JP2021049564A - Tundish upper nozzle structure and method of continuous casting - Google Patents

Abstract

To provide a tundish upper nozzle structure that allows inclusions to float up within a tundish, and a method of continuous casting.SOLUTION: A tundish upper nozzle structure includes a flange-like part 12 that is provided greater than the outer shape of a top end of a tundish upper nozzle 11 in a part or entire of an outer periphery of the top end of the tundish upper nozzle and one or a plurality of gas exit ports 13a, 13b that are provided in any one or a plurality of surfaces out of lower, outer peripheral and upper surfaces of the flange-like part 12 and of an outer peripheral surface of the tundish upper nozzle 11 below the flange-like part 12. By adjusting the length L in the tundish upper nozzle structure, nearly all of gas is floated up, or the flow rate toward the lower side of an inner hole 11a and the float-up amount of the gas is adjusted.SELECTED DRAWING: Figure 1

Description

The present invention relates to a tundish nozzle structure having a gas blowing function and a continuous casting method.

In continuous steel casting, many operations are performed in which gas is blown from a nozzle on a tundish. The purpose of blowing the gas is mainly as follows.
(1) By flowing air bubbles downward from the inner hole of the upper nozzle of the tundish, inclusions may adhere to the inner hole surface of the upper nozzle of the tundish or the nozzle below it, or the inner hole may be blocked due to the adhesion of inclusions. Suppress.
(2) The flow form of the molten steel in the mold is controlled from below the upper nozzle of the tundish.
(3) The inclusions are levitated below the nozzle on the tundish or in the mold.
(4) Raise inclusions in the tundish.
These affect the stability and productivity of casting operations and the quality of slabs.

Regarding the above (1) to (4), gas is conventionally discharged from the tundish upper nozzle in various forms.
Mainly regarding (1) to (3) above
For example, in Patent Document 1, a porous portion for gas discharge is provided in the inner hole of the upper nozzle of the tundish, and a ring-shaped flange portion of a ring-shaped refractory installed on the outer periphery of the upper end of the upper nozzle of the tundish is the tundish. A structure that covers the upper part of the upper nozzle has been proposed. As a result, it is said that gas can be reliably supplied to the inner hole of the upper nozzle of the tundish.

Further, Patent Document 2 aims to prevent inclusions and bare metal from adhering to the vicinity of the contact portion between the stopper and the upper nozzle, to enable stable flow rate control, and to obtain a good slab. A stopper receiving nozzle at the bottom of the tundish is characterized in that a porous refractory is provided on each of the upper and lower molten steel contact surfaces with the contact portion with the stopper as a boundary, and argon gas can be blown out independently of each porous refractory. Has been proposed.

Furthermore, paying attention to the above (4),
In Patent Document 3, an inert gas is blown from a ring-shaped upper porous refractory provided at the top of a nozzle provided at the bottom of the tundish, and a ring-shaped lower porous refractory provided at the bottom of the nozzle. A continuous casting method in which an inert gas is blown from an object has been proposed. As a result, the upper porous refractory can blow the inert gas toward the molten steel of the tundish, and the lower porous refractory can blow the inert gas toward the nozzle opening.

Japanese Unexamined Patent Publication No. 2003-220450 Japanese Unexamined Patent Publication No. 6-297118 Japanese Unexamined Patent Publication No. 2016-182612

In order to improve the quality of the slab, it is also important to levitate inclusions in the tundish of (4) above. The balance between (1) to (3) and (4) is of a property that is appropriately determined according to individual operating conditions (including know-how), steel type, target quality, and the like.
However, in the gas blowing method based on the prior art such as the patent document, most of the blown gas flows to the inner hole side of the nozzle on the tundish, and the gas may float upward, that is, in the molten steel in the tundish. I found that I couldn't.

