JP2009174029A - Method for operating converter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To restrain the formation of stuck bare metal while avoiding any trouble caused by the stuck bare metal in the opening part of a converter and the lowering of a productivity, accompanied with the prevention of this trouble. <P>SOLUTION: When molten iron 13 is blown in the converter 3, according to the distributing state of the stuck bare metal in the converter, any one of two kinds of top-blowing lances 8, 9 of the following (a) and (b), is selected and blown. (a) The top-blowing lance 8 is the one, in which one or more oxygen gas spouting nozzles for blowing are arranged at the lower end part, and at least one of the oxygen gas spouting nozzles has a gas supplying hole for controlling on the wall surface of the fan-state part, and the direction and/or the flowing speed of the jet spouted from the oxygen gas spouting nozzle for blowing can be controlled by supplying the gas for controlling from the supplying hole for controlling. (b) The top-blowing lance 9 is the one, in which the one or more of oxygen gas spouting nozzles for blowing, are arranged at the lower end part, and further, on the outer circumferential part, a gas spouting nozzle for melting the stuck bare metal, is arranged. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a converter operating method in which oxygen gas is blown from an upper blowing lance to hot metal in a converter and oxidative refining is performed on the hot metal, and more specifically, to the converter furnace mouth and side wall by spitting or the like. The present invention relates to an operation method for suppressing the adhesion of gold and performing stable converter refining.

  In converter refining, in which oxygen gas is blown up through an upper blowing lance, molten iron, molten steel, and part of the slag scattered during spitting and slopping generated during oxygen blowing are part of the converter mouth and furnace. It adheres to the inner wall as a bullion. Adhered bullion grows as it continues to operate, and when its size exceeds a certain limit, it not only hinders the introduction of hot metal and scrap into the furnace, but the bullion is bathed in the bath during blowing. Dropping into the melt or flowing down causes fluctuations in the composition and temperature of the bath, causing a significant hindrance to the operation. There is also a risk of damaging the refractory underneath the attached bullion if it is not properly removed. Therefore, while reducing the occurrence of spitting and slopping and aiming for an operation method in which adhesion and growth of bullion is less likely to occur, the bullion once adhered is removed before it becomes large enough to interfere with operation. There is a need.

  In order to reduce the occurrence of spitting, the top blowing lance has been improved conventionally, and methods such as making the blowing oxygen gas injection nozzle porous and increasing the inclination angle have been adopted. For example, in Patent Document 1, two types of Laval nozzles having different inclination angles are alternately arranged in the circumferential direction as oxygen gas injection nozzles for blowing, thereby overlapping the gas jets injected from these nozzles. Techniques for suppressing and reducing spitting are disclosed. However, in the methods that have been reported in the past including Patent Document 1, especially when the oxygen gas supply flow rate (also referred to as “acid feed rate”) is increased to shorten the blowing time, Neither generation nor adhesion of bullion has been suppressed, and it is still necessary to remove bullion attached to the furnace port.

  As a method for removing the furnace-hole-attached metal, there is a traditional method in which a scrap chute is collided with the furnace-hole-attached metal and physically removed. However, since this method directly hits the scrap chute against the furnace-portion metal part, there is a risk of dropping the furnace-port brick due to the impact.

  Further, Patent Document 2 discloses a method of melting and removing a bare metal adhering to the furnace port by inserting a dedicated top blowing lance for melting a bare metal from the furnace port into the furnace during non-operation. However, this method is excellent in removing the adhering metal, but it must be carried out at the time of non-blowing of the converter, leading to an increase in non-steel time and significantly impairing converter productivity. Therefore, in order not to hinder the productivity of the converter, the exhaust gas generated in the furnace during secondary blowing is subjected to secondary combustion, and the heat is used to dissolve and remove the metal that has adhered to the furnace mouth and the inner wall of the furnace. A method has been proposed.

  For example, Patent Document 3 discloses a method in which a blowing oxygen gas is sprayed from a blowing oxygen gas injection nozzle provided at the tip of an upper blowing lance to a hot metal while being spaced apart from the blowing oxygen gas injection nozzle by a predetermined interval. A method is disclosed in which oxygen gas is injected toward the inner wall of the furnace from a metal injection gas injection nozzle installed on the side surface of the blowing lance to dissolve and remove the ingot in the furnace. However, in the method using secondary combustion in the furnace, it is difficult to control the secondary combustion rate. In particular, when the amount of attached metal is reduced, the refractory is damaged by the secondary combustion heat. There is a difficulty that it is easy. In the present invention, an upper blowing lance capable of injecting a bullion melting gas simultaneously with an oxygen gas for smelting is referred to as an “upper lance for blowing and bullion melting”, and only the bullion melting gas is injected. An upper blowing lance that can be supplied is called an “upper blowing lance for melting metal”, and an upper blowing lance that can supply only the oxygen gas for blowing is called an “upper blowing lance for blowing”.

