WO2003013766A2 - Ceramic moulded body - Google Patents

Abstract

The invention relates to a ceramic moulded body, the surface of which is at least partly covered by a steel cladding, whereby the steel cladding is at least partly coated with a fire-resistant material on the surface thereof not covering the moulded body.

Description

 Ceramic molded body

Description

The invention relates to a ceramic molded body, in particular a molded body made of a refractory ceramic material. Because of their refractory properties, ceramic molded articles made from a refractory ceramic material can be used for applications in which they are exposed to high temperatures, for example above 500 ° C. and also far above.

For example, ceramic moldings are used in metal casting, for example as a spout in slide closure systems, for example in continuous metal casting. Although the invention is not limited to the use of ceramic shaped bodies as a spout in slide closure systems, it is described below by way of example for such an application. In metal casting, spouts in the slide closure system are used to introduce melt, for example steel melt, from the ladle into the intermediate container (tundish) or from the tundish into the mold. For guiding (constricting) the metal jet m these slide closure systems, the spouts can be made up in the form of tophats (plate with integrated spout) or as an exchangeable spout. With the interchangeable spout, the spout can be removed as a separate part from the slide closure system and can therefore be replaced.

Ceramic moldings in the form of spouts are usually surrounded on their outer circumferential surface with a sheet metal jacket made of steel. This can improve the mechanical properties as well as the chemical resistance of the spout. At the high temperatures associated with the casting process, oxides (scale) form in the oxidizing air atmosphere on the surface of the sheet metal jacket. This so-called scaling is based on the reaction of the metal sheet jacket with the oxygen in the air. In the case of ferrous materials, the oxidation begins above approximately 400 ° C and becomes particularly strong at temperatures above approximately 600 ° C. The thickness of the scale layer increases with time and temperature. If the scale layer flakes off, is removed by mechanical attack or, as is usually the case with thermal cycling, becomes cracked, the scaling of the sheet metal shell increases considerably. Finally, the sheet metal jacket can scale to such an extent that it can no longer perform its task of improving the mechanical and chemical properties of the spout.

The rate of scaling could be reduced by adding special alloy elements in the steel sheet jacket, which lead to the formation of firmly adhering, dense layers of scale. However, such scale layers have only a low mechanical strength, they can be easily removed from the sheet metal jacket, as a result of which the layers of the sheet metal jacket underneath are now exposed to scaling without protection.

In practice, scaling has so far mostly been countered by using protective gases, in particular argon, at high temperatures. Such argon fumigation of the sheet metal jacket is complex, expensive and therefore extremely uneconomical.

Also, the argon gassing cannot always completely prevent the scaling of the sheet metal jacket.

The consequence is that even with argon fumigation, the sheet metal jacket becomes scaled.

If the scaling of the sheet metal jacket has progressed too far and he can no longer effectively protect the ceramic molded body underneath, he had to Spout and sheet metal jacket can be replaced, although the ceramic molded part would allow longer service life.

The invention has for its object to provide a ceramic molded body, the surface of which is at least partially covered by a steel cladding, which can be used economically and in which the steel cladding is subject to reduced scaling even at high temperatures.

The invention achieves the object by a ceramic molded body, the surface of which is covered at least in sections by a steel cladding, the steel cladding being covered at least in sections with a scale-inhibiting material on its surface which does not cover the molded body.

The reduction or avoidance of scaling leads to the mechanical function of the metal cover being retained for a longer period. This also results in longer service lives / durability for the ceramic molded bodies.

SiO oder sonstige Legierungen oder Verbindungen daraus, einzeln oder m Kombination verwendet werden .It has been found that the oxidation (scaling) of the steel cladding of a ceramic molded body can be effectively inhibited at the points where it is exposed to high temperatures in an oxidizing atmosphere (for example air) if the steel cladding at these points with a scale-inhibiting Fabric is covered. In this context, “scale-inhibiting” substances are understood to mean substances which, owing to their composition, have an increased resistance to scaling compared to the steel cladding. For example, metallic aluminum, chromium or silicon or its oxides (Al0 ₃ ,

SiO or other alloys or compounds thereof, individually or in combination.

The steel cladding can also be coated, for example, with a scale-inhibiting substance by first applying metallic chrome or aluminum to the steel cladding and then allowing it to be passivated.

The scale-inhibiting material can, for example, be placed in a solid form and, in the case of a metallic material, for example as a sheet or plate on the steel cladding. If sheets are used, these and the steel cladding can be welded or glued to one another for their connection, for example. It can also be provided that the sheet made of a scale-inhibiting material is shrunk onto the steel cladding. In particular, provision can be made to cover the steel cladding with the scale-inhibiting material in such a way that the steel cladding at its sections occupied by the scale-inhibiting material cannot come into contact with the surrounding gas atmosphere. The coating / coating should therefore be gas-tight.

When using a scale-inhibiting material in the form of a sheet, the mutually facing surfaces of scale-inhibiting sheet and steel cladding can correspond to one another so that the scale-cladding sheet completely covers the steel cladding. It may also be sufficient for the scale-inhibiting sheet to be gas-tightly connected to the steel cladding, for example welded. According to an alternative embodiment, it can be provided that the scale-inhibiting substance is first applied in liquid form to the steel cladding, for example brushed on or sprayed on (for example by flame spraying or plasma spraying) or the steel cladding is soaked with the liquid, and then the liquid on the steel cladding is converted into a solid form that adheres to the steel cladding.

