JP2016098389A - Manufacturing method of ferritic stainless steel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a manufacturing method of a ferritic stainless steel capable of surely inhibiting a nozzle blockage during manufacturing the ferritic stainless steel to which La and Zr are added.SOLUTION: There is provided a manufacturing method of a ferritic stainless steel containing, by mass%, C:0.2% or less, Si:0.2% or less, Mn:1.0% or less, Ni:2% or less, Cr:15 to 30%, Al:1% or less, Zr:0.001 to 1.0%, La:0.001 to 1.0% by using a refractory with SiO<45 mass% in a part to which a molten steel of the ferritic stainless steel contacts.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for producing ferritic stainless steel.

Ferritic stainless steel containing Zr and La is known as an alloy having excellent oxidation resistance. For example, a typical application is a member for a solid oxide fuel cell.
As an invention of a ferritic stainless steel suitable for a member for a solid oxide fuel cell containing Zr and La, for example, Japanese Patent Laid-Open No. 2007-16297 (Patent Document 1) proposed by the present inventor, JP 2005-320625 A (Patent Document 2), WO 2011/034002 Pamphlet (Patent Document 3), and the like include inventions of ferritic stainless steel having excellent oxidation resistance.

JP 2007-016297 A JP 2005-320625 A WO2011 / 034002 pamphlet

The ferritic stainless steel described above is manufactured by melting in an atmospheric furnace or a vacuum furnace, for example. Molten steel obtained in these melting furnaces becomes steel ingots or slabs by casting. A refractory is generally used for the molten steel path during casting. In the melting and manufacturing process of ferritic stainless steel, contact between the molten steel and the refractory is unavoidable. Since refractories are generally composed of oxides, preventing contamination of molten steel such as the inclusion and elution of refractories is an important factor in melting and manufacturing ferritic stainless steel.
In a ferritic stainless steel to which La and Zr are added, a refractory used for melting and casting is reduced to produce a LaZr-based oxide. In general, oxide formation is detrimental to the mechanical properties of the product. In addition, a large amount of LaZr-based oxide is deposited on the surface of the casting nozzle, causing nozzle clogging and hindering the production of the steel ingot.
The objective of this invention is providing the manufacturing method of the ferritic stainless steel which can prevent reliably nozzle obstruction | occlusion at the time of ferritic stainless steel manufacture to which La and Zr are added.

The present invention has been made in view of the above-described problems.
That is, the present invention is mass%, C: 0.2% or less, Si: 0.5% or less, Mn: 1.0% or less, Ni: 2% or less, Cr: 15-30%, Al: 1 % Or less, Zr: 0.001 to 1.0%, La: 0.001 to 1.0%, with the balance being Fe and impurities, in the manufacturing method of ferritic stainless steel, the molten steel of the ferritic stainless steel is in contact For the portion to be used, a ferritic stainless steel manufacturing method using a refractory material with SiO ₂ <45 mass% is used.
The refractory is a ladle, and / or is a method for producing ferritic stainless steel in which the refractory is a ladle nozzle.
The ferritic stainless steel is a method for producing a ferritic stainless steel further containing W: 0.1 to 3.0% and Cu: 0.1 to 4.0%.

  ADVANTAGE OF THE INVENTION According to this invention, the production | generation of the oxide by contact with a refractory can be suppressed significantly in the melting process of the ferritic stainless steel containing La and Zr. Therefore, for example, nozzle clogging in the casting process can be avoided.

It is a cross-sectional photograph of a nozzle.

