EP0522346A1 - Manufacturing of an immersion nozzle and tundish for use in continuous casting of metals - Google Patents

Abstract

The invention relates to a method for the open continuous casting of molten metals from casting vessels (1), via a tundish (2), into a mold (5), in which the inflow of steel is controlled by means of a pouring nozzle (3) inserted into the refractory immersion nozzle (4) on the tundish (2). The invention furthermore relates to a refractory immersion nozzle used in carrying out the method and to a method for its production. According to the invention, a refractory immersion nozzle with an inserted pouring nozzle is used. The immersion nozzle forms an integral constructional unit with the pouring nozzle of the tundish and has an inserted pouring nozzle. <IMAGE>

Description

The invention relates to a method and a device for the open continuous casting of metal melts from casting vessels via an intermediate vessel (distributor) into a mold.

In the casting processes customary today, the pouring of the molten metals into a mold can essentially take place according to the principle of "open casting" or "hidden casting". With open pouring, the pouring jet emerges unprotected from the refractory pouring spout of the pouring vessel. This process is preferably carried out on continuous casting plants with small cross sections, in particular less than 200 cm². On the one hand, no hidden casting is necessary for quality reasons, on the other hand, the cross-sections for immersing immersion spouts are so small that it is very difficult to regulate them with a stopper or slide.

In such systems, the steel flow is therefore usually automatically regulated by the casting speed in accordance with the free cross section of the pouring nozzle used in the perforated brick.

In the case of hidden casting, fire-resistant immersion nozzles are used, which protect the liquid steel from reoxidation until it enters the continuous casting mold. The pouring jet is regulated by means of a plug closure or slide closure. The refractory spout used in the bottom of the distributor and the immersion tube are two separate parts.

There is often a need to retrofit existing systems that work on the principle of open casting so that the advantages of hidden continuous casting can be used. So far, however, this has involved major modifications to the intermediate vessels (distributors), the molds and the continuous caster, for which considerable investments are required. The use of new locking systems is particularly complex. If bath level controls are to be used for automatic continuous casting, individual control is required for each mold in multiple mold arrangements.

The object of the invention is to utilize the advantages of concealed continuous casting in devices for the continuous casting of steel, in which the steel inflow is controlled via the free cross section of the pouring nozzle.

To achieve this object, the measures and features of the claims are proposed according to the invention. The steel inflow is controlled via the free cross-section of a pouring nozzle in the immersion nozzle. The insertion of an orifice ring in a dip tube was known (DE 36 07 104 C1), but the aperture ring was used to set a laminar flow of the melt in the dip tube, but not to control the flow rate.

The pouring nozzle of the tundish is integrally formed with the immersion pouring tube. The pouring nozzle used therein reduces the flow cross-section within the immersion spout, which is necessary the liquid steel in the dip spout does not freeze. In itself, the pouring nozzle could also be in one piece with the immersion pouring spout, but for manufacturing reasons and in order to be able to provide the zone exposed to the most wear and tear with a higher-quality refractory material, it is more expedient to mold the pouring nozzle separately and to insert it into the immersion pouring spout at the desired location , especially glue in. It is preferred to use the pouring nozzle at the level of the lower edge of the tundish because it has the best effect there.

Casting nozzles with different dimensions in terms of length and free cross-section can be selected to control the steel flow depending on steel melts of various compositions. The pouring nozzles usually have a conical widening at the inlet, but in the case of steel melts with a higher viscosity it is advantageous if the refractory insert is designed as an annular diaphragm. The control of the steel inflow takes place as before via the cross section of the pouring nozzle, the pouring speed depending on the ferrostatic pressure in the tundish.

For practical use, it is particularly important to adjust the thermal conductivity of the refractory immersion spout and its use. The refractory immersion nozzle can preferably consist of alumina graphite. It can be pressed isostatically or, preferably, vacuum-extruded and re-pressed. The immersion nozzle can have a circular, oval or angular cross section. The pouring nozzle is preferably made of refractory material with a zirconium dioxide (ZrO₂) content of more than 60%, the rest essentially Al₂O₃.