  Furthermore, Patent Document 4 discloses a top lance for blowing that can supply only the oxygen gas for blowing, and simultaneously with the supply of the oxygen gas for blowing, the flow rate control is independent of the oxygen gas for blowing. Damage to the refractory at the converter furnace mouth and the inner wall of the furnace by properly using two types of top blowing lances, the blowing blast and blast metal melting top blowing lance that can supply oxygen gas for melting ingots The technique which suppresses formation of adhesion metal is disclosed. However, this method can reduce the risk of abnormal damage to the refractory when using an upper blowing lance for blowing and melting metal, but measures are taken to reduce the occurrence of spitting that causes adhesion metal. Therefore, it is necessary to operate while switching the upper blowing lance in a relatively short period of time. In addition, since the position and injection angle of the metal injection gas injection nozzle provided on the outer periphery of the upper blowing lance for blowing and metal dissolution cannot be changed once installed, If the position where the gold is easy to melt does not match, the dissolution efficiency of the ingot metal does not increase, and the frequency of continuous use of the top blowing lance for blowing and melting metal increases, resulting in abnormal refractories. In some cases, damage may occur.

By the way, in the patent document 5, the present inventors, when performing decarburization refining of hot metal or dephosphorization of hot metal using a converter, the shape of the oxygen gas injection nozzle for blowing, the lance height, oxygen gas Without changing the supply flow rate, it is possible to control the oxygen gas jet even with one top blowing lance, so that melting of the metal adhering to the furnace, molten heat deposition due to increased secondary combustion, and high-speed blowing are possible. As an upper blowing lance capable of achieving smelting, “an upper blowing lance having at least one gas injection nozzle having a throat portion at an inlet portion and a divergent portion downstream of the throat portion, At least one of the gas injection nozzles has at least one control gas supply hole arranged on the wall surface of the divergent portion of the nozzle, and supplies the control gas from the control gas supply hole. Before Direction and / or flow rate of the jet to be injected from the gas injection nozzle is proposed lance "over to being controlled. According to Patent Document 5, since the direction and / or flow velocity of the gas jet injected from the gas injection nozzle is controlled by the control gas supplied from the control gas supply hole, the gas injection nozzle is used for blowing. By using it as an oxygen gas injection nozzle, the effect of being able to arbitrarily adjust soft blow and hard blow is exhibited. However, it is difficult to dissolve the adhered metal using only the top blowing lance disclosed in Patent Document 5.
JP-A-6-57320 JP-A-4-354814 JP-A-8-127812 JP 2000-96122 A JP 2007-77489 A

  As described above, in the conventional technology, it is difficult to completely prevent the adhesion of the bullion by improving the top blowing lance and the operation method, while the technique for removing the adhered bullion remains a problem. .

  The present invention has been made in view of the above circumstances, and the object of the present invention is to convert oxygen in the molten iron in the converter through an upper blowing lance to perform the oxygen refining of the molten iron in the converter furnace. While avoiding troubles caused by the metal sticking to the mouth and the decrease in productivity due to measures to prevent it, the formation of the stick metal is highly suppressed, and the refractories on the furnace mouth and the inner wall of the furnace It is to provide a converter operation method that does not damage the furnace.

  As a result of intensive studies to solve the above problems, the present inventors have obtained the following knowledge.

  That is, when melting the adherent metal at the furnace mouth and inner wall of the converter, a wide range of adhered metal is melted and removed without damaging the base refractory, so that the profile of the furnace mouth and the inner wall of the furnace is good. In order to maintain the flow rate, the upper blowing lance that supplies only the oxygen gas for blowing (the upper blowing lance for blowing) and the flow of the blowing oxygen gas at the same time as the blowing oxygen gas are supplied. Two types of top blowing lances (top blowing lances for blowing and bullion melting) that can supply controllable metal melting gas are properly used and blown using top blowing lances for blowing. Two types of top blowing lances are configured so that the position where bullion easily adheres to the position where bullion using the top lance for blowing and melting metal matches the position where bullion tends to melt. And found that combining is extremely effective.

  The amount and position of adhesion of the bullion to the furnace port and the inner wall of the furnace with the oxygen gas for blowing are greatly affected by the inclination angle of the oxygen gas injection nozzle for blowing. Generally, when the inclination angle of the oxygen gas injection nozzle for blow smelting is made small (close to the vertical downward direction), the spitting grains are likely to jump upward in the vertical direction, and the adhesion of the metal near the furnace mouth increases. On the other hand, if the inclination angle of the oxygen gas injection nozzle for blowing is increased (closer to the horizontal direction), the metal near the side of the side wall furnace tends to grow. However, as the number of times the converter is used increases, the refractory in the furnace wears out, and the shape of the ingot in the furnace does not always grow due to the change in the shape of the furnace. Therefore, a technology that finely adjusts the tilt angle of the oxygen gas injection nozzle for blowing according to the operation status while reflecting changes in the furnace shape, etc. Is required.