In addition, in order to float the inclusions in the above (4), that is, in the tundish, there is also a method of blowing gas into the tundish at any position on the bottom of the tundish other than the nozzle on the tundish.
However, in order to blow gas into the tundish at any position on the bottom of the tundish other than the upper nozzle of the tundish, dedicated equipment for that purpose is required, which increases the initial cost and running cost, and also operates. The risk of steel leakage during time also increases.
Furthermore, it has been pointed out that this method does not have a sufficient effect of removing inclusions in molten steel.
From this point of view, in order to remove inclusions by gas in the tundish, it is possible to use a nozzle on the tundish to form a floating upstream of the gas to the molten steel in the tundish and adjust the ratio. preferable.

The problem to be solved by the present invention is that in the form of blowing gas from the tundish upper nozzle, all the gas blown from the specific location of the nozzle can be floated in the tundish (above from the tundish upper nozzle). Alternatively, a tundish upper nozzle structure and continuous that can arbitrarily adjust the balance between the gas flow rate on the inner hole side or downward side of the tundish upper nozzle and the gas flow rate floating in the tundish (above from the tundish upper nozzle). To provide a casting method.
In addition, one tundish upper nozzle has various discharge positions, forms of discharge holes such as a porous body or a through hole, the number of discharge holes, and the like. "" Means one gas outflow part, in other words, "all the gas discharged from one through hole, or even if there are multiple discharge holes including a porous body, a plurality of bubbles immediately after discharge are combined into one bubble." It means "all the gas discharged from each of the aggregated parts of the very small discharge holes that form one bubble," and all the gas discharged from the nozzle on one tundish. Is not intended.

The reason why most of the gas blown from the vicinity of the upper end of the tundish upper nozzle as in the above patent document flows to the inner hole side of the tundish upper nozzle, and the gas cannot be levitated upward, that is, into the molten steel in the tundish. This is because the molten steel flow to the inner hole of the nozzle near the gas discharge hole near the upper end of the upper nozzle of the tundish is the main component, and the molten steel flow is stronger than the floating upstream of the bubbles. Et al. Found.

That is, the gist of the present invention is to discharge the gas at a position where the molten steel flow velocity to the nozzle inner hole is smaller than the floating flow velocity of the bubble in order to make the floating upstream of the bubble stronger than the molten steel flow to the nozzle inner hole. Moreover, it is a continuous casting method using a tundish upper nozzle structure capable of adjusting the balance between the gas flow rate to the nozzle inner hole and the floating gas flow rate, and the tundish upper nozzle structure.

