EP0990474A1 - Inert gas shrouding device for moulds for the continuous casting of metals - Google Patents

Abstract

Continuous steel casting device, comprises a blanketing device having a ring shaped inflatable membrane made of a gas permeable material in order to protect the surface of the molten metal. Blanketing device of the gap (27) surrounding the free surface (17) of the liquid metal (2) which is continuously cast in an ingot mould (6) positioned under an adaptor (1) having a cast gate (5) of liquid metal (2) feeding the ingot mould, comprises a ring-shaped inflatable membrane (19) made of a gas permeable material. The thickness of the membrane (when inflated) is superior to the maximal distance between the top flange (26) of the ingot mould and the bottom (3) of the adaptor during casting. A tubular armature (20) is positioned inside the membrane and is provided with at least one intake manifold (21,22) for an inert gas. The device also comprises outlets (23,24) for releasing the gas into the membrane, fixing elements (25) for fixing the membrane on the bottom (3) of the adaptor or on the top flange (26) of the ingot mold, the membrane surrounding the casting gate, inflating means to inflate the membrane and to keep it inflated and in seal contact with the bottom of the adaptor and the top flange of the ingot mold.

Description

The invention relates to the continuous casting of metals such as steel. More specifically, it concerns the devices ensuring the protection of the liquid metal present in the mold against possible chemical reactions with ambient air.

Continuous steel casting installations include an ingot mold without bottom, the walls of which are energetically cooled internally by circulation of water, and are made of a metal that conducts heat well, such as copper or its alloys. The liquid steel is continuously introduced into the ingot mold, coming from a container called "distributor" which overhangs it, and it begins its solidification by forming a solid crust against the internal walls of the mold. The product (called a slab, bloom or billet according to its shape and dimensions) is continuously extracted from the mold and completes its solidification at heart outside the mold, thanks to an external cooling by spraying water.

Liquid steel entering the ingot mold must be protected from ambient air, in order to avoid an increase in its nitrogen content and the formation of oxidized inclusions within it. For this purpose, the jet of liquid metal flowing from the distributor is most often protected by a tube of refractory material whose lower end plunges into the bath metallic present in the mold. On the other hand, usually the free surface of the liquid steel present in the ingot mold is covered with an oxide-based powder, called "cover powder". Its functions are multiple. Besides the protection of steel against the ambient air, it stops the radiation from the surface, and thus reduces the metal heat losses. And by infiltrating between the solidified crust and the mold, it provides lubrication of the mold-product interface which allows the extraction of product is produced without risk of tearing of the solidified crust. This extraction is also facilitated by vertical oscillations, and also possibly vibrations ultrasonic printed in the mold.

There are however cases where the use of a covering powder is not possible, i.e. when the cast product is small and the use of a tube could cause the formation of "bridges" of solidified metal between the tube and ingot mold. It is then necessary to sink with a jet of metal exposed to the atmosphere ambient, the impact of which on a surface coated with covering powder would cause a entrainment of powder within the metal, therefore serious pollution of the product. The presence covering powder must therefore be excluded, and lubrication of the ingot mold-product interface is then ensured by a supply of liquid lubricant to the surface of the metal, or even also through the wall of the mold, at different points of the wall-crust interface solidified. Burning the oil reduces the oxygen content of the ambient atmosphere, but it can only imperfectly protect the metal against reoxidation. This action must then be supplemented by gaseous inerting of the surface environment metal. This inerting is conventionally carried out by insufflation of argon (or nitrogen for casting grades that tolerate high levels of this element) around the jet and on the free surface of the liquid metal. To achieve better containment of this protective atmosphere, we often connect the bottom of the distributor and the upper edge of the ingot mold by a fibrous refractory bellows which, by its flexibility, allows vertical movements of the oscillating ingot mold. The amplitude of these displacements can reach a few tens of mm. However, experience shows that these methods of protection are not completely satisfactory and sometimes do not sufficiently prevent the metal to reoxidize. Oxygen content is only very rarely measured in the vicinity of the surface less than 3%, which is still too high. This excessive oxidation of the metal results in the formation of oxidized inclusions, some of which settle on the surface metal and must be periodically removed manually by operators. But if a bellows is used which isolates the environment of the mold from the external atmosphere, this removal is not possible. As for the inclusions which do not settle, they remain within the metal and deteriorate its quality.

The object of the invention is to propose a device for inerting the environment of the surface of the liquid metal bath in an ingot mold more efficient than the devices existing.

