EP0215789B1 - Ceramic casting - Google Patents

Abstract

PCT No. PCT/DE85/00187 Sec. 371 Date Mar. 27, 1986 Sec. 102(e) Date Mar. 27, 1986 PCT Filed May 31, 1985 PCT Pub. No. WO85/05584 PCT Pub. Date Dec. 19, 1985.During ceramic casting for the production of a molten bath it is often observed that the fire-resistant material becomes eroded and/or solid oxide phases are deposited. Both phenomena interfere with the smooth outflow of the molten bath. The present invention is intended, therefore, to provide an outflow which is stable in shape even when a molten bath is passed through, especially in multiple-sequence casting. To this end, the invention provides for ceramic casting with an envelope (10, 14) which is at least partly external and an internal insert (11, 14, 53) at a distance from the envelope (10, 14), the insert ( b 11, 14, 53) and envelope being connected together.

Description

The invention relates to a ceramic spout for performing a molten metal according to the preamble of claim 1.

Such a spout is known from GB-A 1 260 555. In order to eliminate the disadvantages of multi-part spouts, which consist of a casing and an insert, the two parts being mortared or pegged together, the known solution proposes a one-piece construction in which the casing and the insert after the fire have at least one Sub-area are materially connected to each other.

With such a pouring agent, deposits form on the inner surface of the pouring material after a certain pouring time. They lead to a reduction in the cross section of the immersion nozzle that is effective in terms of casting technology, as a result of which the amount of steel flowing through in one unit of time becomes increasingly smaller.

The same observations are also made on two-component immersion tubes of the type described in DE-A 21 65 537, in which the insert and casing are cemented together.

From DE-A 27 31 367 it is known to add Ca or CaSi alloys to the liquid steel in order to prevent the deposits mentioned on the surface of the immersion pouring material. However, the process described there is cumbersome and the goal of completely avoiding the formation of deposits is not always achieved.

The invention has for its object to propose a ceramic spout or a pouring device for performing a metal melt, in which erosions of the refractory material and / or formation of solid, oxidic phases is prevented. The spout or the complete spout device should both be sufficiently wear-resistant to be used in multiple-sequence casting, but they should also be easy to manufacture and use.

To this end, the invention proposes a ceramic spout for carrying out a metal melt with the features a) to g) of claim 1.

The insert preferably consists of a material whose free Gibb enthalpy has a high negative value in the chemical formation reaction.

By arranging the casing and insert at a distance from one another, that is, by forming a space between the two parts, the different thermal parameters of the refractory materials used, in particular the different thermal expansions of the refractory materials of the casing or insert, are taken into account.

If, for example, the insert is selected from a refractory material with higher thermal expansion, the inventive design of the spout can cause mechanical stresses in use or at contact points or at contact surfaces between.

Wrapping and insert are avoided by allowing the insert material to expand freely, filling the space between the cover and insert more and more.

So that the insert sits optimally in the casing during assembly and during the casting process, the invention provides that the space between the inner wall of the casing and the outer wall of the insert is at least partially filled with a material. This material should meet the condition that it is flammable at temperatures below that which can be achieved in this area. According to the invention, the term combustible is understood to mean any type of change in state involving a reduction in volume, so that, for example, gasifiable, coking, evaporable or volatile materials can be used. This ensures that the refractory materials can expand without hindrance after the start of casting, since the filler material burns out in a timed manner. The filling material can no longer provide mechanical resistance, so that strength-reducing tensions can be avoided.

For this reason, an advantageous further development of the invention provides that the material is a combustible material that is largely free of residues, preferably an ash-free combustible material. Ashless materials are understood to mean in particular those which have an ash content of less than 0.5 percent by weight, based on the original material weight. But it is also fire-resistant cotton that is easily compressible, e.g. B. from A1 ₂ 0 ₃ - or SiO _Z -rich materials.