Specifically, the present invention is the following 1 to 11 tundish nozzle structures and 12 continuous casting methods.
1. 1.
A collar-shaped object larger than the outer shape of the upper end portion of the tundish upper nozzle is provided on a part or the entire circumference of the outer periphery of the upper end portion of the tundish upper nozzle, and the lower surface, the outer peripheral surface, the upper surface, and the collar-shaped object of the flange-shaped object are provided. A tundish upper nozzle structure having one or more gas discharge holes on any one or more of the outer peripheral surfaces of the tundish upper nozzle below the object.
2.
The tundish upper nozzle according to 1 above, wherein the gas discharge hole of the brim-shaped object is a hole penetrating from the end of the gas flow path, which is a space in the brim-shaped object, or the lower surface to the upper surface of the brim-shaped object. Structure.
3. 3.
The tundish nozzle structure according to 1 or 2 above, wherein the lower surface of the brim-shaped object is provided with one or a plurality of grooves through which gas can pass.
4.
The tongue according to 1 or 2 above, wherein the tundish upper nozzle structure is attached to the tundish, and a part or all of the lower surface of the brim-shaped object is provided with a space through which gas can pass. Nozzle structure on the dish.
5.
The tundish upper nozzle structure is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper.
The length L (mm) from the vertical position of the inner hole surface of the lower end of the upper nozzle of the tundish to the gas discharge hole or the outer peripheral surface of the upper surface of the brim-shaped object satisfies the following equation 1; The nozzle structure on the tundish according to any one of the above.
L ≧ -1.875M2 + 26.332M-0.3929 ・ ・ ・ Equation 1
here,
M: Casting speed (t / min)
6.
The tundish upper nozzle structure is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper.
The length L (mm) from the vertical position of the inner hole surface of the lower end of the upper nozzle of the tundish to the gas discharge hole or the outer peripheral surface of the upper surface of the brim-shaped object satisfies the following equation 2 from 1 to 4 above. The nozzle structure on the tundish according to any one of the above.
L <-1.875M2 + 26.332M-0.3929 ・ ・ ・ Equation 2
here,
M: Casting speed (t / min)
7.
Any one of 1 to 5 above, wherein the length L (mm) from the vertical position of the inner hole surface of the lower end of the tundish upper nozzle to the gas discharge hole or the outer peripheral surface of the upper surface of the collar-shaped object is 60 mm or more. The tundish top nozzle structure according to item 1.
8.
The tundish upper nozzle structure according to any one of 1 to 7, wherein the brim-shaped object is joined to the tundish upper nozzle.
9.
The tundish upper nozzle structure according to 8 above, wherein the brim-shaped object and the tundish upper nozzle are joined by a screw, a bionette structure, or an adhesive.
10.
The brim-shaped object is fitted to the outer periphery of the tundish upper nozzle and is joined to the tuyere or the refractory layer at the bottom of the tundish adjacent to the tundish upper nozzle, any one of the above 1 to 7. Nozzle structure on the tundish described in.
11.
The nozzle structure on the tundish according to the above 10, wherein the brim-shaped object and the tuyere or the refractory layer at the bottom of the tundish are joined by a screw or a bionette structure or an adhesive.
12.
In the continuous casting method using the tundish nozzle structure according to any one of 1 to 4 above.
The tundish upper nozzle structure is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper.
The length L (mm) from the vertical position of the inner hole surface of the lower end of the upper nozzle of the tundish to the gas discharge hole or the outer peripheral surface of the upper surface of the flange-shaped object is the boundary length LB (mm) that satisfies the following equation 3. A continuous casting method in which almost all of the gas is floated by making it more than mm), or the flow rate of the gas downward on the inner hole side and the amount of floating are adjusted by making it less than the boundary length LB (mm).
LB = -1.875M2 + 26.332M-0.3929 ... Equation 3
here,
M: Casting speed (t / min)

According to the present invention, gas is supplied to the outer peripheral side of the tundish upper nozzle by providing a brim-shaped object larger than the outer shape of the tundish upper nozzle on a part or the entire circumference of the outer periphery of the upper end portion of the tundish upper nozzle. That is, it is possible to guide the molten steel to a region where the flow velocity of molten steel to the inner hole is small, and direct the gas upward from the vicinity thereof. As a result, the gas can be levitated in the tundish, and the effect of levitating inclusions in the tundish can be obtained. As a result, the quality of slabs can be improved.
In addition, from the vertical position of the lower end of the inner hole to the gas discharge part of the brim-shaped object larger than the outer shape of the tundish upper nozzle to the gas discharge hole or the part released upward after flowing along the brim-shaped object. By arbitrarily adjusting the length (L), the flow rate of the gas downward on the nozzle inner hole side and the floating flow rate into the tundish can be arbitrarily adjusted according to individual operations and the like.

The schematic cross-sectional view which shows the main part of the nozzle structure on the tundish which is one Embodiment of this invention. The figure which graphed the right side of the said formula 1 and formula 2. The figure which shows the gas behavior analysis result in the nozzle structure on the tundish of FIG.

FIG. 1 shows a main part of the tundish nozzle structure according to the embodiment of the present invention.
The tundish upper nozzle structure 10 of the present embodiment is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper 20, and the tundish upper nozzle 1 is provided on the entire circumference of the upper end portion of the tundish upper nozzle 11. It is provided with a flange-shaped object 12 having a size larger than the outer diameter (outer diameter) of the above. Further, the tundish upper nozzle structure 10 of the present embodiment is provided with a plurality of (six at equal intervals in the circumferential direction) gas discharge holes 13a on the outer peripheral surface of the tundish upper nozzle 11 below the flange-shaped object 12. ing. Further, the tundish upper nozzle structure 10 of the present embodiment is also provided with a plurality of gas discharge holes 13b (24 at equal intervals in the circumferential direction) on the upper end surface of the tundish upper nozzle 11.
As shown in FIG. 1, the tundish upper nozzle structure 10 is a space through which gas can pass through a part or all of the lower surface of the flange-shaped object 10 when the tundish upper nozzle structure 10 is mounted on the tundish 30. It is equipped with S (the molten steel exists in this space because the tundish is filled with molten steel during casting).

