JP6459643B2 - Method for removing non-metallic inclusions and adsorbent - Google Patents

Description

  The present invention relates to a method for removing non-metallic inclusions and an adsorbent, and more particularly to a method for removing non-metallic inclusions contained in molten steel in a tundish used for continuous casting, and an adsorbent used for the removing method.

  When iron is produced by the blast furnace method, hot metal is produced by reacting coke and iron ore in a blast furnace. Next, decarburization blowing is performed by blowing oxygen into the hot metal in the converter. Of the oxygen blown into the hot metal, except for oxygen that has reacted with carbon to become carbon monoxide, it remains in the molten steel after decarburization blowing. In order to reduce the remaining oxygen, an oxidizing agent such as aluminum is introduced into the molten steel that is discharged from the converter to the ladle. The oxidizing agent becomes an oxide such as aluminum oxide by reaction with oxygen.

  Of the oxides produced in this way, those that floated in the ladle due to the difference in specific gravity with the molten steel are removed, but those that did not float are brought into the tundish together with the molten steel injected from the ladle. It becomes a non-metallic inclusion. Non-metallic inclusions contained in the molten steel in the tundish cause the operation to become unstable due to the clogging of the immersion nozzle. In addition, if the non-metallic inclusions adhering to the immersion nozzle peel and enter the mold, they may be taken into the solidified slab and cause flaws.

  Therefore, in order to stabilize the operation in continuous casting and improve the quality of the slab, it is necessary to reduce nonmetallic inclusions contained in the molten steel in the tundish. For example, Patent Document 1 discloses a technique for adsorbing and removing non-metallic inclusions by floating a spherical alumina-based refractory as an adsorbent in molten steel in a tundish. This technique is characterized in that the alumina-based refractory is not used as a filter, but suspended in molten steel to eliminate clogging, and the alumina-based refractory is made spherical to maximize the surface area.

JP-A-9-206895

  However, since the specific gravity of alumina-based refractory (about 2.5) is much smaller than the specific gravity of molten steel (about 7.0), for example, as shown in FIG. Will float near the molten steel surface in the tundish. On the other hand, the molten steel supplied from the ladle is injected into the tundish from the nozzle soaked deeper than the molten metal surface, and then injected into the mold from the nozzle provided at the bottom of the tundish. . That is, most of the molten steel passes through the tundish without contacting the adsorbent floating near the molten metal surface. Therefore, the technique as described in Patent Document 1 does not always reduce the nonmetallic inclusions sufficiently.

  Therefore, the present invention has been made in view of the above problems, and an object of the present invention is a novel capable of effectively removing non-metallic inclusions for the entire molten steel in the tundish. Another object of the present invention is to provide an improved method for removing non-metallic inclusions and an adsorbent.

In order to solve the above-mentioned problem, according to one aspect of the present invention, there is provided a method for removing non-metallic inclusions contained in molten steel in a tundish used for continuous casting, wherein the molten steel in the tundish is refractory. have a layer has encapsulating metal core structure, suspended a plurality of adsorbers having different specific gravity by changing at least one of the size of the thickness or metal nuclei refractory layer, the adsorption body is non Provided is a method for removing non-metallic inclusions by adsorbing and removing metallic inclusions.

  In the method for removing non-metallic inclusions described above, the adsorbent that floats in the molten steel bath in the tundish has a structure in which the refractory layer includes metal nuclei. As a result, the specific gravity of the adsorbent approaches the specific gravity of the molten steel, and the adsorbent is distributed to a deeper position in the molten steel bath. Therefore, nonmetallic inclusions can be effectively removed from the entire molten steel in the tundish.

In the above method for removing non-metallic inclusions, the refractory layer may include an alumina-silica-carbon refractory. The metal core may contain an iron-based metal. The specific gravity of the adsorbent can be in the range of 4 to 6.5 .

Moreover, in order to solve the said subject, according to another viewpoint of this invention, several adsorption body for adsorbing and removing the nonmetallic inclusion contained in molten steel within the tundish used for continuous casting of molten steel is provided. a adsorber composition having, adsorbents, changing the metal nuclei, and the refractory layer containing the metal nuclei, only including, at least one of the size of the thickness or metal nuclei refractory layer Provides an adsorbent composition in which the specific gravity of the plurality of adsorbents is different .

  As described above, according to the present invention, nonmetallic inclusions can be effectively removed from the entire molten steel in the tundish.

