JP5145736B2 - Dephosphorization method of hot metal in converter type refining furnace - Google Patents

Description

  The present invention relates to a hot metal dephosphorization method performed in a converter-type smelting furnace, and more specifically, a degassing that achieves both a large amount of iron scrap (hereinafter simply referred to as “scrap”) and a hot metal dephosphorization reaction. The present invention relates to a phosphorus treatment method.

  In recent years, the required quality for steel materials has become increasingly strict, and reduction of impurity elements typified by phosphorus and sulfur has been demanded. In order to meet such demands, a method of performing a dephosphorization process in the hot metal stage is common in the steel making process. In this hot metal dephosphorization process, gaseous oxygen or iron oxide is blown into the molten iron in the kneading car or hot metal pan together with the iron making agent, or the iron additive is added to the hot metal in the converter and gaseous oxygen is blown into the hot metal. Processes are selected and implemented according to the facilities and environment of each steelworks, including the methods to be performed.

  Among them, the method using a converter has an advantage that a hot metal having a low phosphorus content can be produced in a short time because a large amount of gaseous oxygen can be sprayed onto the hot metal. Moreover, since the hot metal temperature drop during processing can be suppressed as compared with other processes, there is also an advantage that it is advantageous for melting a large amount of scrap. However, since the dephosphorization reaction does not proceed if the hot metal temperature is too high, it is desirable to suppress the hot metal temperature to about 1300 to 1400 ° C. Generally, by adding iron oxide or the like as a coolant to the hot metal temperature, The rise is suppressed.

Recently, the steel industry has also been making efforts to reduce the environmental burden, such as reducing CO ₂ emissions and promoting the recycling of by-products, and also increasing the amount of scrap used in hot metal dephosphorization. Operation is required. However, the hot metal temperature desirable for the hot metal dephosphorization treatment is as low as about 1300 to 1400 ° C. as described above, so that the scrap having a melting point of about 1500 ° C. is completely dissolved in the hot metal dephosphorization time of about 10 to 15 minutes. It is not easy to do.

Therefore, Patent Document 1 discloses a method of limiting the scrap used in the hot metal dephosphorization process to a so-called “lightweight scrap” having a width of 30 mm or less and a thickness of 15 mm or less. In Patent Document 2, in a converter type refining furnace, at least one of the width and the thickness is charged with a scrap of 100 mm or more, and hot metal dephosphorization treatment is performed. If this is the case, a method of performing the next dephosphorization process while leaving the undissolved scrap together with the slag in the smelting furnace is disclosed.
Japanese Patent Laid-Open No. 1-147011 JP-A-8-92618

  However, the above prior art has the following problems.

  In Patent Document 1, lightweight scrap is used, but the scrap generated in the ironworks is mainly large-scale scraps of semi-finished products such as slabs and blooms. Limiting to lightweight scrap is not practical. In addition, it is not desirable to cut scraps such as slabs and blooms to the above-mentioned size because the cost of main raw materials is increased.

  Further, in Patent Document 2, the next dephosphorization process is performed while the undissolved scrap after the dephosphorization process is left in the refining furnace. In this case, the hot metal subjected to the dephosphorization process is intentionally used. I do not leave. In order to carry out the next dephosphorization process while leaving the undissolved scrap, the slag is not discharged after the hot water is discharged, and the slag is left with the undissolved scrap and the next charge process is performed. This is because scrap is discharged at the same time when waste is carried out in the converter type refining furnace. Therefore, in Patent Document 2, since the slag is left in the furnace together with the unmelted scrap in a state where there is almost no hot metal, the slag and undissolved scrap left in the furnace adhere to the furnace bottom and are installed in the furnace bottom. There is a risk that the bottom blowing tuyere will close or that undissolved scrap may roll around in the furnace and close the tap.

  As described above, in hot metal dephosphorization, it is difficult to say that a technology for melting a large amount of scrap has been sufficiently developed, and many points to be improved remain.

  The present invention has been made in view of the above circumstances, and an object thereof is to enable melting of a large amount of scrap including large heavy scrap when dephosphorizing hot metal in a converter type refining furnace. The present invention is to provide a hot metal dephosphorization method.

