotation driving means of the impeller to realize the hot metal desulfurization method according to any one of claims 1 to 3. Desulfurization equipment.