It is a figure which shows the structure of the apparatus with which the removal method of a nonmetallic inclusion is implemented in one Embodiment of this invention. It is sectional drawing of the adsorbent used in one Embodiment of this invention. It is a photograph which shows the internal state after casting an aluminum killed steel using the immersion nozzle formed with the alumina-silica-carbon type refractory.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In the present specification and drawings, components having substantially the same functional configuration are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is a diagram showing a configuration of an apparatus in which a method for removing non-metallic inclusions is performed in an embodiment of the present invention. Referring to FIG. 1, in this embodiment, non-metallic inclusions contained in molten steel 2 in tundish 1 are removed. The molten steel 2 is injected into the tundish 1 from the ladle 3 via the long nozzle 4. Here, the long nozzle 4 is immersed in the tundish 1 to a position deeper than the molten metal surface of the molten steel 2. The molten steel 2 temporarily stored in the tundish 1 is injected into the mold 6 through the immersion nozzle 5 provided at the bottom of the tundish 1.

  In the illustrated example, the long nozzle 4 and the immersion nozzle 5 are provided with slide nozzle plates 7 and 8 for adjusting the flow rate of the molten steel 2 in each nozzle. In the illustrated example, the molten steel 2 is supplied from the tundish 1 to the two molds 6. These configurations are common in molten steel continuous casting equipment and will not be described in detail. Further, these configurations can be modified as appropriate within the scope apparent to those skilled in the art. Furthermore, the figure shows the tundish slag 9 present on the molten steel surface in the tundish 1 and the mold powder 10 present on the molten metal surface in the mold 6.

  As a configuration unique to this embodiment, in the tundish 1, the spherical adsorbent 11 is suspended in the bath of molten steel 2. As will be described later, the adsorbent 11 is composed of a metal core and a refractory containing the metal core. Nonmetallic inclusions have the property of adhering to the surface of a refractory or agglomerating nonmetallic inclusions with each other. Therefore, by floating the adsorbent 11 having a surface formed of a refractory, the molten steel 2 can be suspended. Non-metallic inclusions contained can be removed by adsorption. Furthermore, since the adsorbent 11 contains metal nuclei, the specific gravity is larger than that of a conventional adsorbent formed entirely of refractory. Therefore, the difference in specific gravity between the adsorbent 11 and the molten steel is smaller than before, and the adsorbent 11 is distributed not only near the molten metal surface but also at a deeper position in the bath of the molten steel 2.

  FIG. 2 is a cross-sectional view of the adsorbent 11 used in the present embodiment. Referring to FIG. 2, the adsorbent 11 includes a surface refractory layer 11a and an internal metal core 11b. The refractory layer 11a can be formed of, for example, an alumina-silica-carbon refractory. Alternatively, the refractory layer 11a may be formed of another refractory having an action of adsorbing non-metallic inclusions. Below, as an example, the reaction on the surface of the adsorbent 11 in the bath of the molten steel 2 when the refractory layer 11a is formed of an alumina-silica-carbon refractory will be described.

  In the bath of molten steel 2, on the surface of the adsorbent 11, silica contained in the refractory layer 11a is reduced by carbon to generate CO gas and SiO gas (Formula 1). On the other hand, the molten steel 2 contains a part of aluminum, which is supplied as an oxidizer after steel is discharged from the converter into the ladle, as metallic aluminum. This metal aluminum reduces CO gas and SiO gas, respectively, to produce aluminum oxide (formulas 2 and 3).

C (s) + SiO ₂ (s) → CO (g) + SiO (g) (Formula 1)
3CO (g) + 2Al → Al ₂ O ₃ (s) + 3C (Formula 2)
3SiO (g) + 2Al → Al ₂ O ₃ (s) + 3Si (Formula 3)

  As a result of such a reaction, aluminum oxide is generated on the surface of the adsorbent 11 and a concentration gradient of reduced C and Si is generated in the bath of molten steel 2 near the surface of the adsorbent 11. Aluminum oxide which is a non-metallic inclusion contained in the molten steel 2 is attracted to the surface of the adsorbent 11 by the action of interfacial tension (so-called Marangoni convection) due to the concentration gradient. Furthermore, the aluminum oxide attracted to the vicinity of the surface of the adsorbent 11 aggregates with the aluminum oxide already present on the surface of the adsorbent 11. Through such a process, the adsorbent 11 adsorbs and removes nonmetallic inclusions contained in the molten steel 2.

