JPH0985393A - Molten metal pouring nozzle for belt wheel type continuous caster - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a molten metal pouring nozzle for a belt wheel type continuous caster, which obtains a cast block having high quality. SOLUTION: In the molten metal pouring nozzle for the belt wheel type continuous caster, the cross sectional area of molten metal passage at the tip part 18 of the molten metal pouring nozzle 10 is narrowed to 0.6 times of the cross sectional area of the cast block. Since the molten metal passage of the molten metal pouring nozzle 10 is narrowed at the tip part, flow speed of the molten metal at the tip part of the molten metal pouring nozzle is quickened, and the deposit and the coarsening of high m.p. compound at the tip part of the molten metal pouring nozzle 10 are restrained, and the mixture thereof into the cast block is prevented. Therefore, the high quality cast block is obtd.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pouring nozzle for a belt wheel type continuous casting machine, which can obtain a high quality ingot.

[0002]

2. Description of the Related Art As shown in FIG. 5, a belt wheel type continuous casting method uses a groove 32 formed on an outer peripheral surface of a rotary wheel 31.
A metal endless belt 33 is brought into contact with a part of the moving mold 34 to form a moving mold 34, a molten metal 41 is injected from one open end 35 of the moving mold 34, and the molten metal 41 is solidified in the moving mold 34. The ingot 42 is used, and the ingot 42 is the other open end of the moving mold 34.
It is a casting method that draws continuously from 36.

In this belt wheel type continuous casting method, usually, one open end 35 of the moving mold 34 is located at the top of the rotary wheel 31, the pouring nozzle 14 is placed at the open end 35, and its axis is made horizontal. Distribute. As shown in FIG. 6, the pouring nozzle 14 is formed by coating the inner and outer surfaces of the iron frame 16 with a heat insulating material 17, and the inner cross-sectional area of the molten metal passage 19 of the pouring nozzle 14 is set as large as possible (ingot cross-sectional area). The molten metal 41 is statically injected into the moving mold 34. The surface of the pouring nozzle 14 that contacts the molten metal is coated with graphite 20. The pouring nozzle 15 shown in FIG. 7 has a tip end portion surrounded by a heat insulating material 17.

[0004]

The tip portion of the pouring nozzle 14 shown in FIG. 5 has a groove 32 of the rotating wheel 31 at the outer periphery thereof.
Since it is in contact with the inner surface of the molten metal, the molten metal temperature 41 drops sharply,
A high melting point compound crystallizes in the molten metal. This high melting point compound is deposited on the inner wall surfaces of the pouring nozzles 14 and 15 and becomes coarse, and this coarse high melting point compound is separated by the flow of the molten metal 41 and mixed into the ingot, casting cracks, rolling cracks, and further It was a cause of disconnection during wire drawing. As a countermeasure for this, a method of heating the molten metal to a high temperature to suppress the crystallization of the high melting point compound has been taken. However, the method of heating the molten metal to a high temperature has various problems such as high heating cost, increase in oxidation loss of the molten metal, increase of oxygen and hydrogen gas absorption of the molten metal, and formation of blowholes in the ingot. Yes it was not practical. The present inventors have conducted diligent research based on such a situation, and by accelerating the flow of the molten metal in the pouring nozzle, they found that coarsening of the deposited compound can be prevented, and further research is conducted. The present invention has been completed. It is an object of the present invention to provide a pouring nozzle for a belt wheel type continuous casting machine, in which coarsening of a high melting point compound is suppressed and a high quality ingot can be obtained.

[0005]

According to the first aspect of the present invention,
In a pouring nozzle for a belt-wheel type continuous casting machine, the cross-sectional area of the molten metal passage at the tip of the pouring nozzle is narrowed to 0.6 times or less of the ingot cross-sectional area, It is a pouring nozzle.

In this invention, since the molten metal passage is narrowed at the tip portion, the flow velocity of the molten metal at the tip portion of the pouring nozzle is increased, and the coarsening of the high melting point compound at the tip portion of the pouring nozzle is suppressed. To be done. The reason why the cross-sectional area of the molten metal passage at the tip of the pouring nozzle is limited to 0.6 times or less of the ingot cross-sectional area is that the effect cannot be sufficiently obtained when it exceeds 0.6 times. preferable. If it is too narrow, it will be difficult to supply the molten metal and productivity will be reduced.

In the present invention, when at least the tip of the pouring nozzle is surrounded by a heat insulating material, a decrease in the temperature of the molten metal is suppressed and the high melting point compound is hard to deposit. Further, even if the molten metal is in a turbulent state in the narrowed molten metal passage portion, the periphery of the tip portion of the pouring nozzle is surrounded by a heat insulating material and is shielded from the outside air, so that gas entrapment is prevented.