In this case, practically the entire volume of space between the casing and insert is available for the expansion of the refractory materials after the burnout, and the essentially ash-free combustion additionally prevents punctiform or planar zones from being formed in the space mentioned, which under certain circumstances can cause expansion counteract the refractory materials. It is particularly advantageous if the distance between the outer wall of the insert and the inner wall of the casing, as well as their wall thickness, is constant over the entire pouring area. Then the advantageous effects of the ash-free burning filler material described above can be used in particular. A uniform distance between the insert and the casing is then ensured both when installing the spout and during the casting operation. This ensures both the homogeneity of the thermal conditions in the pouring area and thus the casting conditions are improved, but also possible thermal stresses, which can damage the insert or the casing, are eliminated.

According to the invention, the distance between the surfaces of the casing or the insert delimiting the space on two sides is greater than or equal to the maximum thermal expansion of the corresponding materials. In the first case, there remains a gap between the casing and insert even at maximum temperature stress, while in the latter variant the outer wall of the insert in extreme cases rests against the inner wall of the casing. It is then not only advantageous if an ash-free combustible filling material is used, but also the corresponding surfaces of the insert and the casing are as smooth as possible in order to avoid stresses caused by an uneven surface support.

The insert is preferably stabilized in its position by the filler material in the casing.

According to the invention, the generic term “ceramic spout” is understood to mean any spout which is used to carry out a metal melt. An example of this is a dip spout for continuous casting plants. Both the so-called shadow pipe between the ladle and the tundish and also the pure immersion pipe, and finally the inlet part adjoining the tundish, can be designed in the manner according to the invention. Furthermore, the inlet part and immersion tube can be designed as a one-piece component which is at least partially surrounded by the covering. In this respect, the term "ceramic spout" refers to individual parts and any combination of parts of such spouts.

The invention provides various embodiments for the arrangement of the insert in the casing.

In various areas of application, it may be sufficient to use the static friction between the filling material and the covering or insert in order to keep the insert aligned in the covering.

However, special measures are preferably taken in order to keep the use in the wrapper safely. For example, the insert can be connected to the casing via one or more support elements and / or holding elements. These can be arranged as a flange at the end of the insert or the casing and can engage in corresponding receptacles of the corresponding part of the spout or rest there.

An advantageous embodiment of the invention provides that the insert is provided with an end-side outer flange, by means of which it is suspended in the casing. Such an embodiment will be particularly suitable for tubular spouts (immersion spouts).

Wrapping and / or insert can also be conically tapered downwards, so that there is automatically a guide for use in the wrapper.

An alternative embodiment provides that the casing is divided in the longitudinal direction, and surrounds the insert provided with an outer flange on both free end faces.

The erosion-resistant refractory material of the insert will be. selected from the refractory products, the free Gibbs enthalpy of which has a high negative value in the chemical formation reaction, so that stable compounds are available. These include CaO, MgO, BeO and Zr0 ₂ ; however, soaked refractory products which prevent oxidation or synthetic resin-bonded materials can also be used, preferably those which give a stable carbon compound when used.

Simple and cheap refractory qualities are suitable as the material for the covering, for example chamotte, alumina graphite, amorphous silica, mullite, mullite graphite or zirconium silicate. However, if the covering is formed in one piece with other parts of the spout that come into direct contact with the molten metal, the covering is also preferably made from the materials that are specified above for use.

Various types of paper and cardboard can be used as filler materials, as well as largely residue-free combustible plastics. Pore-rich and foamed materials are preferred, which on the one hand ensure an exact fit of the insert in the casing, but on the other hand also have lower ash contents due to their lower solids content, for example foamed plastics, epoxy resins etc.

In addition, however, formaldehyde resins or various waxes can also be used, for example.

In the context of the invention, as will be described with reference to the drawing, it can be advantageous to use different materials next to or on top of one another.

In an advantageous embodiment of the invention it is provided that the filling material is produced as a finished part, for example in the form of rings or sleeves, and is pushed, inserted, glued or stapled onto the insert before the insert and the casing are put together.

It has been found to be particularly advantageous in the case of a spout on an intermediate vessel (tundish) to design the inlet part, designated in the following figures with the reference number 14, in the manner according to the invention, in particular also to design the inlet part with insert and casing. It is also possible to then design the use of the inlet part and the use of the dip tube in one piece. It is particularly advantageous if the joint use of this mono-diving nozzle consists of magnesite. In this form, the Another advantage is that there are no more irritating seams or connections in the flow area of the molten metal.