It can also be provided that the scale-inhibiting substance is first applied in powder form to the steel cladding and then firmly bonded to the steel cladding there.

It is usually sufficient to apply the scale-inhibiting material to the steel cladding in a thickness of up to 1 mm, for example in a thickness between 0.1 and 0.7 mm or 0.2 and 0.5 mm.

As already mentioned at the outset, the ceramic molded body can in particular be a ceramic spout for the metal continuous casting, such as an interchangeable spout, and is to be described below by way of example with such a spout.

The surface of the steel cladding facing the ceramic spout can rest directly on the surface of the ceramic spout and the steel cladding can be applied, for example, by shrink-fitting a previously heated sheet. According to one embodiment, it is provided that the steel cladding surrounds the spout on its outer circumferential surface. Such an embodiment is known from the prior art. Since the outer peripheral surface (surface) of the spout is usually rotationally symmetrical, the steel cladding can be placed in the form of a sleeve around the spout.

The mutually facing surfaces of the steel cladding and ceramic spout can be designed to correspond to one another in such a way that they come to lie on one another over the entire surface. In this case, the sections of the surface of the spout which are covered by the steel cladding are directly occupied by the surface of the steel cladding facing the spout. The mechanical strength of the ceramic spout can be increased by prestressing the steel cladding on the spout, for example by shrinking it. Alternatively, it can be provided that the steel cladding is only in contact with the ceramic spout at its edge. The contact area between the steel cladding and the ceramic spout can be made gas-tight.

Further features of the invention emerge from the subclaims and the other application documents.

An exemplary embodiment of a ceramic molded body according to the application will be explained in more detail with reference to the following, highly schematic figure.

It shows

Figure 1 shows a ceramic molded body in the form of a spout for continuous metal casting in a sectional side view. The spout 1 consists of a ceramic molded body 3, which is partially covered by a steel cladding 5. The steel cladding 5 is partially covered with a scale-inhibiting material 7.

The ceramic molded body 3 runs in a rotationally symmetrical manner about its longitudinal axis L. Likewise, in a rotationally symmetrical manner about its longitudinal axis L, it has an inner channel 2 in its interior for the flow of molten metal. An upper, cylindrical section A of the ceramic molded body 3 is adjoined at the bottom by a conically tapering section B, then another cylindrical section C and finally a conically tapering section D. The ceramic molded body 3 consists of a conventional, refractory ceramic material. An upper end face 9 of the ceramic molded body 3 has a recess 11.

On its outer circumferential surface 13, the ceramic molded body 3 is partially covered by the tubular steel cladding 5, which consists of a steel sheet. The steel cladding 5 lies flat on the outer circumferential surface 13. It begins at the upper edge 13o of the outer circumferential surface 13 and ends at a distance from the lower edge 13u of the outer circumferential surface 13 in the region of the section D. The region of the circumferential surface 13 which extends in the region of the section D from the lower end of the steel cladding 5 to the lower edge 13u extends identified by reference numeral 13f; it is the only section of the outer circumferential surface 13 that is not covered by the steel cladding 5.

The upper end face 9 and a lower end face 15 of the ceramic molded body 3 are also not covered by the steel cladding 5.

The section of the steel cladding 5 that covers section D of the ceramic molded body is covered with a scale-inhibiting aluminum layer 7. This aluminum layer 7 is placed in the form of a sleeve on the steel cladding 5 (shrunk) and firmly connected to it. This area represents the contact area to a shadow pipe or immersion nozzle and is exposed to the strongest oxidation. Accordingly, in the exemplary embodiment explained above, only this section of the steel cladding 5 is covered with a scale-inhibiting material.

Claims

Ceramic molded body patent claims 1. Ceramic molded body (1), the surface (9, 13, 15) of which is covered at least in sections by a steel cladding (5), the steel cladding (5) is covered at least in sections with a scale-inhibiting material (7) on its surface not covering the molded body (1). 2. Ceramic molded body (1) according to claim 1 as a spout for the metal casting. 3. Ceramic molded body (1) according to claim 2 as an interchangeable nozzle. 4. Ceramic molded body (1) according to claim 1 for a slide closure system. , Ceramic molded body (1) according to claim 1, wherein the steel cladding (5) rests directly on the surface (13) of the ceramic molded body (1). 6. Ceramic molded body (1) according to claim 1, wherein the steel cladding (5) is a steel sheet. 7. Ceramic molded body (1) according to claim 1, wherein the steel cladding (5) the ceramic molded body (1) on its outer peripheral surface (13). 8. Ceramic molded body (1) according to claim 6, wherein the steel cladding (5) encompasses the ceramic molded body (1) under prestress. 9. Ceramic molded body (1) according to claim 1, wherein the scale-inhibiting substance is a metal or a metal compound. 10. Ceramic molded body (1) according to claim 1 with a scale-inhibiting material in the form of a sheet (7) or a layer applied to the steel cladding (5). 11. Ceramic molded body (1) according to claim 1, wherein the scale-inhibiting material consists of aluminum or an aluminum compound. 12. Ceramic molded body (1) according to claim 1, wherein the scale-inhibiting material (7) on the steel cladding (5) is sprayed on. 3. Ceramic molded body (1) according to claim 1, wherein the scale-inhibiting material (7) forms a gas-tight seal with respect to the hidden surfaces of the steel cladding (5).