In the present invention, in order to narrow the molten metal passage, in addition to the method of increasing the wall thickness of the tip portion of the pouring nozzle,
Any method such as a method of arranging a block at the tip of the pouring nozzle is applied. When the block is arranged, the molten metal passage in that part is narrowed and the flow velocity is increased.

According to a third aspect of the present invention, in a pouring nozzle for a belt-wheel type continuous casting machine, a block is arranged at a tip portion of the pouring nozzle, and a pouring type for a belt-wheel type continuous casting machine. It is a nozzle.

When the block is arranged at the tip portion of the pouring nozzle in this way, the molten metal passage in that portion is narrowed, the flow velocity of the molten metal is increased, and the coarsening of the deposition of the high melting point compound is suppressed. Also in this case, gas entrapment is prevented by surrounding at least the tip of the pouring nozzle with a heat insulating material,
Further, by narrowing the cross-sectional area of the molten metal passage in the portion where the blocks are arranged to 0.6 times or less of the cross-sectional area of the ingot, the coarsening of the deposition of the high melting point compound can be more reliably suppressed.

In the present invention, if the heat-insulating property of the pouring nozzle, particularly the heat-insulating property of the tip portion in contact with the mold, is increased, the melt temperature in the pouring nozzle is prevented from lowering and the precipitation of the high melting point compound is suppressed. The high melting point compound of the present invention is preferred because it promotes the effect of preventing coarsening. In the present invention, it is preferable that the cross-sectional area is narrowed only at the tip of the pouring nozzle where the melt temperature decreases.

[0012]

The present invention will be described below in detail with reference to examples. (Embodiment 1) FIGS. 1A and 1B show the first of the pouring nozzle of the present invention.
FIG. 3 is a vertical sectional view and a front view showing the embodiment of FIG. Pouring nozzle
The entire upper side wall of the inner surface of the tip portion 10 is steeply projected at the tip portion 18. Therefore, the flow rate of the molten metal is 10
It accelerates rapidly at the tip 18 of the.

(Second Embodiment) FIGS. 2A and 2B are a longitudinal sectional view and a front view showing a second embodiment of the pouring nozzle of the present invention. The center portion of the upper side wall of the inner surface of the tip portion of the pouring nozzle 11 projects at the tip portion 18 at a steep inclination from the longitudinal direction and the width direction. Therefore, the flow velocity of the molten metal depends on the tip portion 18 of the pouring nozzle 11.
It speeds up rapidly. As compared with the pouring nozzle shown in FIG. 1, the molten metal is more likely to be disturbed, and the deposition of the high melting point compound is prevented and the deposition compound is exfoliated.

(Embodiment 3) FIGS. 3A and 3B are a longitudinal sectional view and a front view showing a third embodiment of the pouring nozzle of the present invention. On the inner upper surface of the tip of the pouring nozzle 12, a quadrangular pyramid-shaped block 21 is attached to the bottom (flat surface) by the support rod 24.
Is attached toward the tip of the pouring nozzle 12. By this block 21, the melt passage 19 of the pouring nozzle 12 is gradually narrowed toward the tip, and the flow velocity of the melt is increased at the tip portion 18 of the pouring nozzle 12.

(Embodiment 4) FIGS. 4A and 4B are a longitudinal sectional view and a front view showing a fourth embodiment of the pouring nozzle of the present invention. The pouring nozzle 13 is formed by curving each side surface of the quadrangular pyramid-shaped block shown in FIG. 3 into a concave shape. Since each side of the block 22 is curved in a concave shape, the molten metal is more likely to be disturbed than the pouring nozzle shown in the third embodiment, and the deposition of the high melting point compound is prevented and the deposition of the deposited compound is promoted.

By the belt wheel type continuous casting method shown in FIG. 5, a molten Al-0.8 wt% Zr alloy was cast, and the produced ingot (cross-sectional area 1800 mm ² ) was continuously hot-rolled to obtain a 9.5 mmφ product. A rough wire was drawn, and this wire was then drawn into a 3.6 mmφ wire. The temperature of the melt was 800 ℃ in the tundish and 760 ℃ at the nozzle tip. 1 to the pouring nozzle
Each pouring nozzle shown in 4 was used. For the pouring nozzle, the inner and outer surfaces of the iron frame are made of calcium silicate heat insulating material (thermal conductivity:
0.15 Kcal / mh ° C) was used. The blocks 21 and 22 of Examples 3 and 4 were made of graphite, and the blocks were supported by graphite rods 24 on the inner surface of the iron frame of the pouring nozzle. Defects in the ingots and rough lines produced were detected online. Moreover, the number of wire breakages in the wire drawing step was examined. For comparison, the same investigation was conducted for a conventional pouring nozzle (FIGS. 6 and 7) in which the molten metal passage was not narrowed at the tip portion. The results are shown in Table 1. The ratio of the minimum cross-sectional area of the tip of the molten metal passage to the ingot cross-sectional area was changed variously.

