SK15162002A3 - Refractory component and assembly with improved sealing for injection of an inert gas - Google Patents

Abstract

A refractory component (1, 4) provided with means of injecting or conveying (5, 16) gas and means of delivering said gas from an external wall of the component to said means of injection (5, 16), and an assembly including a refractory component as described above and a gas delivery line (9, 19), wherein one end of the gas delivery line is engaged in the part of enlarged cross-section which holds a seal (12, 22) in compression against the side walls of the part of enlarged cross-section.

Description

Technical field

The invention relates to a refractory component used in the treatment of metal in a liquid state, for example steel, and provided with a gas supply, the refractory component having an improved seal.

In particular, the invention relates to such a refractory component used in the continuous casting of a metal in a liquid state.

BACKGROUND OF THE INVENTION

It is known that liquid metal casting is generally carried out by means of a device comprising various refractory components forming a channel between two consecutive metallurgical vessels. These refractory components perform various functions, in particular the functions of guiding the liquid metal, protecting the liquid metal from cooling and exposure to chemicals from the surrounding atmosphere, and optionally also controlling the rate and amount of liquid metal casting. These refractory components may, for example, be an internal nozzle mounted in the hearth block integral with the bottom of the upper metallurgical vessel, a submersible inlet nozzle, a collection nozzle or fixed or movable slide plates.

The interconnecting surfaces between the various components forming the casting channel all create points of ingress of ambient air. As a result of the flow of liquid metal through the casting channel, a substantial negative pressure is created which assists inlet of air through these mating surfaces. The harmful effects of such air (nitrogen and oxygen) ingress on the quality of the cast metal are generally known, and great efforts have been made over a long period to overcome these deficiencies.

One known prior art solution involves injecting an inert gas, such as argon, into the coupling surfaces between two adjacent refractory components in the casting channel. This injection can be carried out, for example, by means of a groove formed for this purpose in the surface of at least one of the components. In order to be effective, the groove must as far as possible surround the pouring hole so that the inert gas which is under pressure can prevent any air from entering the pouring channel.

Recently, International Patent Application WO 98/17421 has proposed improvements to the system, which include the additional injection of the sealant in suspension in the carrier medium, which may be an inert gas, so that any seal failures that may occur between two adjacent surfaces during casting, are immediately removed.

Another known prior art solution involves injecting inert gas directly into the casting channel so as to provide a protective barrier against ambient air contamination around the entire length of the casting channel. In this case, the injection of inert gas into the liquid metal is generally effected by diffusion through the porous wall of the part forming part of the casting channel or, in another known variation, through one or more holes in the form of holes or slots arranged around the casting channel.

Furthermore, a method is also known in which the inert gas is injected directly into the casting channel such that the inert gas cooperates mechanically with the liquid metal. The purpose of this type of inert gas injection may be to prevent the erosion of certain refractory components located downstream of the injection site, which are particularly susceptible to the erosive action of the liquid metal jet, such as the edges of the sliding orifice of the movable slider plate for flow control and flow rate. flow rate.

Another known effect of injecting inert gas into the casting channel is that the problems of clogging or fouling of the casting channel are eliminated. Problems arising from the formation of alumina deposits on the walls of the casting channel have been known for a long time, especially in the case of casting of aluminum steels. The inert gas, which is thus blown downstream of the point where clogging or clogging may occur due to mechanical or thermal action, insulates the liquid metal from the casting channel, thereby preventing or reducing the possibility of such deposits being formed.

Finally, it is also possible to inject gas for cooling the respective refractory component. It should be noted that the invention also relates to components used to inject gas into the bottom of a metallurgical vessel containing a molten bath of metal, such as porous plugs.

For the purposes of this description, it should be noted that the expression "gas injection" refers both to the direct injection or injection of inert gas into the pouring channel or to the bottom of the metallurgical vessel, as well as to injection or injection of inert gas (or sealant in suspension in the carrier fluid, is described in International Patent Publication No. WO 98/17421) to the bonding surfaces between two adjacent refractory components of a casting channel by means of a groove surrounding at least partially the liquid metal pouring opening or injection or injection of cooling gas.

Refractory components designed and configured to inject inert gas generally include means for introducing gas to the means for injecting or injecting it (into a groove or channel). However, refractory assemblies are known in which the gas supply means and the gas injection or injection means are formed as adjacent interconnected components (or may even be separated by means of intermediate refractory components, the essential feature being that the gas can be transported from means for introducing it into means for injecting or injecting it).

For the purposes of this description, when referring to a component provided with gas supply means and means for injecting or injecting gas, it is equally intended to include a component including both gas supply means and means for transmitting and / or interfacing with the means for injection or injection of gas, which may be formed by another refractory component.