To this end, the invention relates to a space inerting device surrounding the free surface of the molten metal poured into a continuous casting mold of metals located under a distributor, from which flows a stream of metal casting liquid feeding the mold, characterized in that it comprises an annular membrane inflatable made of a flexible material permeable to gases and whose thickness, in the state inflated, is greater than the maximum distance between the upper edge of the mold and the bottom of the distributor during casting, a tubular frame housed inside said membrane and provided with at least one tube for supplying an inerting gas in its interior and outlet ports through which said gas escapes within said interior membrane, means for fixing the membrane on the bottom of the distributor or on the upper edge of the mold in a position such that it surrounds the casting jet, and means for blowing said inerting gas into said tube making it possible to ensure the inflation of the membrane and keeping it in compressed state in tight contact and simultaneous with the bottom of the distributor and the upper edge of the mold.

As will be understood, the invention consists in interposing between the bottom of the distributor and the upper edge of the mold an annular seal which is inflated by a gas under pressure. It is made of a heat-resistant and sufficiently permeable material gas (preferably due to its natural porosity) so that gas leaking from the joint come fill the space defined by the seal, the bottom of the distributor and the upper edge of the ingot mold, and in which are the pouring jet and the free surface of the liquid metal poured into the mold. This seal is fixed to the bottom of the distributor or to the upper edge of the ingot mold, and must, once inflated, have a thickness such that it is sufficient to fill the space separating the distributor and the ingot mold when this space has its width maximum (i.e. when the mold, during its oscillation cycle, is in its lowest position).

The invention will be better understood on reading the description which follows, given in reference to the attached single figure, which shows a front view and in cross section a device according to the invention, installed on a continuous metal casting machine.

The single figure shows schematically the upper part of an installation continuous casting of steel billets. Conventionally, it includes a distributor 1 containing liquid steel 2, and of which only the bottom 3 is shown. The bottom 3 has a calibrated nozzle 4 through which the liquid steel 2 flows to form a pouring jet 5. This enters the interior space of a bottomless ingot mold 6 whose walls 7, 8, 9 are energetically cooled internally by water circulating in non-ducts represented. The liquid steel 2 present in the mold 6 gradually solidifies against the walls 7, 8, 9 to form the outer crust 10 of a cast product 11 which is extract from the mold 6 by known means not shown. Upon leaving the mold 6, the product 11 is sprayed with water through nozzles 12, 13, 14, 15 to accelerate its cooling. A layer of lubricating oil 16 covers the surface 17 of the steel liquid 2 present in the ingot mold 6. This is driven by an oscillating movement vertical according to arrow 18, by known means not shown. The amplitude of these oscillations can be of the order of a few mm to a few cm, and their frequency of in the order of a few Hz. Oil can also, in known manner, be supplied in various points of the wall interface 7, 8, 9-crust 10 by orifices (not shown) formed in the walls 7, 8, 9.

• une membrane gonflable 19 de forme annulaire, réalisée en un matériau réfractaire souple poreux, pouvant résister à des températures de l'ordre de 800 à 900°C environ ;
• une armature métallique tubulaire 20, logée à l'intérieur de la membrane 19 ; elle est pourvue de tuyaux 21, 22 d'amenée d'un gaz d'inertage neutre tel que de l'argon ou de l'azote dans son intérieur et d'orifices 23, 24 de quelques mm de diamètre par lesquels ce gaz neutre s'échappe à l'intérieur de la membrane 19 pour assurer son gonflage, puis l'inertage de l'espace environnant le jet de coulée 5 et la surface 17 de l'acier liquide 2 présent dans la lingotière 6 ;
• une plaque annulaire 25 à laquelle sont fixées les parties supérieures de la membrane 19 et de l'armature 20, et qui est elle-même fixée au fond 3 du répartiteur 1, de manière à ce que la membrane 19 entoure le jet de coulée 5.

The continuous casting installation is provided with an inerting device preventing the casting jet 5 and the surface 17 of the liquid steel 2 present in the mold 6 from being exposed to a reactive atmosphere such as ambient air. . According to the invention, this device comprises:

• an inflatable membrane 19 of annular shape, made of a porous flexible refractory material, capable of withstanding temperatures of the order of about 800 to 900 ° C .;
• a tubular metal frame 20, housed inside the membrane 19; it is provided with pipes 21, 22 for supplying a neutral inerting gas such as argon or nitrogen in its interior and orifices 23, 24 a few mm in diameter through which this neutral gas escapes inside the membrane 19 to ensure its inflation, then the inerting of the space surrounding the casting jet 5 and the surface 17 of the liquid steel 2 present in the mold 6;
• an annular plate 25 to which the upper parts of the membrane 19 and of the frame 20 are fixed, and which is itself fixed to the bottom 3 of the distributor 1, so that the membrane 19 surrounds the pouring jet 5 .