The greatest feature of the present invention is to suppress the influence of SiO _{2 in} the refractory on ferritic stainless steel containing La and Zr.
The increase in molten steel oxygen due to contact with a refractory containing a large amount of SiO ₂ is particularly noticeable in steel containing La and Zr. The important point here is that the oxide in the molten steel is LaZr-based in steel containing La and Zr. LaZr-based oxide-SiO ₂ phase diagram is unknown due to lack of La · Zr thermodynamic data, but increase of oxygen and elution of Si in contact between steel containing La and Zr and SiO ₂ Therefore, contact between LaZr and the SiO ₂ refractory in the molten steel dramatically increases the oxide.
Therefore, it is necessary to use a refractory for melting and casting ferritic stainless steel containing La and Zr with a small amount of SiO ₂ . When the SiO ₂ content is 45% by mass or more, the increase in oxide due to contact between LaZr and the SiO ₂ refractory material becomes significant, and the nozzle is likely to be clogged. Therefore, a refractory material having a composition of SiO ₂ <45% by mass is used. I decided to. Incidentally, the content of SiO ₂ is reduced, the strength is increased in a number of refractory, thermal expansion coefficient is increased, easily cracking during use is generated. In view of this point, it is practically advantageous that a certain amount of SiO ₂ is contained, and it is preferable that 5% or more of SiO ₂ is contained. In addition, so that the corrosion resistance is lowered and SiO ₂ is increased. For example, in the Al ₂ O ₃ —SiO ₂ system, cristobalite which is not bonded and fixed to Al ₂ O ₃ and is free SiO ₂ is not included, that is, SiO ₂ <28% by mass is preferable.
The above-described components excluding SiO _{2 of} the refractory material are generally made of at least one of materials which are harder to be reduced than SiO ₂ , for example, oxides such as MgO, CaO, Al ₂ O ₃ and ZrO ₂ and C. Preferably. Components such as Mn ₂ O ₃ , Cr ₂ O ₃ , and Fe ₂ O ₃ that are more easily reduced than SiO ₂ should be avoided as much as possible, and should be suppressed to 3% by mass or less with less content than SiO ₂ .

Here, the refractory to be used is the main refractory (brick, powder, etc.) of the furnace body, the irregular refractory for constructing the furnace body, the unrolled steel slag, and the unshaped form for constructing the slag Refractory, ladle main refractory (brick, powder, etc.), unshaped refractory for ladle construction, tundish main refractory (brick, castable, etc.), tundish construction This refers to fixed refractories, nozzles, unshaped refractories for installing nozzles, runner refractories, unshaped refractories for installing runner refractories, and other refractories that can contact molten steel. The main refractory of the furnace body, the main refractory of the ladle, and the main refractory of the tundish, which have a particularly remarkable influence, reduce SiO ₂ as much as possible, and SiO ₂ <45% by mass in all the parts where the molten steel contacts. It is desirable to use refractories with the following components. This is because if SiO ₂ is contained even a little, it is reduced by La and Zr.
In addition, for the main refractory of the furnace body, the main refractory of the ladle, and the main refractory of the tundish, the time for the refractory to contact the molten steel is longer than that of the other, so the content of SiO ₂ is Less is desirable. In particular, since the furnace body holds the molten steel from melting of the raw material to outgoing steel, the contact area and time with the molten steel are the longest, and the temperature is also high. Therefore, since it is easily affected by molten steel, it is important that the main refractory of the furnace body has a particularly low SiO ₂ content. The ladle and tundish are routes of molten steel, but both have a large contact area with the molten steel and a large flow rate of the molten steel. Therefore, it is more susceptible to erosion / reduction by molten steel than other refractories excluding the furnace body.

Next, the chemical composition of ferritic stainless steel will be described. Each element specified in the present invention and its content are the effects when the ferritic stainless steel of the present invention is suitable for use in a solid oxide fuel cell. explain.
C has the effect of increasing the high temperature strength by forming carbides, but conversely deteriorates the workability and reduces the amount of Cr effective for oxidation resistance by combining with Cr. Therefore, it is limited to 0.2% or less. Desirably, it is 0.1% or less, more desirably 0.08% or less. Note that it is desirable to reduce C as much as possible. However, since C also has a deoxidizing effect, 0.005% remains not a little. Therefore, the practical lower limit of C is about 0.001%.
Si forms a film-like SiO ₂ near the interface between the Cr oxide film and the base material at the operating temperature of the solid oxide fuel cell. This means that Si in the base material is oxidized by a slight amount of oxygen that has entered the base material from the outside through a dense Cr oxide film, thereby degrading the oxidation resistance. The electrical resistivity of the SiO ₂ from higher than Cr, lowers the electrical conductivity of the oxide film. When Si is contained in excess of 0.5%, although it is thin and intermittent, film-like SiO ₂ is formed, which deteriorates oxidation resistance and electrical conductivity. Limited to the following ranges. In order to obtain the above-described effect of reducing Si more reliably, the upper limit of Si is set to 0.2% or less, more preferably 0.1% or less. Preferably it is 0.05% or less, and even if it does not add, it does not interfere.

