JP3404237B2 - How to prevent oxidation of molten steel - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for cleaning molten steel in a tundish by preventing rapid air oxidation of molten steel when pouring molten steel into a tundish from a ladle in continuous casting of steel. It is a thing.

[0002]

2. Description of the Related Art In continuous casting of steel, the tundish is located between the ladle and the mold, and is one of the most important parts in terms of operation and quality. Its functions are to control the amount of molten steel supplied into the mold, store molten steel, and separate and remove inclusions. In particular, the function of removing inclusions has become an extremely important function as the quality of steel materials has become stricter in recent years. However, when pouring molten steel into the tundish from the ladle, the problem of contamination of the molten steel due to air oxidation arises, and therefore, the effect of removing inclusions in the tundish is not sufficiently exerted. Therefore, for the purpose of preventing molten steel contamination in the tundish, for example, as described in JP-A-61-17345, an inert gas is blown into the tundish covered with a heat insulating material board at the initial injection stage. As a result, the air oxidation of the injected molten steel is prevented.

[0003]

However, in order to inject the molten steel into the tundish, a space for inserting the molten steel injecting nozzle is required in the tundish lid,
It is not possible to completely seal the tundish.
Also, when blowing an inert gas into the tundish,
Although the inert gas is blown from the space around the molten steel injection nozzle, this method also causes a problem that air is entrained at the injection point and the oxidation of the molten steel becomes severe. Therefore, the conventional sealing method cannot reduce the oxygen concentration in the tundish to the extent that air oxidation can be prevented.

In view of these problems, in order to prevent air oxidation of molten steel in the tundish, which is the main cause of deteriorating the cleanliness of molten steel, the present invention rapidly and oxygen concentration in the tundish. It is intended to present a method that can be efficiently reduced.

[0005]

SUMMARY OF THE INVENTION The gist of the present invention is, in advance,
Injecting an inert gas into the tundish to reduce the oxygen concentration contained in the atmosphere gas inside the tundish, and then injecting the molten steel in the ladle into the tundish through a nozzle. Oxidation prevention of molten steel Regarding the method, an inert gas is blown into the tundish, and the lump is composed of a metal portion containing 90% by weight or more of Ti and voids, and has a porosity of 10% or more and a specific gravity of 4 or more. A method for preventing oxidation of molten steel (a method for removing oxygen gas existing in the space in the tundish) by adding a Ti-containing lump made into less than 0.5 into the tundish, and particularly T
There is a method for preventing the oxidation of molten steel by using sponge Ti as the i-containing lump.

The term "Ti is 90% by weight
A "Ti-containing lump having a porosity of 10% or more and a specific gravity of less than 4.5" which is a lump composed of a metal portion and voids contained above includes, for example, a entangled pure Ti wire. It is made into a scrubbing shape or a spring shape, but most simply, it has a porosity of 15 to 50%, a Ti content concentration of 99.8% by weight or more, and a particle size of 20.
Most preferred is a so-called "titanium sponge" in the form of lumps of about 50 mm.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION Generally, when pouring molten steel from a ladle into a tundish, the stirring energy of the pouring flow is very large until the molten steel pouring nozzle attached to the ladle is immersed below the surface of the molten metal. Therefore, the surface area of molten steel increases at the initial stage of injection, and many inclusions are generated due to the air oxidation shown by the reaction of the equation (1).

4Al (in molten steel) + 3O ₂ (in air) = 2Al ₂ O ₃ (inclusions) (1) As described above, the air oxidation rate at the initial stage of injection is much higher than that in the steady state, and It is the largest cause of molten steel contamination in the dish.

In order to prevent the air oxidation at the initial stage of injection, the present inventors have studied a method of replacing the inside of the tundish with Ar gas and then starting the injection of molten steel. It was found that the method of blowing Ar gas into the interior cannot reduce the oxygen concentration to the extent that the oxidation of molten steel can be prevented.

FIG. 2 is a diagram for explaining a conventional tundish sealing method.