It can be advantageous to install plugs for each immersion nozzle that are only required for opening and closing the steel inlet. All plugs can be opened or closed centrally simultaneously or individually. With the introduction of stopper closures it is also achieved that the same conditions prevail during the casting process. At the same time, the discharge of the first quantity of steel, which is often contaminated with refractory components from the lining of the intermediate vessel, is avoided and an improvement in output is likewise achieved.

The invention is explained in more detail with reference to the drawing.

Fig. 1

Das Schema einer Stranggußanlage unter Verwendung des Tauchausgußrohres gemäß der Erfindung,

Fig. 2

einen Längsschnitt des Tauchausgußrohres mit der Gießdüse in einer Ausführungsform und

Fig. 3

in einer weiteren Ausführungsform.

Show it:

Fig. 1

The diagram of a continuous casting installation using the immersion pouring pipe according to the invention,

Fig. 2

a longitudinal section of the submerged nozzle with the pouring nozzle in one embodiment and

Fig. 3

in a further embodiment.

In the schematic representation in FIG. 1, 1 denotes a ladle, from the bottom spout of which liquid steel flows into the intermediate vessel 2 and is distributed there, which is why it is often also called "distributor" or "Tundish" from the English. The casting speed is controlled in accordance with the ferrostatic pressure in the intermediate vessel 2. The pouring speed is also dependent on the free cross section of the pouring nozzle 3, which is inserted approximately at the level of the bottom of the intermediate vessel 2 in the dip tube 4. The pouring nozzle 3 thus reduces the cross section of the immersion pouring tube 4, which is integral with the pouring nozzle seated in the bottom of the intermediate vessel 2, from which at open continuous casting, the steel flows freely in the unprotected form against the entry of atmospheric oxygen into the continuous casting mold 5 located underneath. In the illustrated embodiment of FIG. 1, three continuous casting molds 5 are connected to the intermediate vessel 2, each of which is connected to one another via a separate immersion pouring tube 4. The liquid steel thus passes from the intermediate vessel 2 through the immersion pouring tube 4 into the continuous casting mold 5, solidifies therein and comes out of the continuous casting mold 5 as a partially solidified strand 6.

In the embodiment according to the invention, the liquid steel is now protected from oxidation by atmospheric oxygen on its way from the tundish 2 into the continuous casting mold 5 through the immersion pouring tube 4, as is customary in the case of hidden continuous casting. This is made possible by simply extending the pouring nozzle in the tundish 2 down into the continuous casting mold 5. This means that existing systems can be converted from open to concealed continuous casting using relatively simple means at low cost.

In the embodiment in Fig. 2, the pouring nozzle 3 in the immersion nozzle 4 has a downwardly tapering inlet with a subsequent cylindrical section. In contrast, the pouring nozzle in the embodiment according to FIG. 3 has the shape of an annular diaphragm. The shape of the pouring nozzle can be changed from case to case depending on the viscosity of the molten steel.

Claims (7)

Process for the open continuous casting of molten metal from casting vessels via an intermediate vessel into a mold, in which the steel inflow is controlled by means of a pouring nozzle inserted into the refractory immersion nozzle on the intermediate vessel. Intermediate vessel for the open continuous casting of molten metals with at least one refractory immersion nozzle for carrying out the method according to claim 1,
characterized in that the immersion spout (4) forms an integral unit with the pouring nozzle of the intermediate container (2) and has an inserted pouring nozzle (3). Intermediate vessel according to claim 2,
characterized in that the pouring nozzle (3) is inserted at the level of the lower edge of the intermediate vessel (2) in the immersion spout (4). Intermediate vessel according to claim 2 or 3,
characterized in that the pouring nozzle (3) has the shape of an annular diaphragm. Intermediate vessel according to one of claims 2 to 4,
characterized in that the immersion nozzle (4) consists of alumina graphite. Intermediate vessel according to one of claims 2 to 5,
characterized in that the pouring nozzle (3) consists of a refractory material with a zirconium dioxide (ZrO₂) content of at least 60%. Method for producing a refractory immersion nozzle according to one of claims 2 to 6,
characterized in that the immersion spout (4) is vacuum extruded and repressed.

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