Mn forms a spinel oxide together with Fe and Cr. The spinel type oxide layer containing Mn is formed outside the Cr ₂ O ₃ oxide layer. This spinel type oxide layer has a protective effect of preventing Cr, which deteriorates the ceramic electrolyte of the solid oxide fuel cell, from evaporating from the separator steel. In addition, since this spinel type oxide usually has a higher oxidation rate than Cr ₂ O ₃ , it works against the oxidation resistance itself, while maintaining the smoothness of the oxide film and reducing the contact resistance. Or has the effect of preventing evaporation of Cr harmful to the electrolyte.
On the other hand, if added excessively, as described above, the oxidation resistance of the Mn-containing spinel-type oxide itself is insufficient, resulting in poor oxidation resistance. Therefore, Mn is limited to 1% or less (excluding 0%). When the operating temperature is a low temperature of about 700 to 950 ° C., it may be 0.5% or less (not including 0%), and the preferable lower limit for the formation of the Mn-containing spinel oxide is 0.1% And

Cr is an important element for maintaining oxidation resistance and electrical conductivity by producing a Cr ₂ O ₃ coating in the present invention. Therefore, a minimum of 15% is required. However, excessive addition is not so effective in improving oxidation resistance, but also causes deterioration of workability, so it is limited to 15 to 30%. A desirable Cr range is 17 to 26%, and a more desirable Cr range is 18 to 25%.
La and Zr have the effect of greatly improving the oxidation resistance and the electrical conductivity of the oxide film by densifying the oxide film by adding a small amount or improving the adhesion of the oxide film. In the present invention, good oxidation resistance is exhibited mainly by forming a dense Cr oxide film, but in order to improve the adhesion of this Cr oxide film, the combined addition of La and Zr is indispensable. is there. Therefore, Zr: 0.001 to 1.0% and La: 0.001 to 1.0% are essentially added. However, excessive addition degrades hot workability, so the upper limit of both La and Zr is limited to 1.0%. The ranges of La: 0.01 to 0.2% and Zr: 0.1 to 0.5% are provided as the ranges that do not cause the problem of excessive addition while exhibiting the effects of La and Zr more reliably. It is preferable.

Ni is effective in improving toughness by adding a small amount. However, Ni is an austenite-forming element, and excessive addition becomes a ferrite-austenite two-phase structure, which increases the thermal expansion coefficient and deteriorates the oxidation resistance. Therefore, Ni is limited to 2% or less. Desirably, it is 1% or less, More desirably, it is 0.5% or less. In order to exhibit the above-described effect of Ni more reliably, the lower limit of Ni is preferably set to 0.1%.
Al is usually added as a deoxidizer. When a large amount of Al is added, an Al ₂ O ₃ film is formed. As described above, the Al ₂ O ₃ film is effective for oxidation resistance, but increases the electric resistance of the oxide film. Therefore, in the present invention, Al is limited to 1% or less in order to avoid the formation of the Al ₂ O ₃ film. The lower limit of Al may be no addition (0%).