Before the molten steel is injected, the molten steel in the ladle 5 provided on the tundish lid 4 is injected through the molten steel injection nozzle 6 in order to replace the air 2 in the tundish 1 with the Ar gas 3. Nozzle 8 for blowing gas into injection hole 7
Is installed and Ar gas 3 is blown into the tundish 1 from here. However, it is difficult to close the injection hole 7 in operation. Therefore, when Ar gas 3 is blown into the tundish 1 from the gas blowing nozzle 8, the jet of Ar gas 3 entrains the surrounding air 2 and the tundish 1 The oxygen concentration in the inside cannot be reduced sufficiently. As a result of detailed measurement of the amount of air 2 entrained by the Ar gas 3 blown from the gas blowing nozzle 8, the present inventors found that the entrained air flow rate is proportional to the blown Ar gas flow rate and is several times the blown Ar gas flow rate. It has become clear that it has also reached. Furthermore, although the amount of air entrained can be reduced by reducing the flow rate of the blown Ar gas, the amount of Ar
Since the absolute amount of gas becomes small, it takes a long time to reduce the oxygen concentration in the tundish, which proves to be impractical.

Therefore, in order to reduce the oxygen concentration in the tundish efficiently in a short time, the present inventors add a metal into the tundish and combine it with oxygen to reduce the oxygen concentration. A detailed study was conducted on the method. As a result, the inert gas is blown into the tundish at such a flow rate that air entrainment does not matter,
It is effective to add spongy Ti into the tundish, which has a large specific surface area per unit weight and high bondability with oxygen at high temperature (= equilibrium elemental oxygen partial pressure of aluminum element is low). I found it. In addition, sponge-like Ti is the most preferable because it is the most easily available and has little fluctuation in quality.
Porosity 15 to 50% and Ti content concentration is 9% by weight
It is a so-called "sponge titanium" in the form of lumps having a particle size of about 20 to 50 mm, which is 9.8% or more. Other than this, Ti can be expected to have the same effect as 90% by weight.
% Of a metal portion and voids, the porosity of which is 10% or more and the specific gravity of which is 4.5.
A Ti-containing lump that has been made smaller than the above, for example, one that is entangled with a pure Ti wire to form a scourer or one that is processed into a spring shape may be used.

The tundish is preheated before injection of molten steel,
It has a temperature of about 1300 ° C. Therefore, when Ti, which has a high bondability with oxygen at high temperature, is added to the tundish, it reacts with oxygen in the air according to the equation (2), and the oxygen concentration in the tundish rapidly decreases.

Ti + O ₂ (in air) = TiO ₂ (2) Here, when spongy Ti is used as Ti, since many pores are present, the specific surface area per unit weight becomes large and the addition amount is small. Even in the amount, the reaction of the formula (2) can be efficiently advanced. However, since the reaction of the equation (2) proceeds in a single time, volume contraction corresponding to the amount of oxygen in the tundish occurs, and an air flow from the outside into the tundish occurs. In order to prevent the inflow of air, it is necessary to supplement the volume of oxygen, which is decreased by the addition of sponge Ti, by injecting Ar gas. In this case, the flow rate of Ar gas may be small and air entrainment may occur. Problem does not occur. Therefore, by adding spongy Ti and blowing Ar gas at a low flow rate together, it is possible to efficiently reduce the oxygen concentration in the tundish while preventing the entrainment of air.

When the present invention is carried out, Ar gas is blown into the tundish before the spongy Ti is added, and the sponge Ti is added to the molten steel injection position in the tundish with the oxygen concentration reduced as much as possible. Is more efficient. The amount of spongy Ti to be added depends on the amount of oxygen in the tundish (2) considering the reaction efficiency of Ti.
It can be calculated using the stoichiometric relationship of the formula. Further, it is preferable to start the injection of the molten steel after the oxygen concentration in the tundish reaches 1% or less. This has an oxygen concentration of 1
%, It is possible to prevent molten steel contamination to such an extent that it does not become an industrial problem. If the oxygen concentration in the tundish does not fall below 1%, sponge Ti can be further added. . Of course, an inert gas other than Ar gas may be used to reduce the oxygen concentration.

[0016]

EXAMPLES The present invention will be described below with reference to Examples and Comparative Examples.