The method of dephosphorizing hot metal in the converter type refining furnace according to the first aspect of the present invention for solving the above-mentioned problem is to remove the hot metal while melting scrap using a converter type refining furnace having a top bottom blowing function. Among the dephosphorization processes continuously performed in the smelting furnace, the dephosphorization process in which the scrap blending ratio defined by the following formula (1) is 10% or more is performed as the first charge. Phosphorus treatment is performed, and after this dephosphorization treatment, hot metal is poured out while leaving undissolved scrap in the smelting furnace together with part of the molten iron and slag, and then only the hot metal is loaded into the smelting furnace as the second charge. input and subjected to dephosphorization process on the hot metal after the dephosphorization process,倒炉to exit sprue side the refining furnace tapping molten iron and, losses on the opposite side to the smelting furnace exit sprue side after the furnace to discharge the slag from the smelting furnace, and discharge of the slag Later, again, it is characterized in that repeated to the first charge-th and the 2 same dephosphorization and charge eyes.

  The hot metal dephosphorization method in the converter type refining furnace according to the second invention is the first invention, wherein the scrap includes heavy scrap having a thickness or width of 40 mm or more and a unit weight of 100 kg or more. It is a feature.

  The hot metal dephosphorization method in the converter type refining furnace according to the third invention is the first or second invention, wherein after the first charge dephosphorization process, the converter type refining furnace is temporarily turned to a reaction outlet. The furnace is turned down to the side, and a part of the slag flows out from the furnace outlet, and immediately, the furnace is turned down to the hot water outlet to discharge hot metal from the hot water outlet.

  According to the present invention, since the hot water is left while leaving a part of the molten iron together with the undissolved scrap, the highly viscous slag left in the furnace does not directly solidify in contact with the furnace bottom refractory. The problem that undissolved scrap adheres to the furnace bottom and the bottom blowing tuyere is blocked is solved. Also, since the scrap is melted by spending 2 charges, the residence time of the scrap in the furnace can be extended, and not only the heavy scrap can be melted, but also the scraps are mixed and operated equally for each charge. Rather, the amount of scrap that can be melted can be increased. Furthermore, since the number of scraps charged into the converter-type refining furnace is also reduced, the non-treatment time is shortened, and the productivity of the converter-type refining furnace is improved.

  Hereinafter, the present invention will be specifically described. First, the background to the present invention will be described.

  In the hot metal dephosphorization process, to improve scrap solubility, (1) increase the hot metal temperature, (2) increase the melting time, (3) increase the stirring power of the hot metal by the bottom blowing gas, etc. Can be considered. However, if the hot metal temperature is raised, the dephosphorization reaction does not proceed efficiently, and if the melting time is increased, the hot metal dephosphorization treatment time also becomes longer, decarburization proceeds excessively, or the hot metal supply pitch to the subsequent process However, it is not preferable because the production efficiency is lowered. Furthermore, in the method of increasing the stirring force by increasing the flow rate of the bottom blowing gas, carbon can penetrate and diffuse from the scrap surface to lower the melting point of the scrap, but large scraps with a width or thickness of 40 mm or more can be used. It is not so effective as to dissolve completely.

  Thus, when performing dephosphorization of hot metal using a scrap having a width or thickness of 40 mm or more as a cold iron source, it is very difficult to completely dissolve the scrap within a predetermined dephosphorization time as usual. It was difficult.

  In general, in the case of oxygen blowing in a converter-type smelting furnace, when scrap is not melted, the remaining scrap is discharged out of the furnace together with slag at the time of draining after hot water. This is not desirable from the viewpoint of iron yield, but it is very difficult to leave undissolved scrap in the furnace and discharge only the slag. Therefore, in order to leave the undissolved scrap in the furnace, it is conceivable to perform oxygen blowing of the next charge while leaving the slag together with the undissolved scrap without draining after hot water.

  However, in the decarburization blowing of hot metal in a converter, even if scrap is not melted, slag is not left along with it. This is because it is difficult to accurately grasp the amount of unmelted scrap carried over to the next charge. It is because it leads to the production inhibition by generation | occurrence | production of a component deviation. In particular, in the case of decarburization blowing without using dephosphorized hot metal, if this slag residue method is applied, phosphorus, sulfur, Mn, Cr, etc. in the slag will contaminate the hot metal of the next charge, and the component will be removed. The risk of this is further increased.