In order to further reduce the described problems of preventing erosion and / or formation of solid, oxidic phases, the invention also proposes a spout-stopper combination, with a spout according to the invention of the type described above and an associated stopper, the Plug at least on the surface that comes into contact with the spout (the sealing area) is made of the same material as the spout in the corresponding corresponding inlet area, preferably therefore from the materials mentioned CaO, MgO, Zr0 ₂ or BeO. The stopper can either be provided with a corresponding coating on the surface, but the stopper can also be constructed in its entire head region from this material, while the upper part of the stopper consists of conventional refractory qualities, for example an alumina graphite. However, the entire stopper with stopper head can also consist entirely of the refractories mentioned. In the case of a split form with different materials, a connection by gluing, screwing or the like is possible. However, sintering by firing together is also possible. Finally, the invention also proposes to design the stopper, at least in the part that comes into contact with the spout, corresponding to the spout according to the invention. The plug then has a covering made of an erosion-resistant refractory material and an insert made of a temperature-resistant material which is spaced therein (inside). The advantages described for the spout then apply accordingly to the stopper.

It has surprisingly been found that the formation of deposits and / or erosion (which depends, inter alia, on the particular metal qualities that are carried out) can be reduced even further by combining a spout according to the invention with the special stopper.

• Figur 1 Einen erfindungsgemäßen keramischen Ausguß als Tauchausguß für Stranggießanlagen im Längsschnitt
• Figur 2 Ein weiteres Ausführungsbeispiel eines Tauchausgusses gemäß Figur 1
• Figur 3 Ein drittes Ausführungsbeispiel eines Tauchrohres gemäß Figur 1
• Figur 4 Ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Tauchrohres im Längsschnitt
• Figur 5a, b Zwei weitere Ausführungsformen eines erfindungsgemäßen Ausgusses im Längsschnitt
• Figur 6 Einen erfindungsgemäßen Ausguß mit einem Kugelkopf-Einlaufteil
• Figur 7 Eine Ausguß-Stopfen-Kombination mit einem Tauchausguß und einem zugeordneten Stopfen in schematischer Darstellung im Längsschnitt

The invention is explained below with reference to the drawing. Show:

• 1 shows a ceramic spout according to the invention as a dip spout for continuous casting plants in longitudinal section
• FIG. 2 shows another embodiment of a diving spout according to FIG. 1
• FIG. 3 shows a third exemplary embodiment of an immersion tube according to FIG. 1
• Figure 4 Another embodiment of an immersion tube according to the invention in longitudinal section
• Figure 5a, b Two further embodiments of a spout according to the invention in longitudinal section
• Figure 6 A spout according to the invention with a ball head inlet part
• Figure 7 A spout-stopper combination with a dip spout and an associated stopper in a schematic representation in longitudinal section

The immersion spout according to FIG. 1 consists of an outer, cylindrical casing 10 and a likewise cylindrical insert 11 arranged therein.

With their upper free ends 12 and 13, the casing 10 and the insert 11 face the inlet part 14 of the tundish, while their lower free end areas 15 and 16 face the mold arranged below.

The upper free end of the casing 10 is designed in an outwardly angled step shape, wherein in addition to an end-side support surface 17, two further stepped steps 18, 19 are provided with two support surfaces 18a, 19a which run essentially perpendicular to the longitudinal extent of the casing 10.

With the exception of the stepped upper end region 12, the remaining part of the envelope 10 is formed over its entire length as a cylindrical body with a constant wall thickness.

For manufacturing reasons, it may be advantageous to design one or more outer surfaces to be slightly conical, in order to be able to pull the covering 10 off the tool more easily.

The insert 11 of the immersion spout is placed or suspended on the support surface 19a formed by the step 19 of the casing 10. For this purpose, the upper free end 13 of the insert 11 is provided with an outwardly directed annular flange 23. The width of the ring flange 23 is chosen so that the outer surface 21 of the insert 11 is everywhere at the same distance from the inner surface 20 of the sheath 10 after it has been suspended in the sheath 10.

For this purpose, a material 25 is filled in the area between step 10 and insert 11 in the area of stage 19, which material burns at temperatures below those achievable in this area. However, a light, compressible, fireproof cotton wool can also be used as material 25.