Typically, the gas supply means comprises an inlet opening on the outer wall of the refractory member which communicates with the gas supply line. This gas supply line is connected to the fixed gas supply line of the casting device, possibly by means of flexible hoses protected against thermal radiation.

It is common knowledge that during manufacture of such a refractory component a metal connection is mounted on the inlet opening. This connector and material then form an integral assembly after sintering the respective refractory material of the component. The connection may then be connected to the gas supply pipe by screwing (the connection is or provided with an external threaded portion projecting from the component, or the connection may be provided with an internal thread into which the end of the pipe is screwed by an external thread), by welding or means for mechanical connection.

These gas supply means are not entirely satisfactory, in particular because, firstly, it is not certain that the threaded joint can be made airtight, and in particular as a joint which remains airtight at the very high temperatures to which the device is exposed during and, secondly, due to the difference between the expansion coefficients of the metal from which the connector is made and the refractory material, it is essential that the tightness between the connector and the refractory material gradually deteriorates.

The negative effects of this leak tightness have the following three aspects:

First, there is an increase in the amount of gas that must be injected or injected,

Second, since, as mentioned above, the entire casting channel is under negative pressure due to the surrounding environment, there is a risk that air will be pumped through these damaged joints, and

Thirdly, in the case of leakage, the precise control of the amount of gas actually injected or injected into the system is lost, so that a perfectly repeatable system cannot be established.

Various efforts have been made to improve this situation, such as "sealing the refractory component in a metal sheath provided with an opening in the connection, welding to ensure mechanical attachment of the connection, and to improve gas tightness." However, such improvements have a number of disadvantages. Because, for example, the connections integral with the metal sheath tend to release from the refractory material and move in their seat, causing loss of inert gas and also, as mentioned above, air ingress into the liquid metal.

Recently, a very simple device, described in EP 703 028, has been proposed for supplying inert gas to an inner nozzle, the outer surface of the refractory component to which the gas is supplied is simply provided with a gas inlet opening, against which the connecting fitting connected to the inert gas supply pipe is kept in a compressed state. It may also be possible to arrange a seal between the fitting and the inlet opening.

Although this device greatly improves the situation, it has been found that it is not yet entirely satisfactory because the seal between the fitting and the gas inlet opening on the component surface is not perfectly secured, even if a gasket is arranged between the fitting and the opening. .

A refractory member provided with means for injecting or supplying gas and means for guiding the gas from the outer wall of the component to said means for injecting gas, the gas conducting means comprising a larger cross section extending from the outer wall of the component and a reduced section a cross-section communicating with the inner end of the enlarged cross-section and on the other hand with means for injecting, injecting or delivering gas, said component also comprising a seal secured against the inner end of the enlarged cross-section, the seal having an opening which is at least partially aligned with the connection opening between the enlarged section and the reduced section is known from FR 2 763 012.

Due to this particular arrangement of the refractory component, the gas supply pipe can be attached much deeper in said component, so that by using a suitable gasket, a tightness is ensured not only between the two portions of the gas supply means but also on the walls of the enlarged cross-section. A substantial improvement in tightness has been observed in comparison with the device according to EP 703 028 (reduction of inert gas consumption, reduction of air penetration, and precise control of the amount of gas supplied). However, it is still desirable to further improve the relevant tightness.

SUMMARY OF THE INVENTION

According to the present invention, the seal has a cross-section that is substantially similar to that of the enlarged portion. Thus, when the seal is positioned in a compressed state in a suitable manner, it rests not only on the end of the enlarged cross-section but also on the side walls of the enlarged cross-section, which results in an even better seal.

It is preferred that the thickness of the gasket does not exceed the depth of the enlarged cross-section portion, otherwise, due to compression through the gas supply line, the plastic gasket would rest against the edge of the outer opening of the gas supply means as it deforms; enlarged cross-section.

In accordance with a preferred embodiment of the present invention, the inner end of the enlarged cross-section portion forms a surface having an aperture, said enlarged and reduced cross-section portions being connected through the opening. In this way, it is possible to use a gas supply pipe having a substantially tubular shape.

Preferably, the enlarged aperture portion, which is substantially circular, can be very easily formed.

a cross-section formed by a cross-section that is

It has also been provided that the surface forming the inner end of the enlarged cross section is planar and substantially perpendicular to the axis of the opening. This arrangement is not only very easy to implement, but its sealing will also be improved if it is done by compressing the parallel elements.

In accordance with a preferred aspect of the present invention, the thickness of the gasket does not exceed the depth of the enlarged cross section. It should be noted here that the seal may be formed integrally with the part.

The gasket preferably has a cross-section that is substantially similar to that of the enlarged portion. Thus, when the seal is positioned in a compressed state in a suitable manner, it rests not only on the end of the enlarged cross-section but also on the side walls of the enlarged cross-section, whereby the seal formed is improved. It is essential that the thickness of the seal does not exceed the depth of the enlarged cross-sectional part, otherwise, due to compression through the gas inlet pipe, the plastic seal will abut on the edge of the outer opening of the gas inlet means as it deforms. section.