  On the other hand, in a steelmaking method in which hot metal refining is performed by using one of two or more converters as a dephosphorization furnace and the other as a decarburization furnace, if scrap remains due to blowing in the dephosphorization furnace, The above-mentioned problem does not occur even if the next charge dephosphorization blowing is performed. This is because in the case of dephosphorization blowing, decarburization blowing is refrained in the next process, so the hot metal temperature after dephosphorization treatment and the allowable range of components are wide, and the accuracy as decarburization furnace is required. Because it is not done. Further, in the blowing in the presence of unmelted scrap, the melting of the scrap proceeds while taking latent heat from the molten iron. Therefore, the temperature of the molten iron is unlikely to rise until the melting of the scrap is completed. As described above, since the dephosphorization reaction does not proceed easily as the hot metal temperature becomes higher, the presence of undissolved scrap works advantageously in promoting the dephosphorization reaction.

  However, since the dephosphorization furnace has a lower furnace temperature and higher slag viscosity than the decarburization furnace, it has the property that unmelted scrap and slag are easily welded in the furnace. For this reason, there is a risk that slag and undissolved scrap left in the furnace will adhere to the bottom of the furnace, and the bottom blowing tuyere will close, or undissolved scrap may roll around in the furnace and close the outlet. When undissolved scrap is left without being discarded, it is difficult to perform stable continuous operation.

  The present inventors have conducted extensive experiments to solve these problems that occur when slag remains. As a result, the present inventors have found that the above problem can be avoided by leaving the hot metal leaving a part of the molten iron instead of leaving only the slag together with the undissolved scrap. The solidification temperature of hot metal containing about 4% by mass of carbon is low (about 1200 ° C), hardly solidifies even if left in the furnace, and has a higher specific gravity than slag, so the highly viscous slag left in the furnace This is because the problem that the slag and undissolved scrap adhere to the bottom of the furnace and the bottom blowing tuyere is closed is eliminated.

  The present invention has been made on the basis of such knowledge, and is defined by the following formula (1) among the dephosphorization processes continuously performed using a converter type refining furnace having an upper bottom blowing function. The dephosphorization treatment with a scrap mixing ratio of 10% or more is performed as the first charge, and after this dephosphorization treatment, undissolved scrap is left in the smelting furnace together with a part of the hot metal and slag. The hot metal is discharged, then only the hot metal is charged into the refining furnace as the second charge, and the hot metal is dephosphorized. After the dephosphorizing process, the hot metal is discharged and the slag is discharged from the refining furnace. In addition, after the slag is discharged, the dephosphorization process similar to that in the first charge and the second charge is repeated.

  Hereinafter, an example of carrying out the hot metal dephosphorization method according to the present invention using an upper bottom blowing type converter as a converter type refining furnace will be described with reference to the drawings. FIG. 1 is a schematic cross-sectional view showing an example of a top-bottom blowing type converter equipment used when carrying out the dephosphorization processing method according to the present invention.

  As shown in FIG. 1, the converter equipment 1 contains a hot metal 2 inside thereof and a converter main body 4 for performing dephosphorization refining of the hot metal 2, and is inserted into the converter main body 4. The upper blow lance 7 for supplying gaseous oxygen to the inside of the converter main body 4 that can move in the direction and the furnace port of the converter main body 4 are covered, and the gas generated from the converter main body 4 is collected by a dust collector (see FIG. (Not shown), a hopper 8 for containing quicklime 16 as a refining agent, a hopper 10 for containing iron oxide 17 such as mill scale or iron ore as a dephosphorizing agent, Connected to the hopper 10, the quick lime 16 cut out from the hopper 9 and the iron oxide 17 cut out from the hopper 10 are transported and added to the inside of the converter body 4, and the addition device 13 is connected to the hood 8. Due to the addition device 13 penetrating Quicklime 16 and iron oxide 17 that has been added Te and chute 14 for introducing into the interior of Tenro body 4, and a scrap chute 15 for supplying Supurappu 18 inside the Tenro body 4.