  As described above, the present inventors have disclosed a method of substantially changing the inclination angle of the gas injection nozzle by applying a fluid element in Patent Document 5. That is, in a so-called Laval nozzle type gas injection nozzle having a throat portion at the inlet portion and a divergent portion downstream of the throat portion, a control gas supply hole is arranged on the wall surface of the divergent portion, and this control This is a technique for freely changing the jet direction of the jet jetted from the gas jet nozzle by changing the flow rate of the control gas supplied to the gas supply hole. The gas injection nozzle of this configuration is applied to the blowing oxygen gas injection nozzle that supplies only the blowing oxygen gas, and the tilt angle of the blowing oxygen gas injection nozzle is substantially adjusted by adjusting the flow rate of the control gas. As a result, it was found that the position where the metal is easily attached and the position where the metal is easily dissolved can be matched by fine adjustment.

The present invention has been made on the basis of the above knowledge, and the converter operating method according to the present invention includes supplying oxygen gas from an upper blowing lance and blowing hot metal in the converter, According to the distribution state of the attached bullion, select one of the two types of top blowing lances (b) and (b) below, and perform blowing using the selected top blowing lance. It is what.
(A) An upper blowing lance provided with one or more blowing oxygen gas injection nozzles for injecting blowing oxygen gas at the lower end, the blowing oxygen gas injection nozzle having a throat at the inlet And at least one of the blown oxygen gas injection nozzles supplies at least one control gas to the wall surface of the divergent portion. The control gas supply hole is supplied with a control gas whose flow rate can be controlled independently from the blowing oxygen gas, and is injected from the blowing oxygen gas injection nozzle. A blown top lance capable of controlling the direction and / or flow rate of the generated jet.
(B) One or more blown oxygen gas injection nozzles for injecting blown oxygen gas at the lower end, and an outer periphery where flow rate can be controlled independently of the blown oxygen gas An upper blowing lance for melting and melting a bullion provided with a gas injection nozzle for melting a bullion supplying oxygen-containing gas and / or purge gas for dissolving gold.

  According to the present invention, the direction of the oxygen gas jet injected from the blowing oxygen gas injection nozzle of the upper blowing lance for blowing can be controlled. Adhesion can be reduced, and the adhesion position of the metal can be adjusted to a position where it can be easily dissolved by the upper blowing lance for blowing and metal melting. Therefore, the operation with the upper blowing lance for blowing can be continued for a long period of time, and if the adhering metal has grown to some extent, switching to the upper blowing lance for blowing and melting the metal, Adhesive metal can be removed efficiently, and stable converter operation and converter productivity can be improved.

  Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a schematic diagram of an example of a converter facility used for carrying out the present invention.

  In FIG. 1, two types of an upper blowing lance 8 for blowing and an upper blowing lance 9 for blowing and bullion melting are applied to a converter body 2 having an iron shell 3 as an outer shell and a refractory 4 inside thereof. The top blowing lances can be inserted into the converter main body 2 through the furnace port 5. The upper blowing lance 8 for blowing is an upper blowing lance for supplying oxygen gas for blowing from the lower end thereof, while the upper blowing lance 9 for melting and melting metal is blown from the lower end thereof. This is an upper blowing lance for supplying a working oxygen gas and supplying a purge gas such as an oxygen-containing gas or a nitrogen gas for dissolving a metal from the outer peripheral portion thereof. The oxygen-containing gas includes oxygen gas.

  Further, the converter main body 2 is provided with a hot water outlet 6 at the upper part of the side wall and a plurality of bottom blowing tuyere 7 at the bottom. The tap 6 is a discharge hole for pouring molten steel obtained by oxygen blowing or hot metal that has been dephosphorized, and the bottom blow tuyere 7 is a stirring gas such as Ar gas or nitrogen gas. It is a device for blowing in. In this way, the converter equipment 1 is configured. In the converter operation, the top blow lance is subjected to a severe heat load, so that the frequency of repair and replacement is generally relatively high. For this reason, in most converter facilities currently in operation, an upper blowing lance and its lifting device are installed in parallel for one converter main body so that the upper blowing lance can be replaced quickly. The equipment configuration. From this point of view, the basic configuration of the converter equipment 1 used in the present invention is not a special equipment, and therefore, no special equipment modification is required to implement the present invention.

  First, the top blowing lance 9 for melting and melting metal used in the present invention will be described in detail with reference to the drawings. FIG. 2 is an enlarged view of the top blowing lance 9 for blowing and melting metal shown in FIG.