In the present invention, in addition to the above elements, W and Cu can be added in combination.
By suppressing the outward diffusion of Cr, W can suppress a decrease in the amount of Cr inside the alloy after the Cr oxide film is formed. Further, W can prevent abnormal oxidation of the alloy and maintain excellent oxidation resistance. Therefore, W may be added particularly in the case of improving oxidation resistance. However, when W is added in excess of 3.0%, the hot workability deteriorates, so W is set to 3.0% as an upper limit. In order to make the effect of W more reliable, the lower limit of W is preferably 0.1%, and more preferably 0.5%.
Cu, by densifying a spinel type oxide containing Mn is formed on the _Cr 2 _{O 3} oxide layer, an effect of suppressing evaporation of Cr from _Cr 2 _{O 3} oxide layer. Therefore, when considering Cr evaporation as a problem, Cu may be added in a range of up to 4.0%. Even if Cu is added more than 4.0%, there is no further improvement effect, and there is a possibility that the hot workability is lowered or the ferrite structure becomes unstable, so the upper limit of Cu is 4.0%. To do. In order to make the effect of Cu more reliable, the lower limit of Cu is preferably 0.1%, and more preferably 0.5%.
The components other than those described above are Fe and impurities inevitably contained.

Steels having the components shown in Table 1 containing La and Zr were melted in a refractory furnace having a SiO ₂ content shown in Table 2 conditions (1), (2) and (3). Since many experiments were performed, the components in Table 1 are shown as representative values.
In condition (1), a ladle containing a high concentration of SiO ₂ and a runner containing a moderate amount of SiO ₂ are used. Condition (2) uses a ladle / runner containing low concentration of SiO ₂ , and condition (3) assumes that only the runner contains medium SiO ₂ in condition (2). Is.

Table 3 shows the oxygen values of the steel ingot obtained by melting. As shown in Table 3, the oxygen value of the steel ingot is greatly reduced by making SiO ₂ 45 mass% or less. In particular, it can be seen that by reducing the amount of SiO _{2 in} the ladle, the oxygen value of the steel ingot is significantly reduced.
From the comparison between the condition (2) and the condition (3), the change in SiO ₂ in the runner has a slightly higher oxygen value. From this, it can be seen that it is preferable that the entire portion of the ferritic stainless steel that is in contact with the molten steel is 28% by mass or less, which is a preferable range of SiO ₂ . In these meltings, the oxygen concentration of the molten steel in the melting furnace, not the steel ingot, was measured and found to be less than 4 ppm. From this, it is preferable that the amount of SiO ₂ be as small as possible I understand.

Next, the nozzle cut surface of the ladle in conditions (1) and (2) is shown in FIG.
In the present invention condition (2) in which the amount of SiO ₂ is reduced, the thickness of the adhered steel inside the nozzle is drastically reduced. When the steel adhered in the nozzle shown in the condition (1) in FIG. 1 was observed with a scanning electron microscope, it was confirmed that the adhered steel was a deposit of LaZr-based oxide.
The nozzle clogging due to the deposition of LaZr-based oxide occurred in about 90 seconds with a φ50 mm nozzle, but the amount of SiO _{2 in} the part where the molten steel comes into contact, including the ladle and the runner, should be reduced. As a result, nozzle clogging did not occur at all.
Moreover, in the conditions (2) and (3), it was confirmed that the decrease in La and the increase in Si when passing through the ladle were also suppressed.
As described above, it is understood that nozzle clogging in the casting process can be avoided by using a refractory material with SiO ₂ <45 mass% at the portion where the molten steel comes into contact. This is expected to improve the mechanical properties of the product.

Claims (4)

In mass%, C: 0.2% or less, Si: 0.5% or less, Mn: 1.0% or less, Ni: 2% or less, Cr: 15-30%, Al: 1% or less, Zr: 0 0.001 to 1.0%, La: 0.001 to 1.0%, the balance being ferritic stainless steel made of Fe and impurities,
A method for producing a ferritic stainless steel, characterized in that a refractory material with SiO ₂ <45% by mass is used in a portion where the molten ferritic stainless steel contacts.   The method for producing ferritic stainless steel according to claim 1, wherein the refractory is a ladle.   The method for producing a ferritic stainless steel according to claim 1, wherein the refractory is a ladle nozzle. The ferritic stainless steel according to any one of claims 1 to 3, wherein the ferritic stainless steel further contains W: 0.1 to 3.0% and Cu: 0.1 to 4.0%. Steel manufacturing method.