  The hopper 9 is provided with a cutting device 11 for adjusting the amount of quicklime 16 added, and the hopper 10 is provided with a cutting device 12 for adjusting the amount of iron oxide 17 added. The furnace body 4 is provided with a plurality of bottom blowing tuyere 6 for blowing stirring gas such as nitrogen gas or Ar gas at the bottom, and the dephosphorized hot metal 2 is provided at the upper part of the side wall. A hot water outlet 5 for hot water is provided. The scrap chute 15 is lifted and moved by a crane and is inclined, and the scrap 18 is supplied to the inside of the converter main body 4, but the crane is omitted in FIG. 1. Using the converter equipment 1 having such a configuration, the hot metal dephosphorization treatment according to the present invention is performed as follows.

  In the present invention, in the dephosphorization treatment of the hot metal 2 continuously performed in the converter equipment 1 described above, a large amount of scrap 18 is blended in the first charge with one set of two-charge dephosphorization treatment performed continuously. Then, the dephosphorization process is performed, and then the hot metal 2 of the second charge is charged and dephosphorized. By the end of the dephosphorization process of the second charge, a large amount of scrap 18 charged in the first charge is removed. It is intended to dissolve. The dephosphorization process at the first charge will be described in order.

  First, the converter main body 4 is inclined to the side where the scrap chute 15 is installed, and the scrap 18 is charged into the converter main body 4 via the scrap chute 15. The amount of scrap 18 charged is set so that the scrap blending ratio defined by the above equation (1) is 10% or more. The scrap 18 to be used may be a heavy scrap having a thickness or width of 40 mm or more and a unit weight of 100 kg or more. That is, for example, even if it is large, such as crop scrap of a continuous cast slab, it may be charged as it is. After the scrap 18 is charged into the converter main body 4, the hot metal 2 accommodated in a charging pan (not shown) or the like is charged into the converter main body 4 while the converter main body 4 is inclined. . In addition, if the size of the scrap 18 is small and can be charged through the adding device 13 installed on the furnace, the scrap 18 may be continuously charged from the furnace during dephosphorization refining. Is possible. The hot metal 2 used can be processed with any composition.

Before charging the hot metal 2 into the converter main body 4, blowing of a non-oxidizing gas such as nitrogen gas or a rare gas such as Ar gas from the bottom blowing tuyere 6 is started as the stirring gas. Is blown into the hot metal 2 from the bottom blowing tuyere 6 while supplying gaseous oxygen from the top blowing lance 7 toward the bath surface of the hot metal 2 and adding quick lime 16 to carry out dephosphorization refining for the first charge. To do. The quicklime 16 is melted to form the slag 3, and the generated slag 3 absorbs P ₂ O ₅ produced by the dephosphorization reaction, whereby the dephosphorization reaction is efficiently performed. The quicklime 16 may be mixed with a melting point depressant such as fluorite.

  The dephosphorization reaction is an oxidation reaction, and the temperature of the hot metal 2 rises due to heat generated by the oxidation reaction. The scrap 18 is stirred and melted with the hot metal 2 heated by the stirring gas blown from the bottom blowing tuyere 6. In addition, when the temperature of the hot metal 2 becomes too high by using only gaseous oxygen as a dephosphorizing agent, iron oxide 17 may be added as a dephosphorizing agent. The iron oxide 17 functions as a coolant because it raises its own temperature and is reduced by the carbon in the hot metal, and at that time it takes heat of the reduction reaction from the hot metal 2. However, when it is desired to increase the amount of dissolution of the scrap 18, it is preferable to add the total amount of gaseous oxygen without adding the iron oxide 17 that functions as a coolant. Alternatively, quick lime 16 and iron oxide 17 may be sprayed onto the bath surface of the hot metal 2 together with the carrier gas via the top blowing lance 7.

  When a predetermined amount of gaseous oxygen or gaseous oxygen and iron oxide 17 is supplied as the dephosphorizing agent, the supply of the dephosphorizing agent is stopped and the dephosphorizing refining of the first charge is completed.