  The alumina-silica-carbon refractory is also used as a material for the immersion nozzle 5, for example. In FIG. 3, the internal state after casting an aluminum killed steel using the immersion nozzle 5 formed with the alumina-silica-carbon type refractory is shown with a photograph. In the operation at this time, the adsorbent 11 is not used. In this case, as shown in the photograph, it can be seen that an adhering non-metallic inclusion layer is formed on the inner surface of the immersion nozzle 5 formed of an alumina-silica-carbon refractory. Also from this, the alumina-silica-carbon refractory can effectively adsorb non-metallic inclusions contained in the molten steel 2, and is suitable as a material for the refractory layer 11a of the adsorbent 11 in the present embodiment. I understand that.

  On the other hand, the metal core 11b included in the refractory layer 11a by the adsorbent 11 is formed of an iron-based metal such as cast iron, pig iron, and steel. Here, the action of the metal core 11b is to increase the specific gravity of the entire adsorbent 11b so as to approach the specific gravity of the molten steel 2. Therefore, the metal core 11b is not limited to the iron-based metal, and may be formed of various materials. However, since light metals such as aluminum cannot be expected to increase the specific gravity, and heavy metals other than iron-based metals are expensive, it is practical to form the metal core 11b with iron-based metals. .

  The adsorbent 11 having a structure in which the refractory layer 11a includes the metal core 11b is manufactured, for example, by applying a refractory to the metal core 11b and firing it. In this case, the fired refractory constitutes the refractory layer 11a. Alternatively, the adsorbent 11 may be manufactured by housing the metal core 11b in a refractory container and sealing it. In this case, the sealed refractory container constitutes the refractory layer 11a. In addition, the shape of the adsorbent 11 composed of the refractory layer 11a and the metal core 11b is preferably a sphere having a maximum surface area. The shape may be adopted.

  Here, it is sufficient if the thickness of the refractory layer 11a is approximately 10 mm or more. Then, the specific gravity of the adsorbent 11 is adjusted by changing the thickness of the refractory layer 11a and the diameter of the metal core 11b. The specific gravity of the adsorbent 11 is preferably in the range of 4 to 6.5. When the specific gravity is less than 4, the specific gravity difference from the molten steel 2 is too large, and many adsorbents 11 float only near the molten steel surface as in the conventional adsorbent. On the other hand, when the specific gravity exceeds 6.5, the specific gravity difference with the molten steel 2 is too small, and the adsorbent 11 tends to sink to the bottom of the tundish 1. By setting the specific gravity of the adsorbent 11 in the middle of these ranges, the adsorbent 11 is distributed over a wide range in the bath of molten steel 2, and non-metallic inclusions are effectively removed by contacting more molten steel 2. Can be removed.

  Further, the size of the adsorbent 11 (diameter in the case of a spherical shape) is set so that the adsorbent 11 stays stably in the tundish 1 without disturbing the flow of the molten steel 2 in the tundish 1. . For example, the diameter of the adsorbent 11 is set so as not to exceed the shorter half of the width or depth of the tundish 1. This is because if the diameter is larger than this, the flow of the molten steel 2 injected into the mold 6 through the immersion nozzle 5 provided at the bottom of the tundish 1 may be hindered. Further, the diameter of the adsorbent 11 is set so as to exceed the inner diameter of the immersion nozzle 5. This is because if the diameter is smaller than this, the immersion nozzle 5 may be sucked.

  During the continuous casting operation, the adsorbent 11 is preheated together with the tundish 1. After completion of preheating, molten steel 2 is poured into the tundish 1 from the ladle 3, and thereafter the adsorbent 11 adsorbs and removes nonmetallic inclusions while floating in the bath of molten steel 2. After completion of casting, the adsorbent 11 is recovered from the tundish 1. The collected adsorbent 11 is reused if the amount of non-metallic inclusions adhering to the surface is small, and is exchanged if the amount of adhering material 11 is large.

