EP0379647A2 - Refractory nozzle and induction coil therefor - Google Patents

Abstract

The invention relates to a refractory nozzle between a vessel containing a metal melt and a withdrawal device for the metal melt, in particular a refractory outlet for molten steel. <??>To avoid the metal melt freezing in and to avoid deposits of constituents of the metal melt on the inner surface (2) of the wall of the outlet, the invention essentially proposes that the inner wall (1) of the outlet be composed completely or partially of a ceramic material which is electrically conductive at least at the liquidus temperature of the metal melt and can be inductively heated by means of an induction coil (4), or contains such a material. The invention also relates to the particular design of an induction coil (4) which is economic to use for this purpose or, indeed, in another context.

Description

The invention relates to a refractory connection between a vessel containing a molten metal and an extraction device for the molten metal, in particular a refractory spout for molten steel.

With such spouts there is particularly when it comes to the continuous casting of molten metal, e.g. Melting steel, in molds for thin slabs, because of the relatively small cross sections of the spouts, the problem of freezing the molten metal and smearing due to undesirable deposits, such as alumina deposits from the molten metal.

The object of the present invention is to provide a refractory spout of the type mentioned, in which the disadvantages mentioned are reliably avoided.

This object is essentially achieved in that the spout inner wall consists entirely or partially of ceramic material which is electrically conductive at at least the liquidus temperature of the molten metal and can be inductively heated by means of a primary coil, or has such a material.

This makes it possible to use inductive heating in the required areas of the spout, which e.g. has already been heated by the molten metal flowing through, to avoid freezing of the molten metal or undesirable deposits in an economical manner. The required conductivity should expediently begin at least at the temperature and should at least continue until the liquidus temperature of the molten metal or above which the pouring inner wall is heated by the molten metal itself.

Induction furnaces are known per se in which the wall of the heating chamber is heated by means of an induction coil surrounding it (cf. e.g. GB 2 121 028 A).

It is also known per se in a device for regulating the flow rate of a molten metal during continuous casting (cf. EP 0 155 575 B1) to arrange an electromagnetic coil concentrically around the pouring tube in order to constrict the casting jet and thus one when the coil is electrically acted on to achieve a reduced flow cross-section. A certain inductive heating of the molten metal can also occur in the effective range of the coil, which is arranged only a short distance around the pouring tube. In this way, however, freezing of the molten metal and undesired deposition of, for example, alumina on the inner surface of the pouring wall cannot be avoided.

With the invention, the induction coils known per se are supplied with a completely new application and thereby undesirable freezing of molten metal in a refractory spout and undesirable deposits from the molten metal are reliably avoided by inductively heating the pouring wall to the required temperature or keeping it there , in which the entire adverse side effects are avoided.

Under certain conditions, it is sufficient if the spout does not consist of the electrically conductive ceramic material over its entire length, but only over a longitudinal section of the spout wall, and if the induction coil is assigned to this longitudinal section. In the case of particularly long spouts, it may also be expedient to have two or more such longitudinal sections follow one another at a distance, so that the metal melt is repeatedly brought to the required temperature as it flows through the spout, at which a freezing of the metal melt and a Deposition of e.g. Prevents alumina.

As an electrically conductive, inductively heatable ceramic material, one which is or has ZrO₂ is particularly suitable in the context of the invention. Such materials have already proven themselves as sheathing induction coils and have excellent erosion and corrosion resistance against molten metal.

For an effective thermal coupling of the electromagnetic coil and the electrically conductive, inductively heatable ceramic material, it is advantageous if the ZrO₂ is stabilized by means of Y₂O₃, CaO and / or MgO.

In a special embodiment of the invention, the primary coil itself can also consist of ceramic material, which is particularly advantageous if cooling for energy reasons is to be dispensed with.

The primary coil can advantageously be part of the pouring wall itself, for example embedded in it.

If, according to a further embodiment of the invention, the output of the primary coil can be regulated, the heating temperature can be changed to regulate the temperature of the molten metal and / or to prevent or remove deposits from the molten metal.

For the intended use here, the frequency range should expediently be in the order of 3 to 10 MHz.

The invention relates to a novel, at least one primary coil inductor for heating electrically conductive material, in particular electrically conductive, ceramic material or components made therefrom. According to the invention, it is distinguished by the fact that its coil consists of an electrically conductive ceramic material. This solves the problem on economical way to operate an induction coil permanently. As with metal coils, cooling is not required.

Such an induction coil can be used according to a further proposal of the invention for inductively heating components of the electrically conductive material, in particular tubular components, preferably connections between a vessel containing molten metal and a withdrawal device, such as refractory spouts of the type described above. In such cases, the coil preferably encloses the component or is integrated in its wall.