As described above, since the flange-shaped object 12 is provided in the tundish upper nozzle structure 10 of the present embodiment, the molten steel flow velocity (direction of arrow A) to the outer peripheral side of the tundish upper nozzle 11, that is, the inner hole 11a is small. The gas can be directed upward from the vicinity of the region by guiding it to the region (direction of arrow B). As a result, the gas can be levitated in the tundish 30, and the effect of levitating inclusions in the tundish 30 can be obtained. As a result, the quality of slabs can be improved.

Further, the present inventors, in such a tundish upper nozzle structure 10, the ratio of the flow rate of the gas downward on the inner hole 11a side to the amount of ascending into the tundish 30 is the length L shown in FIG. It was found that it largely depends on (mm) and the casting speed M (t / min). Here, the length L shown in FIG. 1 is the length from the vertical position of the inner hole surface 11b at the lower end of the tundish upper nozzle 11 to the gas discharge hole or the outer peripheral surface on the upper surface of the flange-shaped object 12. , Casting speed M (t / min) is synonymous with the throughput of molten steel.

The length L is defined as the vertical position of the inner hole surface 11b at the lower end of the tundish upper nozzle 11, although the outer circumference and the vicinity of the upper end of the tundish upper nozzle may have various shapes, but the inner hole surface at the lower end. The position (almost the same as the inner hole diameter) does not fluctuate at the same casting speed, that is, there is no big difference in the speed of the molten steel flowing into the inner hole, and even in the case of stopper control, the fitting is performed. This is because the portion positions are substantially the same in the radial direction according to the diameter of the inner hole.

That is, when the length L (mm) satisfies the following equation 1, almost all of the gas can be levitated in the tundish, and when the following equation 2 is satisfied, the present inventors can float the gas in the tundish. It was found that the flow rate of gas downward on the inner hole side and the amount of floating gas can be adjusted.
L ≧ -1.875M ² + 26.332M −0.3929 ・ ・ ・ Equation 1
L <-1.875M ² + 26.332M-0.3929 ・ ・ ・ Equation 2

As described above, the control of the inner hole side or the floating ratio of the gas in the present invention is performed for each gas discharged from each discharge hole.
Therefore, if there are gas discharge holes on the upper surface of the brim-shaped object, which is one of the criteria for determining the length L (mm), the above-mentioned description for each of the individual discharge holes, regardless of whether one or more of them are present. If it is the length, or if the gas flows from either the lower part of the brim-shaped object or the outer peripheral surface and the gas is released upward on the outer peripheral surface of the brim-shaped object, it reaches the outer peripheral surface of the brim-shaped object. Refers to the length.
Even if these coexist, the ratio of the inner hole side / levitation according to the above formula is determined by the L (mm) of each discharged gas. Whether or not to coexist and what to do with the number is related to the control of the gas discharge amount and form of the nozzle as a whole on the tundish, and this point may be set according to the individual operating conditions (optional).

The right side of Equations 1 and 2 is graphed as shown in Fig. 2. When the length L is in the region above this approximate line, almost all of the gas can be levitated in the tundish. If the area is less than the approximate line, the flow rate of the gas downward on the inner hole side and the amount of floating can be adjusted.

Next, the technical basis (derivation basis) of the above equations 1 and 2 will be described.