A corresponding material strip 25a is also placed on the end bearing surface 23a of the ring flange 23, as will be described in more detail below.

In order to further optimize the arrangement of the insert 11 in the casing 10, that is to say to ensure that there is a constant distance from the casing 10 over the entire length of the insert 11, preferably in the lower area of the space 26 facing the mold, between Cover 10 and insert 11, another, filling the space material strips 27 may be inserted.

In an advantageous embodiment of the invention it is provided that both the material strip 25a in the region of the flange 23 and the material strip 27 in the lower region of the space 26 are placed on the insert 11 as prefabricated parts before the insert 11 is inserted into the casing 10 what the zu assembly of the entire diving spout is simplified.

With the lower free end regions 15 and 16, the casing 10 and the insert 11 protrude into the mold, the steel bath height being represented by a wavy line.

A variant (not shown) provides for the outside of the lower part of the casing 10, which lies in the molten steel, to be reinforced with a refractory material such as zirconium oxide in order to prevent erosion, in particular in the contact area between the casing and casting powder.

Both the casing 10 and the insert 11 are made of refractory materials. While chamotte qualities, alumina-graphite mixtures or amorphous silicic acid can be used in addition to zirconium silicate or mullite for the casing 10, the erosion and corrosion-resistant refractory feedstock is preferably selected from the group of substances whose free Gibbs enthalpy in the chemical formation reaction has the highest possible negative value. These substances have proven to be particularly favorable in terms of erosion resistance and the avoidance of build-up since the connections are very stable. In addition to MgO, Zr0 ₂ and BeO or CaO, for example, are suitable materials. These materials have a high surface tension in the solid state, which should also be responsible for the good behavior in the casting operation.

In experiments, the thermal expansion of the materials used can be readily determined in order to subsequently calculate the necessary gap width of the room 26. This is to ensure that there is no pressing of the outer wall 21 of the insert 11 and the inner wall 20 of the sheath 10, even with maximum thermal expansion of the insert or wrapping material, so that tension problems in this area can be reliably avoided.

The gap width of the space 26 is preferably selected so that even after maximum thermal expansion in this area there remains a remaining distance between the insert 11 and the casing 10.

For the filling material 25, 27, ash-free burning substances are preferably used, for example paper and cardboard qualities, polyvinyl chlorides, formaldehyde resins or waxes which can be burned to a large extent without residue.

The immersion nozzle is attached to the tundish nozzle forming the inlet part 14 by placing it on holding pins 33 below the stepped end 12 and additionally connecting it to the inlet part 14 via a refractory cement 30. For this purpose, the lower free end of the inlet part 14 is designed in a step-like manner corresponding to the design of the immersion spout. The refractory cement 30 is filled between the corresponding contact surfaces 29, 28 of the immersion nozzle or the inlet part 14, with the exception of the area above the ring flange 23 of the insert 11, in which, as described, the combustible material is inserted. The material layers 25, 25a between insert 11 and casing 10 ensure their free mobility with respect to one another. Plastic putty, which has good adhesive properties, is preferably used. The putty 30 also enables an airtight connection between the dip tube and the inlet part.

The putty has the property of curing during the preheating of the entire device. The particular advantageous effects of a spout produced according to the invention then appear.

During and after the hardening of the putty 30, the insert 11 could no longer expand freely if the space 26 according to the invention between the insert 11 and the casing 10 or the special attachment to the inlet part 14 had not been provided.

After the putty 30 has hardened, the insert 11 can now expand in the direction of the casing 10 or in the direction of the mold, the space 26 being continuously reduced. At the same time, the filling material 25, 25a, 27 burns out due to the temperatures prevailing during the preheating and thus enables the unimpeded expansion of the insert or wrapping material. In the connection area to the inlet part 14, the material layer 25a likewise ensures unimpeded expansion of the ring flange 23 in the direction of the inlet part 14 and perpendicularly thereto.

Depending on the preselected gap width of the space 26, it is at least particularly advantageous if the filling material 25, 27 burns out largely without residues, so that there is no point or area-like bridge formation in the space 26.