[0017]

[Table 1] The ratio of the minimum cross-sectional area of the pouring nozzle tip to the ingot cross-sectional area. ~ Number of defects or number of wire breaks per 200 tons of sample.

As is clear from Table 1, the invention example (No. 1)
In No. 8), the number of defects was small in both the ingot and the rough drawn wire, and the number of wire breakages in the wire drawing step was about 1 to 4 which was extremely small. This is because the flow rate of the molten metal at the tip of the nozzle is high, so that the high melting point compound does not deposit, or even if it deposits, it flows out before coarsening. On the other hand, in Nos. 9 and 10 of the conventional example, defects were generated in the ingot and the rough wire, and many wire breakages occurred in the wire drawing step. This is because the flow of molten metal at the tip of the nozzle is slow,
This is because the high melting point compound was deposited and coarsened, and the coarsened high melting point compound flowed into the mold and was mixed into the ingot as it was. When a broken portion of the wire was investigated, a coarse high melting point compound was detected.

(Example 5) In Example 3, the silica / alumina type heat insulating material (heat conductivity: 0.12 Kcal / mh) was used as the heat insulating material.
C.) or by coating the outside and / or inside of the nozzle with a silica / alumina heat insulating material to improve the heat retention of the nozzle, and by the same method as in Example 3, Al-0.8
A wt% Zr alloy wire was manufactured. Table 2 shows the number of wire breaks.

[0020]

[Table 2] No.12 to 14: Calcium silicate type heat insulating material coated with silica-alumina type. The value (mm) is the thickness of silica-alumina type heat insulating material.

As is clear from Table 2, a heat insulating material using a silica-alumina heat insulating material having excellent heat insulating properties (poor thermal conductivity) (No. 11) or a silica-alumina heat insulating material is used. In the coated products (Nos. 12 to 14), the decrease in the melt temperature at the tip of the pouring nozzle was reduced, and the number of wire breaks was reduced. This is because the amount of the high melting point compound deposited at the tip of the nozzle decreased.

[0022]

As described above, according to the present invention,
The high melting point compound does not deposit on the inner wall of the pouring nozzle, coarsens and is not mixed into the ingot, and therefore a high quality ingot which does not cause rolling cracks or disconnection can be obtained. Further, by increasing the heat insulating property of the nozzle, the precipitation of the high melting point compound can be reduced, and the quality of the ingot can be further improved. Therefore, it has a remarkable industrial effect.

[Brief description of drawings]

FIG. 1 is a vertical sectional view and a front view showing a first embodiment of a pouring nozzle of the present invention.

FIG. 2 is a vertical sectional view and a front view showing a second embodiment of the pouring nozzle of the present invention.

FIG. 3 is a vertical sectional view and a front view showing a third embodiment of the pouring nozzle of the present invention.

FIG. 4 is a vertical sectional view and a front view showing a fourth embodiment of the pouring nozzle of the present invention.

FIG. 5 is an explanatory diagram of a belt-wheel type continuous casting method.

FIG. 6 is a front view of a conventional pouring nozzle.

FIG. 7 is a front view of a conventional pouring nozzle.

[Explanation of symbols]

 10-15… Pouring nozzle 16 ……… Iron frame 17 …… Insulation 18 …… Tip of pouring nozzle 19 ……… Molten passage 20 ……… Graphite 21,22… Pyramid block 23 …… … Bottom of square pyramid block 24 ………… Block support rod 31 ………… Rotating wheel 32 ……… Rotate wheel outer peripheral groove 33 ………… Metal belt 34 ………… Movable mold 35 ………… One open end 36 ……… The other open end 41 ……… Molten metal 42 ……… Ingot

Claims (4)

[Claims] 1. A belt wheel type continuous casting machine pouring nozzle, wherein a cross-sectional area of a molten metal passage at a tip portion of the pouring nozzle is narrowed to 0.6 times or less of an ingot cross-sectional area. Wheel pouring nozzle for continuous casting machine. 2. A belt wheel type continuous casting machine pouring nozzle, wherein at least a tip portion of the pouring nozzle is surrounded by a heat insulating material, and a cross-sectional area of a molten metal passage at a tip portion of the pouring nozzle is A pouring nozzle for a belt-wheel type continuous casting machine characterized by being narrowed to 0.6 times or less of the ingot cross-sectional area. 3. A pouring nozzle for a belt-wheel type continuous casting machine, wherein a block is arranged at a tip portion of the pouring nozzle. 4. A belt wheel type continuous casting machine pouring nozzle, wherein at least a tip portion of the pouring nozzle is surrounded by a heat insulating material, and a block is arranged at the pouring nozzle tip portion. A pouring nozzle for a belt-wheel type continuous casting machine, wherein a cross-sectional area of a molten metal passage in a portion where the blocks are arranged is narrowed to 0.6 times or less of a cross-sectional area of the ingot.