Further objectives, features, advantages and possible applications result from the following description of exemplary embodiments with reference to the drawing. All of the described and / or illustrated features, alone or in any meaningful combination, form the subject matter of the present invention, regardless of how they are summarized in the claims or their relationship.

• Figur 1 schematisch einen die Erfindugn aufweisenden feuerfesten Ausguß im Vertikalschnitt, und
• Figur 2 eine Schnittdarstellung entsprechend Figur 1 für eine andere Ausführungsform eines erfindungsgemäßen Ausgusses.

Show it:

• Figure 1 shows schematically a refractory spout having the invention in vertical section, and
• Figure 2 is a sectional view corresponding to Figure 1 for another embodiment of a spout according to the invention.

The refractory spout for a continuous caster according to FIG. 1 has a spout inner wall 1 which encloses a flow channel 3. At a distance, the spout inner wall 1, in this case over its entire length L, is surrounded by a primary coil 4. The primary coil 4 in turn is provided with a metallic shield 5 against stray radiation, which can be cooled. The space 7 delimited by the shield 5 and the outer wall surface 6 of the pouring inner wall 1 can be filled with a thermally insulating material, for example a ZrO₂ granulate. The primary coil 4 can be connected to a frequency-dependent current source with controllable power. In this way, the inner wall surface 2 of the spout inner wall 1 delimiting the flow channel 3 can be heated to the required extent in a controlled manner or can be kept at the desired temperature after the wall has been heated by the molten metal flowing through it, in order to avoid freezing of the molten metal. The inner wall 2 can have a layer or casing that is electrically insulating from the molten steel.

In the embodiment according to FIG. 2, the primary coil 4 also extends over the entire length L of the spout inner wall 1, in contrast to FIG. 1, however, it is embedded in the stronger spout inner wall 1 itself. The optionally cooled metal shield 5 is here directly on the outer wall surface 6 of the inner wall 1. In the embodiment according to FIG. 2, the inner wall 2 can also have a layer or casing which is electrically insulating from the molten steel.

The primary coil 4 can be arranged such that its inducing magnetic field is directed parallel or perpendicular to the axis of the spout.

In both of the exemplary embodiments shown, the primary coil 4 itself can consist of electrically conductive ceramic material, so that cooling of the coil itself is unnecessary. An arrangement equipped with such a coil 4 can also be used for other heating purposes.

Reference symbol list:

• 1 pouring spout
• 2 inner wall
• 3 flow channel
• 4 primary coil
• 5 shielding
• 6 outer wall surface
• 7 room
• L length section

Claims (12)

1. Refractory connection between a vessel containing a molten metal and an extraction device for the molten metal, in particular a refractory spout for molten steel,
characterized,
that the spout inner wall (1) consists entirely or partially of ceramic material that is electrically conductive at at least the liquidus temperature of the molten metal and that can be inductively heated by means of a primary coil (4) or has such a material. 2. Refractory connection according to claim 1,
characterized,
that a length section (L) of the spout inner wall (1) consists of or has the electrically conductive ceramic material and this length section (L) is inducible. 3. Refractory connection according to claim 1 or 2,
characterized,
that the electrically conductive ceramic material is ZrO₂ or has. 4. Refractory connection according to claim 3,
characterized,
that the ZrO₂ is stabilized by means of CaO or MgO or in particular Y₂O₃. 5. Refractory connection according to one of claims 1 to 4,
characterized,
that the primary coil (4) consists of electrically conductive ceramic material. 6. Refractory connection according to one of claims 1 to 5,
characterized,
that the primary coil (4) is part of the pouring spout (1). 7. Refractory connection according to one of claims 1 to 6,
characterized,
that the power output of the primary coil (4) can be regulated by means of a frequency-dependent current source. 8. Refractory connection according to one of claims 1 to 7,
characterized,
that the frequency of the current source is in the order of 3 to 10 MHz. 9. induction coil for heating electrically conductive material, in particular electrically conductive ceramic material or components consisting thereof,
characterized,
that its primary coil (4) consists of electrically conductive ceramic material. 10. Use of an induction coil according to claim 9, for inductive heating of components made of electrically conductive material, in particular tubular components, preferably of connections between a vessel containing molten metal and a withdrawal device for the molten metal, such as refractory spouts according to one of claims 1 to 8. 11. Use according to claim 9, for inductive heating of components made of electrically conductive, in particular tubular, material and / or an electrically conductive fluid contained therein, in particular molten metal. 12. Use according to claim 11, for moving, in particular transporting the fluid and / or mixing the fluid.

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