(Embodiment 1) As shown in FIG.
A tundish 1 of t (depth 1.2 x width 1.5 x length 6.0 m) is covered with a refractory lid 4, and a molten steel pouring nozzle 6 having an inner diameter of 200 mm is inserted from the bottom of the tundish 1 to 200 m.
It was installed at a position of mm. Further, a gas blowing nozzle 8 having an inner diameter of 20 mm was inserted from the injection hole 7 of the tundish lid and fixed at a position 1.2 m above the bottom of the tundish 1. Ar gas was blown at a flow rate of 20 Nm ³ / h and sponge Ti was 2.0 k in the tundish.
g was added. One minute after the spongy Ti was added, the oxygen concentration in the tundish became stable at 1% or less, and 1 minute and 30 seconds after the start of blowing, the Ar gas blowing flow rate was reduced to 1 Nm ³ / h, and the component C: 50 ppm. , S
i: 0.015%, Mn: 0.25%, P: 0.02
%, S: 0.01%, Al: 0.035%, temperature 155
Take 250 t of molten steel at 0 ° C (in the tundish) from the ladle
Injection was performed at 5 t / min. At this time, the total amount of oxygen in the molten steel on the outlet side of the tundish showed a constant value from the initial stage of injection, and a total amount of oxygen of 15 ppm could be stably secured. As a result, molten steel contamination was reliably prevented, and no surface defects occurred in the rolled product.

(Comparative Example 1) As shown in FIG.
t tundish (depth 1.2 x width 1.5 x length 6.
(0 m) with a refractory lid 4 and a molten steel injection nozzle 6 with an inner diameter of 200 mm 200 mm from the bottom of the tundish 1.
It was installed in the position. Furthermore, a gas blowing nozzle 8 having an inner diameter of 20 mm was inserted from the injection hole 7 of the tundish lid, fixed at a position 1.2 m above the bottom of the tundish 1, and Ar gas was blown at a flow rate of 250 Nm ³ / h. . The oxygen concentration in the tundish gradually decreased to 5% after 3 minutes. However, even if gas blowing was continued for 5 minutes, the oxygen concentration in the tundish was 5
%, The content of C was 50 ppm, Si was 0.015%, and Mn was 0.25.
%, P: 0.02%, S: 0.01%, Al: 0.03
Molten steel 25, 5%, temperature 1550 ° C (in tundish)
0 t was poured from the ladle at 25 t / min. At this time, the total oxygen content in the molten steel on the tundish outlet side was 80 p
It reached pm and then gradually decreased, but the final reached value was 5
It was 0 ppm. For this reason, it was not possible to prevent the contamination of molten steel at the initial stage of injection, and surface defects occurred in the product after rolling.

[0019]

As described above, according to the method for cleaning molten steel in the tundish of the present invention, the oxygen concentration in the tundish can be reduced quickly and efficiently, so that it is the most vigorous without disturbing the operation. Since the contamination of molten steel in the early stage of casting can be reliably prevented, the quality of the slab is significantly improved.

[Brief description of drawings]

FIG. 1 is a diagram for explaining the present application.

FIG. 2 is a diagram for explaining a conventional tundish sealing method.

[Explanation of symbols]

1 tundish 2 air 3 Ar gas 4 tundish lid 5 ladle 6 Molten steel injection nozzle 7 injection holes 8 Gas injection nozzle 9 Sponge titanium block

─────────────────────────────────────────────────── --- Continuation of the front page (56) References JP-A-5-177316 (JP, A) JP-A-4-238656 (JP, A) JP-A-3-221247 (JP, A) JP-A-63- 188460 (JP, A) JP-A-9-300051 (JP, A) JP-A-9-150244 (JP, A) Actual development 2-104152 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) B22D 11/11 B22D 11/106 B22D 11/108 C21C 7/04

Claims (2)

(57) [Claims] 1. An inert gas is blown into the tundish in advance to reduce the oxygen concentration contained in the atmospheric gas in the space inside the tundish, and then the molten steel in the ladle is passed through the nozzle into the tundish. Regarding the method for preventing the oxidation of molten steel in which injection is started, a lump consisting of a metal portion containing 90% by weight or more of Ti and voids, which is obtained by blowing an inert gas into the tundish, and having pores A method for preventing oxidation of molten steel, characterized in that a Ti-containing lump having a ratio of 10% or more and a specific gravity of less than 4.5 is added into a tundish. 2. The method for preventing oxidation of molten steel according to claim 1, wherein spongy Ti is used as the Ti-containing lump.