First, a simulation was performed under the following conditions using flow analysis software (fluent).
・ The inner hole diameter of the tundish upper nozzle is 80 mmφ,
・ As a stopper control, the space is about 12 mm for a diameter of 100 mmφ of the fitting part when fully closed.
-Gas discharge holes are 0.3 mmφ through holes, → 13b (24 holes), 13a (6 holes)
・ Bubble diameter 3.5 mmφ,
・ Casting speed is 0 to 5t / min
And said.
Furthermore, a water model experiment was conducted under the following conditions.
・ The inner hole diameter of the tundish upper nozzle is 80 mmφ,
・ As a stopper control, the space is about 15 mm for a diameter of 100 mmφ of the fitting part when fully closed.
・ The gas discharge hole is a through hole of 0.3 mmφ (the bubble diameter is about 1.5 to 3.5 mmφ as a result),
・ Casting speed is 3t / min
And said.

In the water model, when the diameter of the gas discharge hole is 0.3 mmφ, the bubble diameter is about 1.5 to 3.5 mmφ, and in molten graphite, it is 2 to 3 times that, and this gas discharge hole. The present inventors have conducted experiments so far that the bubble diameters of a through hole of 0.3 mmφ and an alumina-graphitite porous body (so-called porous refractory, average pore diameter ≈100 to 120 μm) are almost the same. ， It is known from the results of actual operation.

By these simulations in which the casting speed was changed, the above-mentioned length L (mm) as a boundary value capable of floating almost all of the (13a) gas blown from the outer circumference was obtained (each plot in FIG. 2). The result was expressed by an approximate line and an approximate formula by regression analysis, and the following formula 3 was obtained.
LB = -1.875M ² + 26.332M-0.3929 ... Equation 3

In comparison between these simulations and the water model experiment, the lengths L (mm) were almost the same.

In other words, the length L (mm) can be made equal to or greater than the boundary length LB (mm) satisfying the above equation 3, and almost all of the gas can be levitated, or the boundary length LB (mm). ), The flow rate of the gas downward on the inner hole side and the amount of floating can be adjusted.

Since the vertical axis L (mm) in FIG. 2 is the length from the vertical position of the lower end of the inner hole of the upper nozzle of the tundish, the length including the wall thickness of the flange-shaped object installation position of the upper nozzle structure of the tundish. That's right. Therefore, the case where the brim-shaped material has the above-mentioned wall thickness (mm) <LB (mm) is within the scope of the present invention.
Further, in general (many) castings, the amount of gas floating often decreases when the casting speed per such tundish upper nozzle is about 3 (t / min) or more. Considering the actual situation, if the length L (mm) is about 60 mm or more, almost all the gas will float upward.
That is, in general (many) castings, L ≧ 60 mm is required to float all the (13a) gas blown from the outer circumference upward, and in the case of L <60 mm, the smaller L is, the more gas is required. This means that the flow rate downward on the inner hole side is increased (see FIG. 3).

Hereinafter, a modified example of the present embodiment (FIG. 1) will be illustrated.
(A) In the present embodiment, the brim-shaped object 12 is installed on the entire circumference of the upper end portion of the tundish upper nozzle 11, but may be installed on a part of the outer circumference of the upper end portion of the tundish upper nozzle 11. Even if the brim-shaped object 12 is installed at a part of the outer periphery of the upper end portion of the upper nozzle 11 of the tundish, the effect of floating the gas in the tundish (the effect of floating inclusions in the tundish) is not a little. can get.
Further, the plan view shape of the brim-shaped object 12 is not limited to a circle, and may be, for example, an ellipse or a polygon.

(B) In the present embodiment, a plurality of gas discharge holes 13a are provided on the outer peripheral surface of the tundish upper nozzle 11 below the flange-shaped object 12 (six at equal intervals in the circumferential direction), but the gas discharge holes 13a are provided. One or more may be provided on any one or more of the lower surface, the outer peripheral surface, and the upper surface of the brim-shaped object 12. When the gas discharge hole 13a is provided in the collar-shaped object 12 in this way, the gas discharge hole 13a of the collar-shaped object 12 is the end of the gas flow path, which is the space inside the collar-shaped object 12, or the lower surface of the collar-shaped object 12. It can be a hole that penetrates the upper surface.