  When the dephosphorization process of the first charge is completed, the converter body 4 is inverted to the side of the tap 5 and the hot metal 2 in the furnace is transferred from the tap 5 to a hot metal holding container (not shown) such as a hot metal ladle. Let it drain. The possibility that undissolved scrap 18 remains at the end of the first charge is extremely high, and the converter main body 4 is erected in a state where a part of the molten iron 2 remains, and the hot water discharge operation is completed. In the converter main body 4, unmelted scrap 18, part of the molten iron 2, and slag 3 remain. The amount of the hot metal 2 remaining in the furnace is sufficient to be about 3 to 10 tons although it depends on the capacity of the converter body 4.

  After the hot water is discharged, the second charge of molten iron 2 is charged into the converter main body 4 without carrying out the draining operation of the slag 3 and without charging the scrap 18 into the converter main body 4. Immediately after the hot metal 2 is charged, gaseous oxygen is sprayed and supplied from the upper blowing lance 7 toward the bath surface of the hot metal 2 and quick lime 16 is added to perform dephosphorization refining for the second charge. In order to prevent the bottom blowing tuyere 6 from being blocked, the stirring gas is continuously blown from the bottom blowing tuyere 6 after the first charge. When a predetermined amount of dephosphorizing agent has been supplied, the supply of the dephosphorizing agent is stopped and the second charge dephosphorizing refining is completed.

  When the dephosphorization process of the second charge is completed, the converter main body 4 is inverted to the hot water outlet 5 side, and the hot metal 2 in the furnace is discharged from the hot water outlet 5 to a hot metal holding container such as a hot metal ladle. Then, when the discharge of the hot metal 2 in the converter body is completed, the converter body 4 is then tilted in the direction opposite to the outlet 5 (referred to as the “counter outlet side”) to invert the furnace, The slag 3 is discharged from a furnace port of the converter main body 4 to a slag pot (not shown). After the slag 3 is discharged, the blowing of the stirring gas from the bottom blowing tuyere 6 may be interrupted.

  After the slag 3 is discharged, the dephosphorization process in which the first charge and the second charge become one set is repeatedly performed.

  In this case, if the amount of slag 3 is excessively large in the dephosphorization process of the second charge, or if it is necessary to dissolve a low phosphorus content with a particularly low phosphorus concentration in the second charge, the desorption of the first charge is performed. After the phosphorus treatment, the converter main body 4 is inverted to the side of the hot water outlet and a part of the slag 3 flows out from the furnace outlet of the converter main body 4, and then the furnace is turned down to the hot water outlet side of the hot metal 2 from the hot water outlet 5. You can take a bath.

  By adopting such an operation mode, the residence time of the scrap 18 in the furnace can be extended, and not only the heavy scrap can be melted but also the scrap 18 is evenly mixed with each charge and operated. Also, the amount of scrap that can be used can be increased. Further, since the number of times the scrap 18 is charged into the converter main body 4 is also reduced, the non-processing time is also shortened.

  Furthermore, by leaving a part of the hot metal 2 together with the unmelted scrap 18, the high-viscosity slag 3 left in the furnace does not come into direct contact with the furnace bottom refractory and solidifies, so that the slag 3 In addition, the problem that the undissolved scrap 18 adheres to the furnace bottom and the bottom blowing tuyere 6 is blocked is solved. Furthermore, since the tilt angle of the converter main body 4 in the hot water can be made shallower than 90 °, the possibility that the undissolved scrap 18 rolls in the furnace and closes the hot water outlet 5 can be reduced.

  Using a converter-type refining furnace similar to that shown in FIG. 1, scrap melting was performed during the dephosphorization process based on the operating conditions described in Table 1.

  A conventional operation example (referred to as “comparative example”) is as follows.