  As shown in FIG. 2, the upper blow lance 9 for smelting and melting metal is composed of a cylindrical lance body 9a and a lance tip 9b connected to the lower end of the lance body 9a by welding or the like. The lance body 9a is composed of four types of concentric steel pipes, that is, a quadruple pipe, consisting of an outer tube 24, a partition tube 23, an inner tube 22 and an innermost tube 21, up to the middle. Are formed of three kinds of concentric steel pipes consisting of a partition pipe 23 and an inner pipe 22, that is, a triple pipe, and a copper lance tip 9b at the tip portion has a plurality of blow squeezings directed vertically downward. A working oxygen gas injection nozzle 10 is installed. The center line of each blowing oxygen gas injection nozzle 10 is inclined with respect to the vertical direction, and an angle with respect to the vertical direction is called an inclination angle. In addition, a gas injection nozzle 11 for dissolving a metal bar is provided on the outer peripheral portion of the lance body 9a, which is spaced apart from the tip of the upper blowing lance 9 for blowing and melting a metal bar, in a diagonally downward direction. It has been. From this metal injection gas-discharging nozzle 11, a metal-containing oxygen-containing gas or purge gas is injected.

  The gap between the outer pipe 24 and the partition pipe 23 and the gap between the partition pipe 23 and the inner pipe 22 serve as cooling water flow paths for cooling the upper blowing lance 9 for melting and melting metal. The cooling water supplied from a water supply joint (not shown) provided at the upper part of the upper blowing lance 9 for melting and melting metal is passed through the gap between the partition pipe 23 and the inner pipe 22 and flows into the lance tip 9b. A drainage joint (not shown) provided at the upper portion of the upper blowing lance 9 for blowing and smelting metal through the gap between the outer pipe 24 and the partition pipe 23 by reversing at the portion of the lance tip 9b. Discharged from. In this case, the water supply / drainage path may be reversed.

  The gap between the inner tube 22 and the innermost tube 21 serves as a supply flow path for oxygen-containing gas and / or purge gas to the metal injection gas injection nozzle 11, and an upper blow lance 9 for blowing and metal dissolution. The oxygen-containing gas and / or the purge gas supplied to the gap between the inner pipe 22 and the innermost pipe 21 from the upper end of the gas passes through the gap between the inner pipe 22 and the innermost pipe 21, and the gas injection nozzle 11 for dissolving the metal bar 11. Is ejected into the converter body. The inner tube 22 and the innermost tube 21 are connected directly below the installation position of the lowermost-stage metal melting gas injection nozzle 11, and the innermost tube 21 is disconnected at that position. Here, an example in which the innermost pipe 21 is cut off immediately below the metal injection gas injection nozzle 11 has been shown. However, if the lower end is closed, the position may be further lower, and it is configured on the equipment layout. It is sufficient to make the structure easy. In addition, the purge gas is a gas for holding the metal injection gas injection nozzle 11 so as not to be clogged when the metal dissolution operation is not performed, and nitrogen gas, Ar gas, or the like can be used as the purge gas.

  Further, the inside of the innermost pipe 21 serves as a supply flow path for oxygen gas to the oxygen gas injection nozzle 10 for blowing, and the innermost pipe 21 extends from the upper end portion of the upper blowing lance 9 for blowing and metal melting. The oxygen gas supplied to the inside passes through the inside of the innermost pipe 21, passes through the inside of the inner pipe 22 at the tip, and is jetted from the blowing oxygen gas injection nozzle 10 into the converter main body. In this way, the supply path of the oxygen-containing gas for melting the metal can be controlled independently of the supply path of the oxygen gas for blowing.

  An enlarged view of this blowing oxygen gas injection nozzle 10 is shown in FIG. As shown in FIG. 3, the oxygen gas injection nozzle 10 for blowing is a so-called Laval nozzle type nozzle composed of two cones, a portion whose cross section is reduced and a portion where the cross section is enlarged. The enlarged portion is a divergent portion 27, and the narrowest portion, which is a portion that transitions from the narrowed portion 25 to the divergent portion 27, is called a throat 26. The oxygen gas that has passed through the inside of the lance main body 9 a passes through the throttle portion 25, the throat 26, and the divergent portion 27 in this order, and is injected from the tip of the blowing oxygen gas injection nozzle 10. The injected gas becomes a subsonic to supersonic jet depending on its flow rate. In FIG. 3, Dt is the throat diameter, De is the outlet diameter, and the spread angle θo of the divergent portion 27 is usually 10 degrees or less.

  In addition, in the oxygen gas injection nozzle 10 for the blowing of a Laval nozzle shown in FIG. 3, the throttle portion 25 and the divergent portion 27 are conical, but for the Laval nozzle, the constricted portion 25 and the divergent portion 27 need to be conical. Instead, the inner diameter may be configured by a curved surface, and the throttle portion 25 may be a straight cylindrical shape having the same inner diameter as the throat 26. When the throttle portion 25 and the divergent portion 27 are configured with curved surfaces whose inner diameter changes in a curved manner, an ideal flow velocity distribution as a Laval nozzle can be obtained, but the processing of the nozzle is extremely difficult. In the case of a straight cylindrical shape, it is slightly dissociated from the ideal flow velocity distribution, but there is no problem for use in converter blowing, and the nozzle processing becomes very easy. In the present invention, all these divergent nozzles are called Laval nozzles.