(C) In the present embodiment, the lower surface of the brim-shaped object 12 is provided with a space S through which gas can pass, but the lower surface of the brim-shaped object 12 is provided with one or more grooves through which gas can pass. You can also prepare.
Further, the groove includes a form in which the lower surface of the collar-shaped object 12 is curved in the circumferential direction to make a part of the circumferential direction concave, and the concave portion extends in the radial direction. That is, the groove may have a structure as a gas flow path through which gas can be concentrated and flow toward the outer peripheral side.
Further, a porous refractory having high gas permeability can be installed at the position of the space S instead of the space.

(D) In the present embodiment, the collar-shaped object 12 is joined to the tundish upper nozzle 11 by an adhesive, but it may be joined to the tundish upper nozzle 11 by a screw or a bionet structure.
Further, the brim-shaped object 12 may be fitted to the outer periphery of the tundish upper nozzle 11 and joined to the tuyere 31 adjacent to the tundish upper nozzle 11 or the refractory layer 32 at the bottom of the tundish. The joining can be done with screws or bionet structures, or adhesives.

(E) The tundish upper nozzle structure 10 of the present embodiment is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper 20, but is for continuous casting of steel whose flow rate of molten steel is controlled by a sliding nozzle device. You can also do it. That is, it can be applied to a structure in which there is no so-called obstacle that changes the flow of molten steel above the nozzle on the tundish.

Under the following casting conditions and tundish nozzle conditions, a conventional product (comparative example) in which the flange-shaped object 12 is not installed and a conventional product (comparative example) in which the flange-shaped object 12 is installed and the length L (mm) is 30 to 60 mm. Using the product of the present invention (Example) changed in the range of (Example), a continuous casting test of steel in which the flow rate of molten steel is controlled by a stopper was carried out. The number of surface defects was evaluated. Specifically, the alumina adhesion thickness in the tundish upper nozzle in the conventional product was set to 1.0, and the alumina adhesion thickness in the tundish upper nozzle in the present invention product was indexed. The smaller the alumina adhesion thickness index in the nozzle, the smaller the alumina adhesion thickness in the nozzle on the tundish. Further, the number of coil surface defects in the conventional product was set to 1.0, and the number of coil surface defects in the product of the present invention was indexed. The smaller the coil surface defect occurrence index, the smaller the number of coil surface defects, that is, the better the quality of the slab.

<Casting conditions>
-Steel type: General aluminum killed steel-Casting size: 250 mm (thickness) x 1250 mm (width)
-Casting speed (throughput of molten steel): Approximately 3 (t / min)
<Nozzle condition on tundish>
・ Inner hole diameter: 80 mm
-Diameter x number of gas discharge holes: 0.3 (mm) x 13b (24 holes), 13a (6 holes)
・ Gas (Ar) discharge amount: 10 (L / min)
-Gas (Ar) discharge flow velocity: 1.56 (m / min)

Table 1 shows the results of the continuous casting test. Since the casting speed (throughput of molten steel) is about 3 (t / min) in this continuous casting test, the boundary length LB in the above formula 3 is about 60 mm.

The floating amount (ratio) of bubbles is an index with the total amount as 100, and is based on an estimated value (example) from visual inspection and water model experiments, etc., where 100 is almost all floating and 0 is all toward the inner hole side. Means the influx of.

As shown in Table 1, the product of the present invention (Example 3) in which L (mm) has a boundary length LB (about 60 mm) or more has a tundish upper nozzle as compared with the conventional product (Comparative Example 1). The thickness of alumina adhesion has decreased, and the number of surface defects on the coil has also decreased.
For the products of the present invention (Examples 1 and 2) in which L (mm) is less than the boundary length LB (about 60 mm), the amount of air bubbles floating / the amount on the inner hole side can be adjusted by adjusting L (mm). It shows that the proportions can be adjusted, which in turn can also adjust the quality of the slabs.