In order to keep both the gap width of the space 26 constant over the entire area of use of the immersion spout and to keep the contact surface for the molten metal flowing through on the inner wall 31 of the insert 11 as small as possible, the walls 21, 31 of the insert 11 and the inner wall 20 the envelope 10 designed with a particularly high surface quality. This can be achieved through various manufacturing processes.

For example, the components can be manufactured using the «wet matrix process. A rubber mold is filled with the respective powder, sealed and then placed under pressure in a container filled with a certain liquid (for example oil or oil-water mixture). Since the rubber mold is surrounded on all sides by the press liquid, the compression takes place evenly; the pressure applied is the same in all directions.

The powder is pressed onto centrically attached metal mandrels that determine the internal passage of the pipes. The powders are subject to a compression shrinkage during compression, which varies depending on the material and grain structure can be, but is predictable.

Elements manufactured using such a method meet the criteria set. Point-like or sheet-like contact points between insert 11 and casing 10 can be excluded. The surfaces 20, 21, 31 should preferably be as smooth as that of the metal surfaces after a roughing treatment. There are no limits to the fineness of the surface quality.

The components can also be produced by pressing a flexible inner mold onto a rigid outer mold, the pressure being applied from the inside to the outside.

Another embodiment variant provides that the through openings of the components 10, 11 for the molten metal are formed by drilling out of blocks.

Experiments have shown that the arrangement according to the invention has a further advantage. By designing a distance (space 26) between insert 11 and casing 10 and / or by using a heat-insulating material as filler material in this space 26, the heat transfer when passing the hot molten metal to the environment is significantly reduced, thereby reducing the working conditions for the Operators can be improved. Due to the insulating effect, the reactivity of the refractory material with the casting powder, which is placed on the steel bath of the mold, is less.

When using an immersion nozzle according to the invention shown in FIG. 1, not only can the undesired formation of deposits be avoided, but such an immersion nozzle also enables casting with a high number of pan sequences.

In the same way as described above with reference to the immersion spout, the tundish spout (inlet part 14) can also be constructed from an inner insert and an outer covering. With regard to the materials used and the advantages resulting from such an arrangement, the same applies as was described above with regard to the components 10, 11.

The embodiment shown in FIG. 2 is again the representation of a multi-part immersion nozzle made of different materials. However, the envelope 10 is provided at its lower end 15 with an inner flange 35 on which the insert 11 is seated. Similarly, as also described with reference to the exemplary embodiment according to FIG. 1, the area between the flange 35 and the lower free end of the insert 11 is underlaid with a filling material 27, so that even after the device has been heated, the refractory material can expand freely in all directions , because the filling material burns out in a timed manner.

The upper free ends 12, 13 of the casing 10 or of the insert 11 are again glued to the inlet part 14 via a refractory cement 30.

So that the plastic putty 30 does not penetrate into the space 26, the space 26 is again filled with the filler material 25 at its upper free end. This can be pushed over the insert 11 as a prefabricated ring, which considerably simplifies handling and assembly.

The exemplary embodiment according to FIG. 3 differs from the ones described above in particular in that the casing 10 is divided lengthways. This is necessary here because the insert 11 is provided with outer flanges 39 formed in one piece on both sides, so that the casing 10 can no longer be pushed onto the insert 11, but must be placed laterally.

The filling material 27 is again introduced between the flange edges of the flanges 39 and the casing 10.

The inlet part 14 is again glued to the outer surface 39a of the ring flange 39 via a refractory cement 30. It can, moreover, be designed in the same way as the immersion spout with a circumferential covering.

In FIG. 4, the casing 10 and the insert 11 are connected to one another via an interposed plate 40.

While the basic structure of the casing corresponds to that according to the exemplary embodiment in FIG. 1, the insert 11 differs from that according to FIG. 1 insofar as it is designed in the form of a simple tube without an end flange.

At its upper free end 13, the end face of the insert 11 is glued to the lower surface of the plate 40. The plate 40 lies on the rest on the contact surface formed by the step 41 of the envelope 10 and is also glued to it. The dimensions of the annular plate 40 are chosen so that it sits well on the step 41 and the inner surface of its central bore 43 is flush with the inner surface 31 of the insert 11.