  There is no restriction | limiting in particular in the number of the adsorption bodies 11 arrange | positioned in the tundish 1. FIG. A single adsorbent 11 may be disposed within a range in which nonmetallic inclusions contained in the molten steel 2 can be sufficiently adsorbed and removed and the flow of the molten steel 2 in the tundish 1 is not hindered. The adsorbent 11 may be disposed. When a plurality of adsorbents 11 are arranged, the specific gravity and size of each adsorbent 11 may be different. More specifically, a plurality of adsorbents 11 having different specific gravity within the range of 4 to 6.5 described above may be disposed in the tundish 1. Thereby, since each adsorbent 11 floats in the bath of the molten steel 2 at different depths, the nonmetallic inclusions contained in the molten steel 2 can be more effectively adsorbed and removed.

  Next, examples of the present invention will be described. In this example, continuous casting was performed using a tundish 1 having a length of 7 m, a depth of 1 m, a width of the molten metal surface of 1.2 m, a width of the bottom of 0.6 m, and a 2-strand tundish. The amount of molten steel injected from the ladle 3 was 5 t / min per strand. Twenty adsorbents 11 were prepared and all had a diameter of 0.1 m. The refractory layer 11 a of the adsorbent 11 is formed of the same alumina-silica-carbon refractory as the immersion nozzle 5. Further, the metal core 11b was formed of a steel material of JIS SS400. Here, the adsorbent 11 in the present embodiment includes five types of adsorbents having different specific gravity by adjusting the thickness of the refractory layer 11a and the size of the metal core 11b. More specifically, four adsorbents each having a specific gravity of 4.5, 5, 5.5, 6, and 6.5 are included.

  In this example, after preheating the tundish 1 with the adsorbent 11 disposed inside, the molten steel 2 was poured into the tundish 1 from the ladle 3 and continuous casting was performed for 40 minutes. When 20 minutes have elapsed since the start of casting, a molten steel sample is taken at a position 0.1 m from the top of each of the two strands of the immersion nozzle 5 and the bottom of the tundish 1, and nonmetallic inclusions are extracted by electrolytic extraction. did. The extracted non-metallic inclusions were evaluated by the number of particles for each size (less than 50 μm and 50 μm or more). As a result of powder X-ray diffraction, it was confirmed that the extracted nonmetallic inclusion was aluminum oxide (α-alumina).

  On the other hand, as a comparative example, continuous casting was performed without using the adsorbent 11 under the same conditions as in the above example. Also in the comparative example, similarly to the example, a molten steel sample was taken when 20 minutes had elapsed after the start of casting, and the nonmetallic inclusions extracted by the electrolytic extraction method were evaluated by the number of particles for each size. Table 1 shows the results of comparison of the number of nonmetallic inclusion particles in Examples and Comparative Examples. In Table 1, the number of non-metallic inclusion particles is indicated by an index with a comparative example of 1. In addition, the number of non-metallic inclusion particles in each example is the average value of the samples collected in each of the two strands.

  From the above results, it is shown that the method for removing non-metallic inclusions according to the embodiment of the present invention is effective regardless of the size of non-metallic inclusions, and can significantly reduce non-metallic inclusions contained in molten steel. It was done.

  The preferred embodiments of the present invention have been described in detail above with reference to the accompanying drawings, but the present invention is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field to which the present invention pertains can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that these also belong to the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Tundish 2 Molten steel 3 Ladle 4 Long nozzle 5 Immersion nozzle 6 Mold 7, 8 Slide nozzle plate 9 Tundish slag 10 Mold powder 11 Adsorbent 11a Refractory layer 11b Metal core

Claims (5)

A method for removing non-metallic inclusions contained in molten steel in a tundish used for continuous casting,
Plurality in molten steel in the tundish, refractory layer have a structure containing therein a metal core, with different specific gravity by changing at least one of the size of the thickness or the metal nuclei of the refractory layer The adsorbent is suspended, and the adsorbent adsorbs and removes the nonmetallic inclusions.   The non-metallic inclusion removal method according to claim 1, wherein the refractory layer includes an alumina-silica-carbon refractory.   The method for removing non-metallic inclusions according to claim 1, wherein the metal nucleus includes an iron-based metal.   The specific gravity of the said adsorbent is a removal method of the nonmetallic inclusions in any one of Claims 1-3 which exists in the range of 4-6.5. An adsorbent composition having a plurality of adsorbents for adsorbing and removing non-metallic inclusions contained in molten steel in a tundish used for continuous casting of molten steel,
The adsorbent is
A metal core,
A refractory layer containing the metal core ;
Only including,
An adsorbent composition in which the specific gravity of the adsorbents is made different by changing at least one of the thickness of the refractory layer and the size of the metal core .