The seal is preferably in the form of a washer. However, it is also possible to use the entire assembly such that, depending on the desired thickness, the prior art can have very washers, namely seals. One skilled in the art can readily determine the optimum seal thickness

The seal is preferably made of a plastic material so that it can sufficiently deform at operating temperatures when it is under pressure to form a seal with the underside and side walls of the end of the enlarged cross-section. Clay and graphite are materials that are potentially suitable for such applications, with graphite being the recommended choice.

In accordance with another aspect, the invention also relates to an assembly comprising a refractory member as described above and a gas inlet conduit, wherein one end of the gas inlet conduit is retained in an enlarged cross-section portion that maintains tightness at the inner end against the side walls of the enlarged cross section. The advantages of such an assembly have already been described above.

According to a preferred particular embodiment of the invention, the refractory member is provided with a metal sheath (e.g. in the case of an internal nozzle) or a strip (e.g. in the case of a slider plate) covering at least partially the gas supply means. It is thus possible to provide a firm attachment between the supply line (by welding or screwing) and the jacket or strip, thereby preventing possible leakage, for example in the case of vibrations.

Preferably, the end of the conduit is attached in an enlarged cross-sectional portion arranged to form a tight seal by sealing. For example, the end may be shaped as a cone or truncated cone so that it is "wedged" to the joint. In an alternative embodiment, the pipe end may be threaded to allow the pipe to be screwed into the joint. Provision may also be made to form a self-tapping end such that a perfectly matched thread is formed on site in the gasket so that the pipe joint and the seal are completely sealed. According to this variant, it is advantageous that, when screwing the end of the pipe into the gasket, the gasket is compressed towards the side walls of the enlarged cross-section.

Finally, in accordance with the most preferred embodiment of the present invention, the enlarged cross-sectional part is sufficiently deep such that due to the thermal expansion of the pipe end retained in the enlarged cross-sectional part, an increased seal compression occurs. If the pipe is made firmly in one piece with a sheath or strip, there is only the possibility of expanding towards the end of the enlarged cross section where the gasket is located.

Thus, in accordance with the present invention, there is provided a refractory member having gas means and outer wall means for injecting a component comprising means for injecting or delivering said gas by means of an enlarged cross-section gas extending from the outer the wall of the component and the reduced cross-section portion communicating with the inner end of the enlarged cross-section portion and with the gas injection or supply means, said component also comprising a seal attached to the inner end of the enlarged cross-section portion; is at least partially aligned with the connecting aperture between the enlarged section and the reduced section, the seal does not exceed the depth of the section by the section, the seal having a cross section substantially similar to that of the enlarged section ezom.

with the thickness being enlarged

Preferably, the inner end of the enlarged cross-sectional area forms an area provided with an aperture, wherein the enlarged cross-sectional portions and the reduced cross-sectional portions are interconnected by the aperture.

The enlarged cross-section preferably consists of an opening having a substantially circular cross-section.

The surface constituting the inner end of the enlarged cross-section is preferably planar and substantially perpendicular to the axis of the opening.

The seal is preferably formed by one or more washers of plastic material.

In accordance with another aspect of the present invention, there is also provided an assembly comprising the above refractory member and a gas supply line, wherein one end of the gas supply line is provided with a seal that is pressed against the side walls of the enlarged cross-section.

Preferably, the refractory member is provided with a metal sheath or strip, wherein the gas supply conduit extends or adheres to the loose metal sheath or strip, wherein a rigid connection is made between the pipe and the sheath or strip.

The end of the gas supply pipe attached to the refractory member is preferably arranged to form a tight seal to the gasket.

The end of the supply pipe in the refractory component may be preferably provided with a thread which is fastened in the gas seal.

The end of the refractory or truncated gas supply pipe, attached to the components, may advantageously be shaped like a cone, a cone attached to the gasket.

The enlarged cross-section is sufficiently deep that, due to the expansion of a portion of the gas supply pipe retained in said enlarged cross-section, the seal is pressed against the inner end and against the side walls of the enlarged cross-section.

Overview of the drawings

The invention will now be explained in more detail by way of examples of specific embodiments thereof, the description of which will be given with reference to the accompanying drawings, in which:

Fig. 1 shows an axial sectional view of the inner nozzle,

Fig. 2 is an enlarged view of the location in circle I of Fig. 1; and

Fig. 3 shows an axial sectional view of the slider plate.

DETAILED DESCRIPTION OF THE INVENTION

1 shows an inner nozzle 1 consisting of a refractory body 2 forming a casting channel 3 and a plate 4. Inner nozzle

1 is also provided with means for injecting a gas, for example an inert gas, such as argon, into the casting channel 3. These means for injecting gas are formed, for example, by a porous sleeve 5 of porous material arranged in a recess 6 formed in the refractory body. is connected to the gas supply means.