10 Tundish upper nozzle structure 11 Tundish upper nozzle 11a Inner hole 11b Inner hole surface 12 Brim-shaped object 13a, 13b Gas discharge hole 20 Stopper 30 Tundish 31 Tuft 32 Tundish bottom refractory layer S space

Claims (12)

A collar-shaped object larger than the outer shape of the upper end portion of the tundish upper nozzle is provided on a part or the entire circumference of the outer periphery of the upper end portion of the tundish upper nozzle, and the lower surface, the outer peripheral surface, the upper surface, and the collar-shaped object of the flange-shaped object are provided. A tundish upper nozzle structure having one or more gas discharge holes on any one or more of the outer peripheral surfaces of the tundish upper nozzle below the object. The tundish according to claim 1, wherein the gas discharge hole of the brim-shaped object is a hole penetrating the end of the gas flow path, which is a space in the brim-shaped object, or the lower surface to the upper surface of the brim-shaped object. Nozzle structure. The tundish nozzle structure according to claim 1 or 2, wherein the lower surface of the brim-shaped object is provided with one or a plurality of grooves through which gas can pass. The first or second aspect of the present invention, wherein the nozzle structure on the tundish is provided with a space through which gas can pass in a part or all of the lower surface of the collar-shaped object in a state where the nozzle structure is attached to the tundish. Nozzle structure on the tundish. The tundish upper nozzle structure is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper.
From claim 1, the length L (mm) from the vertical position of the inner hole surface of the lower end of the upper nozzle of the tundish to the gas discharge hole or the outer peripheral surface of the upper surface of the brim-shaped object satisfies the following formula 1. The tundish top nozzle structure according to any one of 4.
L ≧ -1.875M ² + 26.332M −0.3929 ・ ・ ・ Equation 1
here,
M: Casting speed (t / min) The tundish upper nozzle structure is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper.
From claim 1, the length L (mm) from the vertical position of the inner hole surface of the lower end of the tundish upper nozzle to the gas discharge hole or the outer peripheral surface of the upper surface of the brim-shaped object satisfies the following equation 2. The tundish top nozzle structure according to any one of 4.
L <-1.875M ² + 26.332M-0.3929 ・ ・ ・ Equation 2
here,
M: Casting speed (t / min) Any of claims 1 to 5, wherein the length L (mm) from the vertical position of the inner hole surface of the lower end of the tundish upper nozzle to the gas discharge hole or the outer peripheral surface of the upper surface of the collar-shaped object is 60 mm or more. The tundish top nozzle structure according to item 1. The tundish upper nozzle structure according to any one of claims 1 to 7, wherein the brim-shaped object is joined to the tundish upper nozzle. The tundish upper nozzle structure according to claim 8, wherein the brim-shaped object and the tundish upper nozzle are joined by a screw, a bionette structure, or an adhesive. Any one of claims 1 to 7, wherein the brim-shaped object is fitted to the outer periphery of the tundish upper nozzle and is joined to a tuyere or a refractory layer at the bottom of the tundish adjacent to the tundish upper nozzle. Nozzle structure on the tundish described in the section. The nozzle structure on a tundish according to claim 10, wherein the brim-shaped object and the tuyere or the refractory layer at the bottom of the tundish are joined by a screw or a bionette structure or an adhesive. In the continuous casting method using the tundish nozzle structure according to any one of claims 1 to 4.
The tundish upper nozzle structure is for continuous casting of steel whose flow rate of molten steel is controlled by a stopper.
The length L (mm) from the vertical position of the inner hole surface of the lower end of the upper nozzle of the tundish to the gas discharge hole or the outer peripheral surface of the upper surface of the flange-shaped object is the boundary length LB (mm) that satisfies the following equation 3. A continuous casting method in which almost all of the gas is floated by making it more than mm), or the flow rate of the gas downward on the inner hole side and the amount of floating are adjusted by making it less than the boundary length LB (mm).
LB = -1.875M ² + 26.332M-0.3929 ... Equation 3
here,
M: Casting speed (t / min)

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