  First, in the first charge treatment, after 30 tons of scrap including 2 tons of heavy scrap was charged, 320 tons of hot metal was charged and dephosphorization was performed for about 11 minutes. After completion of the dephosphorization treatment, 321 tons of hot metal was discharged, but undissolved scrap remained in the refining furnace. After the hot water was discharged, undissolved scrap was also discharged out of the furnace. Subsequently, as in the first charge, 30 tons of scrap including 2 tons of heavy scrap was charged, and then 320 tons of hot metal was charged, and the dephosphorization process for the second charge was performed for about 11 minutes. After completion of the dephosphorization process, 319 tons of hot metal was discharged, but undissolved scrap remained even at the second charge. As with the first charge, drainage was performed after the hot water was discharged, and undissolved scrap was also discharged out of the furnace. The average amount of tapping through two charges was 320 tons, and tapping yield was 91.4%.

  On the other hand, in the dephosphorization processing method according to the present invention (referred to as “example of the present invention”), the operation was performed as follows.

  First, in the first charge treatment, 60 tons of scrap including 4 tons of heavy scrap was charged, and then 300 tons of hot metal was charged and dephosphorization treatment for the first charge was performed for about 11 minutes. The hot water was finished when 317 tons of hot metal was poured out. It was confirmed that unmelted scrap and hot metal remained in the smelting furnace. Thereafter, 340 tons of hot metal was charged without performing waste and dephosphorization treatment for the second charge was performed for about 11 minutes. In the hot metal after the dephosphorization treatment at the second charge, no undissolved scrap was found, and the amount of discharged hot water was 329 tons. The average amount of tapping through two charges was 323 tons, and the tapping yield was 92.3%.

  That is, the tapping yield in the inventive example was 0.9% higher than that in the comparative example, which corresponds to the amount of undissolved scrap discharged out of the furnace at the time of discharging in the comparative example. As described above, according to the present invention, even if the scrap is not melted at the first charge in which the scrap is charged, it is possible to eliminate the unmelted scrap for the entire operation, and to maintain a high hot water yield. It was. Furthermore, even if such operation was continued for one day, troubles such as closing of the bottom blowing tuyeres and hot water outlets did not occur.

  Table 1 also shows the amount of auxiliary raw material used, the amount of oxygen blown up, the component composition before and after the dephosphorization of the hot metal, and the hot metal temperature. As shown in Table 1, it was confirmed that the dephosphorization characteristics of the examples of the present invention were not different from those of the conventional examples, and the increase in the amount of auxiliary materials and oxygen was not accompanied.

It is a schematic sectional drawing which shows an example of the top bottom blowing type converter equipment used when implementing the dephosphorization processing method which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Converter equipment 2 Hot metal 3 Slag 4 Converter main body 5 Hot water outlet 6 Bottom blowing tuyere 7 Top blowing lance 8 Hood 9 Hopper 10 Hopper 11 Cutting device 12 Cutting device 13 Addition device 14 Chute 15 Scrap chute 16 Quicklime 17 Oxidation Iron 18 Slap

Claims (3)

Among the dephosphorization processes continuously performed in the refining furnace when the dephosphorization process of the hot metal is performed while melting the scrap using the converter type refining furnace having the top bottom blowing function, the following (1) The dephosphorization process with a scrap blending ratio defined by the formula of 10% or more is carried out as the first charge, and after this dephosphorization process, the undissolved scrap together with a part of the hot metal and slag in the refining furnace As the second charge, only the hot metal is charged into the smelting furnace, and the hot metal is dephosphorized. After the dephosphorization process, the smelting furnace is turned to the outlet side. furnace was then tapped molten iron, the said the smelting furnace exit sprue side and倒炉the opposite side to discharge the slag from the smelting furnace after its, after discharge of the slag, once again, the first charge-th and the 2 Repeated dephosphorization process similar to the charge Dephosphorization method hot metal in characterized, converter type refining furnace that.
Scrap mix ratio (%) =
Scrap charge x 100 / (molten metal charge + scrap charge) (1)   The hot metal dephosphorization method according to claim 1, wherein the scrap includes heavy scrap having a thickness or width of 40 mm or more and a unit weight of 100 kg or more.   After the dephosphorization treatment of the first charge, the converter-type smelting furnace is once inverted to the reaction outlet and part of the slag is discharged from the furnace outlet, and then immediately discharged to the outlet. 3. The method of dephosphorizing hot metal in a converter-type refining furnace according to claim 1, wherein hot metal is discharged from the pouring gate.

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