  In addition, as shown in FIG. 1, the gas injection nozzle 11 for dissolving a metal bar is installed in a three-stage distance from the tip of the lance (3-stage configuration), but can take any number of stages, Regardless of whether it is a single stage or a plurality of stages, the effect of the present invention can be fully exerted if the design is performed according to the shape of each converter body 2. Furthermore, although the metal injection gas injection nozzle 11 shown in FIG. 2 is a straight type nozzle, it may have a Laval nozzle shape depending on use conditions. Furthermore, depending on use conditions, the blowing gas oxygen injection nozzle 10 may be vertically downward, and the metal melting gas injection nozzle 11 may be horizontal or upward.

  Next, the top blowing lance 8 for blowing used in the present invention will be described in detail with reference to the drawings. FIG. 4 is an enlarged view of the upper blowing lance 8 for blowing shown in FIG. The blowing lance 8 for blow smelting is similar to the blowing lance 9 for blowing and bullion melting and will be described in some cases.

  As shown in FIG. 4, the upper blow lance 8 for blowing is composed of a cylindrical lance body 8a and a lance tip 8b connected to the lower end of the lance body 8a by welding or the like. Is composed of four types of concentric steel pipes consisting of an outer pipe 20, a partition pipe 19, an inner pipe 18, and an innermost pipe 17, that is, a quadruple pipe. The copper lance tip 8b at the tip is vertically inclined downward. A plurality of blowing oxygen gas injection nozzles 10 facing in the direction are installed. This blowing oxygen gas injection nozzle 10 is a Laval nozzle as shown in FIG. 3 described above, and the center line of each blowing oxygen gas injection nozzle 10 is inclined with respect to the vertical direction. Further, at least one of the blowing oxygen gas injection nozzles 10 is provided with at least one control gas supply hole 12 on the wall surface of the divergent portion 27 thereof. From the control gas supply hole 12, a control gas for controlling the direction and / or flow velocity of the jet injected from the blowing oxygen gas injection nozzle 10 is injected. The control gas can be any type of gas, whether nitrogen gas, air, or Ar gas, but the control gas is ultimately Since it is mixed with the blowing oxygen gas by the blowing oxygen gas injection nozzle 10 and injected, it is desirable that oxygen gas can be used for refining. Hereinafter, an example in which oxygen gas is used as the control gas will be described.

  The gap between the outer pipe 20 and the partition pipe 19 and the gap between the partition pipe 19 and the inner pipe 18 serve as a flow path for cooling water for cooling the upper blowing lance 8 for blowing. Cooling water supplied from a water supply joint (not shown) provided on the upper portion of the upper blowing lance 8 passes through the gap between the partition pipe 19 and the inner pipe 18 to reach the portion of the lance tip 8b. It reverses at the site, passes through the gap between the outer pipe 20 and the partition pipe 19 and is discharged from a drainage joint (not shown) provided at the upper part of the upper blowing lance 8 for blowing. In this case, the water supply / drainage path may be reversed.

  The gap between the inner pipe 18 and the innermost pipe 17 serves as a supply flow path for oxygen gas to the blowing oxygen gas injection nozzle 10, and from the upper end of the upper blowing lance 8 for blowing to the inner pipe 18 and the innermost pipe 18. The oxygen gas supplied to the gap with the inner pipe 17 passes through the gap between the inner pipe 18 and the innermost pipe 17 and is jetted from the blowing oxygen gas injection nozzle 10 into the converter main body. The injected gas becomes a subsonic to supersonic jet depending on its flow rate.

  Further, the inside of the innermost pipe 17 is a supply flow path for the control gas (in this case, oxygen gas) to the control gas supply hole 12, and the innermost pipe from the upper end portion of the upper blowing lance 8 for blowing. An oxygen gas (hereinafter referred to as “control oxygen gas”) supplied to the inside of the control gas 17 passes through the innermost pipe 17 and is injected from the control gas supply hole 12. Thus, the control oxygen gas supply path can be controlled independently of the blowing oxygen gas supply path.

  The control gas supply hole 12 is a device for controlling the direction and / or flow velocity of the jet injected from the blowing oxygen gas injection nozzle 10, and as shown in FIG. Is directed to the outer surface side from the center of the upper blowing lance 8 for blowing, if the flow rate of the control oxygen gas is increased with respect to the flow rate of the blowing oxygen gas, the blowing oxygen gas injection The jet flow injected from the nozzle 10 is further deflected toward the outer peripheral side of the upper blowing lance 8 for blowing and when the inclination angle of the blowing oxygen gas injection nozzle 10 is increased (close to the horizontal direction). Has the same effect. On the contrary, if the flow rate of the control oxygen gas is decreased with respect to the flow rate of the blowing oxygen gas, the jet flow injected from the blowing oxygen gas injection nozzle 10 becomes difficult to be deflected. The same effect as when the inclination angle is decreased (approaching vertically downward) is exhibited. Here, the blown oxygen gas injection nozzle 10 shown in FIG. 4 is oriented obliquely downward, and is generally oriented obliquely downward in this manner, but may be a vertically downward direction.