The plate 40 is made of graphite, for example. The remaining contact surfaces between plate 40 and casing 10 can be sealed with a refractory putty. The inlet part adjoins in the manner shown in Figure 1 upwards.

FIGS. 5a, 5b each show a spout in which the casing of an immersion tube is formed integrally with the inlet part 14, specifically in terms of construction (FIG. 5a) or in terms of material (FIG. 5b).

In the example according to FIG. 5a, the insert 11, similar to that in FIG. 1, is held in the casing 10 via an upper, end-side ring flange 23.

The lower part 10 largely corresponds to the casing according to FIGS. 1 to 4, a tongue and groove connection 50 in the height of the support 23a of the ring flange 23 making it possible to connect the casing 10 to the inlet part 14.

In contrast to the exemplary embodiments according to FIGS. 1-4, however, the components 10, 14 here are made from one and the same material, for example magnesium oxide or a similar erosion-resistant refractory material.

The casing 10 of the spout has a step 51 on the inside at its upper end 12, on which, as shown in FIG. 1, the insert 11 rests over the ring flange 23. The other structure largely corresponds to that described with reference to FIGS. 1-4. The mode of operation and effect of the individual components also correspond to that described for the preceding figures.

As an alternative to embodiment 5a, in the case of a spout with an insert 11 with an end flange 23, an embodiment is available, as shown in FIG. 5b. Here, the inlet part 14 is designed in one piece with the covering 10 _IL m the insert 11. In order to be able to connect the insert 11 to the inlet part 14, the area of the passage opening 44 is indeed funnel-shaped, but the inner surface is not or only partially convex. After a slightly convex part extending from the upper edge 44a, the passage opening 44 continues with a cylindrical section 44b in the direction of the lower free end 16 of the insert 11, namely in the region of a step 52 which extends inwards vented. Another cylindrical recess 47 extends downward from the front end of the step. The diameter of the cylindrical recess 47 is smaller than that of the cylindrical section 44b of the passage opening 44. In the manner described for FIGS. 1 and 5a, the insert 11 is again hooked into the inlet part or the casing with an annular flange 23, during assembly can be inserted from above through the passage opening 44. The insert 11 is designed such that the outer diameter of the ring flange 23 is selected to be somewhat smaller than the diameter of the lower part 44b of the passage opening 44.

A strip 25a of the combustible material is again inserted in the area of step 52. Such a strip 27 is also at a distance from the ring flange 23 around the insert 11 and fills the space 26 between the insert 11 and the casing 10.

An insert 53 extends from the upper end face 23a of the ring flange 23. The insert 53 has a shape which, after installation, gives the upper part of the inlet part 14 a shape as in FIG. 5a. For this purpose, the insert 53 has a cylindrical shape, with a somewhat smaller diameter than the passage opening 44b, while the inner part is also convex in extension of the convex curvature of the passage opening 44 and is aligned at its lower end with the inner wall 31 of the insert 11 .

The insert 53 can be glued into the inlet part 14 with the putty 30. The insert 53 is preferably made of the same material as the insert 11, from which the inlet part 14 and the casing 10 connected to it can also be made.

The spout shown in Figure 6 shows a spherical head part with a dip tube connected at the end and therefore has its name. The structure of the spout largely corresponds to that in Figure 5b d. H. the insert 11 lies on a step 52 of the casing.

The ring flange 23 of the insert 11 is, however, formed in accordance with the upper part 24 of the spout in the region of the passage opening 44 with a concave curvature, so that the corresponding surfaces of the spherical head inlet 45 and the ring flange 23 or part 24 run parallel to one another.

7 shows a spout according to the invention, specifically as a so-called “mono-immersion spout _” , in which the insert 11 is formed in one piece with the inlet part 14. To avoid repetition, reference is made to the description of FIG. 5a. The exemplary embodiment according to FIG differs from this in that the insert 11 is designed without an annular flange 23 and integrally merges into the inlet part 14 (which runs in the tundish bottom). The casing 10 is arranged analogously around the insert part 11 and also via a tongue and groove connection 50 the inlet part 14 connected via a refractory putty 30.

In this form, the inlet part 14 represents a part of the insert 11. The sheath 10 can of course also be carried out within the scope of the invention up to the area of the inlet part 14 and encompass it. The best embodiment usually depends on the local conditions.