As shown in FIG. 1, these gas supply means may be embedded in the upper surface of the plate 4. There is also shown a portion of the gas supply line 9 together with the metal housing 10 surrounding the plate 6 of the inner nozzle 1.

FIG. 2 shows the connection between the gas supply and the gas supply means on the inner nozzle plate 4 in more detail.

These gas supply means comprise an enlarged cross-sectional part T and a reduced cross-sectional part 8 which are interconnected by means of a connection opening 11. The inner end of the enlarged cross-sectional part 11 is provided with seals 12 such as a graphite seal.

There is also shown one end of the gas supply line 9, which is attached in the enlarged cross section. The gas supply pipe 9 is fixed to the metal housing 10 by means of a circular weld 13.

Referring now to FIG. 3, a refractory slide plate 14 is provided with a metal pouring hole 15. This refractory plate 14 is provided with a circular groove 16 that surrounds the casting aperture 15, forming together with a refractory component surface (not shown) adhering to the refractory plate

14, a channel for injecting gas between these adhering components.

The circular gas circulation plate 16 is connected to gas supply means comprising an enlarged cross-section 17 and a reduced cross-section 18, which are connected to each other by means of a connection opening 21.

Also shown is a gas supply conduit 19 mounted in an enlarged cross-section portion 17 that is attached to the metal strip 20 of the refractory plate 14 by spot welding 23.

As long as the refractory plate 14 is in operation, due to the effect of the temperature to which the entire assembly is heated, a portion of the gas supply line 19 between the spot weld 23 and its inner end expands towards the inner end of the enlarged cross-section 17, compressing the seal 22 .

Claims (7)

PATENT CLAIMS Refractory element (1, 14), provided with means (5, 16) for injecting or supplying gas and means for discharging said gas from the outer wall of the component to said means (5, 16) for injection, said means for discharging gas comprising a portion (7, 17) with an enlarged cross-section extending from the outer wall of the component and a reduced-section (8, 18) interconnected with the inner end of the enlarged cross-section (7) and with injection means (5, 16); a gas supply, said component also comprising a seal (12, 22) attached to the inner end of the enlarged cross-section (7, 17), the seal (12, 22) comprising an opening which is at least partially aligned with the connecting opening (11, 21) between enlarged and reduced cross-section parts, wherein the thickness of the gasket (12, 22) does not exceed the depth of the enlarged cross-section part (7, 17), characterized in that and in that the seal (12, 22) has a cross-section substantially similar to that of the enlarged cross-section (7). Refractory component according to claim 1, characterized in that the inner end of the enlarged cross-section (7, 17) forms a surface provided with an opening (11, 21), wherein the enlarged cross-section (7, 17) and the reduced cross-section parts (8, 18) are connected through this opening (11, 21). Refractory component according to claim 1 or 2, characterized in that the enlarged cross section (7, 17) consists of an opening having a substantially circular cross-section. A refractory component according to claim 3, characterized in that the surface forming the inner end of the enlarged cross-section (7, 17) is planar and substantially perpendicular to the axis of the opening. Refractory component according to claim 1, characterized in that the seal (12, 21) is formed by one or more washers of plastic material. An assembly comprising a refractory member (1, 14) according to any one of claims 1 to 5 and a gas supply line (9, 19), characterized in that one end of the gas supply line (9, 19) is provided with a seal ( 12, 22), which is pressed against the side walls of the enlarged cross section (7, 17). Assembly according to claim 6, characterized in that the refractory element (1, 14) is provided with a metal sheath (10) or a strip (20), wherein the gas supply pipe (9, 19) passes through said metal sheath (10) or a strip (20) or adheres thereto, wherein between pipe and connection. or Strap is made solid 8. Assembly by one of the claims 6 or 7, you out on the čuj ú c a by that end pipes (9, 19) on the gas supply, attached in a refractory component, is a organized 22). so that creates tight spoj s seal (12, 9. Assembly by Claim 8 v y wit u j ú c and sa because of the end pipeline (9, 19) na supply gas, 11th fastened in the refractory component, it is provided with a thread which is fastened in the gasket. An assembly according to claim 8, characterized in that the end of the gas supply pipe (9, 19) attached in the refractory component is shaped like a cone or truncated cone attached in the seal (12, 22). An assembly according to any one of claims 6 to 10, characterized in that the enlarged cross-section (7, 17) is sufficiently deep such that, as a result of the expansion of a portion of the gas supply pipe (9, 19) attached to said portion (7) 17) with an enlarged cross-section, the gasket (12, 22) is pressed against the inner end and against the side walls of the enlarged cross-section (7, 17).