  Furthermore, another embodiment of the upper blowing lance 8 for blowing used in the present invention will be described with reference to the drawings. FIG. 5 is an enlarged view of an embodiment different from FIG. 4 of the top blowing lance for blowing used in the present invention. Here, in order to distinguish from the upper blowing lance 8 for blowing described above, the blowing upper blow lance of another embodiment is indicated as “upper blowing lance 8A for blowing”.

  As shown in FIG. 5, the upper blow lance 8A for blowing is composed of a cylindrical lance body 8c and a lance tip 8d connected to the lower end of the lance body 8c by welding or the like. Is composed of four types of concentric steel pipes consisting of an outer tube 20, a partition tube 19a, a partition tube 19b, and an inner tube 18, that is, a quadruple tube, and a copper lance tip 8d at the tip is vertically inclined downward. A plurality of blown oxygen gas injection nozzles 10 facing the direction are installed. This blowing oxygen gas injection nozzle 10 is a Laval nozzle as shown in FIG. 3 described above, and the center line of each blowing oxygen gas injection nozzle 10 is inclined with respect to the vertical direction.

  Further, at least one of the blowing oxygen gas injection nozzles 10 is provided with at least one control gas supply hole 12 on the wall surface of the divergent portion 27 thereof. . From the control gas supply hole 12, a control gas for controlling the direction and / or flow velocity of the jet injected from the blowing oxygen gas injection nozzle 10 is injected. As the type of the control gas, any type of gas can be used, whether it is nitrogen gas, air, or Ar gas, as in the case of FIG. Since the control gas is finally mixed with the blowing oxygen gas by the blowing oxygen gas injection nozzle 10 and injected, it is desirable that oxygen gas can be used for refining. Hereinafter, an example in which oxygen gas is used as the control gas will be described.

  The gap between the outer pipe 20 and the partition pipe 19a and the gap between the partition pipe 19b and the inner pipe 18 serve as a cooling water flow path for cooling the upper blowing lance 8A for blowing. Cooling water supplied from a water supply joint (not shown) provided at the upper part of the upper blow lance 8A passes through the gap between the partition pipe 19b and the inner pipe 18 to reach the site of the lance tip 8d. It reverses at the site, passes through the gap between the outer pipe 20 and the partition pipe 19a, and is discharged from a drainage joint (not shown) provided at the upper part of the upper blowing lance 8A. In this case, the water supply / drainage path may be reversed.

  The inside of the inner pipe 18 serves as a supply flow path for oxygen gas to the blowing oxygen gas injection nozzle 10, and oxygen gas supplied from the upper end of the blowing upper blowing lance 8 </ b> A to the inside of the inner pipe 18. Is injected into the converter body from the oxygen gas injection nozzle 10 for blowing. Further, the gap between the partition pipe 19a and the partition pipe 19b serves as a supply flow path for the control oxygen gas to the control gas supply hole 12, and the partition pipe 19a and the partition pipe are separated from the upper end of the upper blowing lance 8A for blowing. The control oxygen gas supplied to the gap between the pipes 19b is injected from the control gas supply hole 12. Thus, the control oxygen gas supply path can be controlled independently of the blowing oxygen gas supply path.

  The control gas supply hole 12 is a device for controlling the direction and / or flow velocity of the jet injected from the blowing oxygen gas injection nozzle 10, and as shown in FIG. Is directed to the center from the outer surface side of the upper blowing lance 8A for blowing, if the flow rate of the control oxygen gas is increased relative to the flow rate of the blowing oxygen gas, the blowing oxygen gas injection When the jet flow injected from the nozzle 10 is further deflected toward the center axis side of the upper blowing lance 8A for blowing, and the inclination angle of the blowing oxygen gas injection nozzle 10 is reduced (approached vertically downward) Has the same effect as On the contrary, if the flow rate of the control oxygen gas is decreased with respect to the flow rate of the blowing oxygen gas, the jet flow injected from the blowing oxygen gas injection nozzle 10 becomes difficult to be deflected. The same effect as when the tilt angle is increased (close to the horizontal direction) is exhibited. Here, the blown oxygen gas injection nozzle 10 shown in FIG. 5 is directed obliquely downward, and generally is directed obliquely downward as described above, but may be a vertically downward direction.

  The above-mentioned two types of top blowing lances 8 and 8A and equipment for supplying gas to the top blowing lances 9 for blowing and metal melting have specifications common to both top blowing lances. ing. That is, the valve stand is provided with two types of lines, a high flow rate line and a low flow rate line, and the oxygen gas for blowing to the upper blowing lances 8 and 8A for blowing and blowing The oxygen gas for blowing to the upper blowing lance 9 for melting gold is supplied from a high flow rate line, and the oxygen gas for control and the upper blowing for melting and blowing molten metal are supplied to the upper blowing lances 8 and 8A for blowing. The oxygen-containing gas for dissolving the metal to the lance 9 is supplied from a low flow rate line.