In the embodiment according to FIG. 7, all seams or connecting pieces in the area through which the molten metal passes are eliminated, which is particularly advantageous.

A plug 60 is assigned to the spout and is arranged in a known manner above the passage opening 44. The plug 60 on its surface 62 which comes into contact with the spout (or the inlet area 14) consists of the same material as the spout in the corresponding inlet area 14, preferably CaO, MgO, Zr0 ₂ or BeO.

It has been shown that it is precisely when the spout and stopper are made of the same erosion-resistant, refractory material that the undesirable build-up or erosion (depending on the steel quality) can be prevented.

Instead of a coating, provision can also be made to produce a more or less large area at the lower end of the stopper from the material mentioned. For example, the area from the lower vertex 63 to the line 64 shown in broken lines in FIG. 7 can be produced from magnesite. This part is then glued, screwed or the like to the upper part 65, which consists for example of alumina graphite. Depending on, The materials from which the parts 60, 65 are made can also be fired together.

Further embodiments of a spout according to the invention are possible within the scope of the claims. For example, the insert part 53 of the spout according to FIG. 5b can not only be designed as a prefabricated component, but rather this area can also be filled, for example, by a known injection molding compound, preferably from the same material as the inlet part 14.

Claims (14)

1. Ceramic spout for the casting of metal melt with

a) at least a partial casing (10), made of temperatur resistant material and

b) an inner inset (11), made of an erosion resistant, fireproof material,

c) inset (11) and casing (10) being arranged at a distance from one another, characterized in that

d) inset (11,53) and casing (10) are constructed as separate components and

e) are arranged at a distance from one another along their corresponding surfaces,

f) the distance being bigger than or identical to the maximum thermal expansion of the corresponding materials of the casing (10) and the inset (11, 53) in this area during use and

g) the space (26) between casing (10) and inset (11, 53) is at least partially filled with one or more materials (25, 27), which is / are combustible and / or very compressible with loss of volume, at temperatures below those which can be achieved in the space (26).

2. Spout under claim 1, characterized by the fact that the material (25, 27) is a material which burns considerably free of residue, preferably ash-free.

3. Spout under claim 1 or 2, characterized by the fact that the inset (11, 53) is made of a material, the free Gibbs enthalpy of which reaches a high negative value during the chemical reaction.

4. Spout under one of the claims 1 through 3, characterized by the fact that the space (26) is at least partially filled with a thermal insulating material (25, 27).

5. Spout under one of the claims 1 through 4, characterized by the fact that the inset (11) is connected to the casing (10) by way of one or several support and / or suspending elements (23).

6. Spout under one of the claims 1 through 5, characterized by the fact that the inset (11) is suspended in the casing (10) with the help of a flange (23). -

7. Spout under one of the claims 1 through 6, wherein the inset (11, 53) and / or the casing (10) is (are) manufactured in the isostatic pressing process.

8. Spout under one of the claims 1 through 7, characterized by the fact that the casing (10) is made of a fire-proof, ceramic material, in particular : fire-clay, alumina, alumina-graphite, amorphous silica, mullite, mullit-graphite or zirconic silicate.

9. Spout under one of the claims 1 through 8, characterized by the fact that the inset (11, 53) is made of CaO, MgO, BeO or Zr0₂.

10. Spout under one of the claims 1 through 9, characterized by the fact that its structural components (10, 11, 53) are at least partially soaked in tar.

11. Spout under one of the claims 1 through 10, characterized by the fact that the inset (11, 53) and the casing (10) are made of the same fire- proof material.

12. Spout under one of the claims 1 through 11, characterized by the fact that the material (25, 27) is a paper or cardbord grades, a foamed synthetic material, an epoxy resin or a wax.

13. Spout under one of the claims 1 through 12, characterized by the fact that the material (25, 27) fills up the space (26) partially or completely in the form of rings, bars, distance plates or as a sleeve over inset (11).

14. Spout under one of the claims 1 through 13 with an influx element (14) and a plug (60) related thereto, characterized by that the spout is made of the same material, preferably MgO, Zr0₂, BeO or CaO as the corresponding surface of the plug allocated thereto.

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