  The outline | summary is demonstrated below about the form of the operation using the above-mentioned 2 types of top blowing lances 8 and 8A for blowing, and the top blowing lance 9 for blowing and metal melting | dissolving.

  When the converter main body 2 is started up after repairing the furnace, there is no metal in the furnace and at the furnace port 5, so the upper blow lance 8 for blowing or the upper blow lance 8 A for blowing is used to Blowing that is not intended for melting operation is performed for one charge or more. At this time, the flow rate of the control oxygen gas is blown under a predetermined reference condition. Part of the hot metal 13 and the slag 14 scattered by spitting and slopping generated during the blowing process adheres to the furnace port 5 and the furnace inner wall of the converter body 2 as a bare metal.

  After the completion of the charge blowing, the blowing operator visually observes the state of the metal attached to the furnace port 5 and the furnace inner wall of the converter body 2. In FIG. 1, the bullion attached to the furnace port 5 (hereinafter referred to as “furnace port attached bullion”) is denoted by reference numeral 15, and the bullion attached to the inner wall of the furnace (hereinafter referred to as “side wall attached bullion”). Is denoted by reference numeral 16. On the other hand, the selection standard of the bullion adhesion situation and the type of top blowing lance to be used for it is determined in advance. This selection criterion shall be based on quantitative estimation of attached metal and attached shape.

  If it is determined that “requires bullion melting operation” in accordance with the above criteria, switch to the upper blow lance 9 for blowing and bullion melting, and at least one charge for blowing and bullion melting after the next charge Blow using the top blow lance 9. After completion of the blowing, the blowing operator visually observes the melting state of the furnace mouth adhering metal 15 and the side wall adhering metal 16 adhering to the converter main body 2, and based on the above selection criteria, It is determined whether to continue blowing with the upper melting lance 9 for melting gold after the next charge, or to switch to the upper blowing lance 8 for blowing or the upper blowing lance 8A for blowing.

  In this manner, by appropriately switching between the blowing lances 8 and 8A for blowing and the blowing lance 9 for melting and melting metal, the attached metal on the furnace port 5 and the inner wall of the furnace is always appropriate. It is possible to operate within a limited range.

  During this time, the adhesion tendency (position, amount) of the bullion when using the top blowing lance 8 for blowing or the top blowing lance 9 for blowing, and the top blowing lance 9 for melting and melting metal are used. When the upper blow lance 8 for blowing or the upper blow lance 8A for blowing is used to control the adhesion position of the bare metal while grasping the melting tendency of the bare metal (position and amount easy to dissolve) The flow rate of the control oxygen gas can be adjusted. It is also possible to change and adjust the flow rate of the control oxygen gas even within one charge blowing.

  In the case of the top blowing lance 8 shown in FIG. 4, generally, when the flow rate of the control oxygen gas is reduced with respect to the flow rate of the blowing oxygen gas, the blowing oxygen gas injection nozzle 10. The same effect as when the angle of inclination is reduced (nearly vertically downward), the position where the metal sticks and grows easily tends to be in the vicinity of the furnace port 5, and the flow rate of the oxygen gas for blowing When the flow rate of the control oxygen gas is increased, the same effect as when the inclination angle of the blowing oxygen gas injection nozzle 10 is increased (close to the horizontal direction) is obtained, and the position where the metal is easily attached and grown is It changes to a position close to the bottom of the furnace inside the furnace. On the other hand, in the case of the upper blowing lance 8A shown in FIG. 5, if the flow rate of the control oxygen gas is reduced with respect to the flow rate of the blowing oxygen gas, the inclination angle of the blowing oxygen gas injection nozzle 10 is reduced. The position where the same effect as that obtained by increasing the flow rate is obtained and the adhesion and growth of the metal is easy is close to the bottom of the furnace, and the flow rate of the control oxygen gas relative to the flow rate of the blowing oxygen gas Is increased, the same effect as when the inclination angle of the blowing oxygen gas injection nozzle 10 is reduced is obtained, and the position where the metal is easily attached and grown changes to the vicinity of the furnace port 5.

  As described above, according to the present invention, the direction of the oxygen gas jet injected from the blowing oxygen gas injection nozzle provided in the upper blowing lance for blowing can be controlled. In addition, the adhesion of the metal to the converter inner wall can be reduced, and the adhesion position of the metal can be adjusted to a position where it can be easily dissolved by the upper blowing lance for blowing and metal melting. Therefore, the operation with the upper blowing lance for blowing can be continued for a long period of time, and if the adhering metal has grown to some extent, switching to the upper blowing lance for blowing and melting the metal, Adhesive metal can be removed efficiently, and stable converter operation and converter productivity can be improved.

  Here, the metal for dissolving the metal from the gas injection nozzle for dissolving the metal is generally oxygen gas, but may be any oxygen-containing gas and may be mixed with an inert gas. In addition, an industrial pure oxygen gas is normally used for the oxygen gas for blowing.

  The present invention will be described in more detail with reference to examples. The test method is that a 300 ton converter is charged with 310 tons of hot metal, 10 tons of scrap, and a predetermined amount of a slagging agent, and an upper blowing lance for melting and melting metal shown in FIG. Decarburization refining was performed using two types of top-blow lances. The top blowing lance for blowing and melting metal is a gas injection nozzle for melting metal that is provided in 3 steps, 2 meters above the bottom of the lance and 2 points above it at intervals of 1 meter. The gas injection nozzles for dissolving the metal bar were arranged in six holes on the circumference of the outer periphery of the lance at each stage. In addition to the oxygen gas, nitrogen gas and Ar gas are supplied to the metal injection gas injection nozzle as purge gas. The converter equipment used is similar to that shown in FIG.

The flow rate of oxygen gas from the top blowing lance for blowing was 45,000 to 60000 Nm ³ / hr, and about 5% of this was supplied from the control gas supply hole as control oxygen gas. On the other hand, for the top blowing lance for blowing and metal melting, the oxygen gas flow rate from the blowing oxygen gas injection nozzle is 45000 to 60000 Nm ³ / hr, and the oxygen gas flow rate from the metal melting gas injection nozzle is 0 to 0. Adjustment was made within the range of 3000 Nm ³ / hr. Purge gas was supplied when the flow rate of oxygen gas from the metal injection gas injection nozzle was 0 Nm ³ / hr.

  When the top blow lance for blow smelting was used continuously for 28 charges, the ingot metal on the furnace mouth and the inner wall of the furnace grew and reached the preset standard. Switching to the top blowing lance, three consecutive charges were blown up to the 31st charge using the top blowing lance for blowing and metal melting. During this time, the adhesion metal gradually decreased and reached a level that no longer required dissolution. Moreover, when the inside of the furnace was inspected, no damage was observed on the refractory inside the furnace.

  Thereafter, 25-30 charges are continuously blown using an upper blowing lance for blowing, and then 2-5 charges are blown continuously by switching to an upper blowing lance for blowing and melting metal. Operated in a cycle. As a result, it was possible to operate smoothly without excessively growing the attached metal and damaging the refractories in the furnace.

  Thus, by applying the present invention, it has been confirmed that adhesion of metal can be efficiently suppressed without inhibiting damage to the furnace mouth and the inner wall refractory without impairing the productivity of the converter. It was done.

It is the schematic of one example of the converter equipment used in order to implement this invention. It is an enlarged view of the upper blowing lance for blowing and metal melting | dissolving shown in FIG. It is an enlarged view of the oxygen gas injection nozzle for blowing shown in FIG. It is an enlarged view of the top blowing lance for blowing shown in FIG. It is an enlarged view of another example of the top blowing lance for blowing shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Converter equipment 2 Converter body 3 Iron skin 4 Refractory 5 Furnace port 6 Outlet 7 Bottom blowing tuyere 8 Top blowing lance for blowing 8A Top blowing lance for blowing 9 Top blowing lance for blowing and metal melting DESCRIPTION OF SYMBOLS 10 Blowing oxygen gas injection nozzle 11 Metal injection gas injection nozzle 12 Control gas supply hole 13 Hot metal 14 Slag 15 Furnace adhesion metal 16 Side wall adhesion metal 17 Inner pipe 18 Inner pipe 19 Partition pipe 20 Outer pipe 21 innermost pipe 22 inner pipe 23 partition pipe 24 outer pipe 25 throttle part 26 throat 27 end spreading part

Claims (1)

When oxygen gas is supplied from the top blowing lance and hot metal is blown in the converter, the following two types of top blowing (b) and (b) are performed according to the distribution state of the metal attached to the converter. A converter operating method, wherein any one of the lances is selected and blown using the selected top blowing lance.
(A) An upper blowing lance provided with one or more blowing oxygen gas injection nozzles for injecting blowing oxygen gas at the lower end, the blowing oxygen gas injection nozzle having a throat at the inlet And at least one of the blown oxygen gas injection nozzles supplies at least one control gas to the wall surface of the divergent portion. The control gas supply hole is supplied with a control gas whose flow rate can be controlled independently from the blowing oxygen gas, and is injected from the blowing oxygen gas injection nozzle. A top blowing lance capable of controlling the direction and / or flow velocity of the generated jet.
(B) One or more blown oxygen gas injection nozzles for injecting blown oxygen gas at the lower end, and an outer periphery where flow rate can be controlled independently of the blown oxygen gas An upper blowing lance provided with a gas injection nozzle for dissolving a metal in order to supply an oxygen-containing gas for dissolving gold and / or a purge gas.

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