Conventional means, not shown, for insufflating a neutral gas supply the pipes 21, 22 under flow and pressure conditions such that a inflation of the membrane 19 which gives it a shape approaching that of a torus. The dimensions of the membrane are calculated so that once inflated, it can fill at the compressed state, like an O-ring, the space separating the bottom 3 from the distributor 1 and the upper edge 26 of the mold 6, even when the mold 6 and the distributor 1 are at their maximum distance during the oscillation cycle of the ingot mold 6. Under the effect of the internal pressure prevailing in the membrane 19, the latter is permanently in flexible and sealed contact with the upper edge 26 of the mold 6, which is itself set in motion by the oscillations of the mold 6.

Due to the porous nature of the membrane 19, a fraction of the gas which swells it escapes into the interior space 27 delimited by the membrane 19, the distributor 1 and the ingot mold 6, and contributes to making its atmosphere inert with respect to the casting jet 5 and the surface 17 of the liquid steel 2 present in the mold. Especially if we also provide good sealing of the contact between the plate 25 and the bottom 3 of the distributor 1, it is thus possible obtain an oxygen content of the order of 0.5% in space 27, which is sufficient down to suppress significant reoxidation of the liquid metal 2. We do not observe, in effect, more formation of oxides on the surface of the bath 17, and it is no longer necessary to carry out periodic cleaning of this surface 17.

As an example, a membrane 19 made of refractory felt based on graphite, having a porosity of around 70% and a thickness of 8 mm. Initially, the felt is in the form of a commercial strip which is rolled up to form a tube which is closed according to a generator by sewing or gluing, then which is closed on itself to form a ring. To ensure the inflation of the membrane 19, we injects 150 Nl / min of nitrogen under a pressure of 1 bar. This gas injection allows also to sufficiently cool the membrane 19 to avoid its deterioration thermal.

Optionally, the membrane 19 can be coated, on its portion facing the outside of the space 27, by a gas-tight material, so that all the gas leaving the membrane 19 is effectively introduced into the space 27.

Alternatively, the plate 25 can also be given a relatively thick important and integrate a transparent window, through which we can have access visual on the surface 17 of the liquid metal 2 in an ingot mold, so as to make it possible the use of a device for regulating the level of this surface 17 of a type comprising a camera or any other device requiring optical access to the surface 17.

Another variant would be to fix the plate 25 either on the bottom 3 of the distributor 1, but on the upper edge 26 of the mold 6.

Of course, the plate 25 is only one example of a means of fixing the membrane 19, and any other type of fixing means which can play the same function is usable.

The device according to the invention, in addition to its effectiveness for protecting the metal liquid, has the advantages of ease of installation and use. In particular, it is very tolerant of slight variations in height positioning of the distributor 1 (a few mm) that can usually be encountered.

The device according to the invention can also be used on the installations of casting which include, instead of an oscillating ingot mold, an ingot mold to which prints low amplitude and high frequency movements using transmitters ultrasonic, as well as molds on which such movements are superimposed on classic oscillations. It is also applicable in the case of ingot molds which are extended upwards by an extension of refractory material inside which maintains the surface of the liquid steel.

It goes without saying that the device according to the invention can also be used in the case where the casting jet 5 is itself protected by a tube of refractory material. It is applicable to the casting of products of all formats. Likewise, it is applicable to continuous casting other metals than steel.

Claims (4)

Device for inerting the space (27) surrounding the free surface (17) of the metal liquid (2) poured into a mold (6) for continuous metal casting located under a distributor (1), from which flows a pouring stream (5) of liquid metal (2) supplying the mold (6), characterized in that it comprises an inflatable annular membrane (19) made of a flexible material permeable to gases and the thickness of which, when inflated, is greater than the maximum distance separating the upper edge (26) of the mold (6) and the bottom (3) of the distributor (1) during casting, a tubular frame (20) housed inside of said membrane (19) and provided with at least one tube (21, 22) for supplying a gas inerting in its interior and outlet orifices (23, 24) through which said gas escapes inside said membrane (19), means (25) for fixing the membrane (19) to the bottom (3) of the distributor (1) or on the upper edge (26) of the mold (6) in a position as it surrounds the pouring jet (5), and means for blowing said gas inerting in said tubing (21, 22) for ensuring the inflation of the membrane (19) and to maintain it in the compressed state in tight and simultaneous contact with the bottom (3) of the distributor (1) and the upper edge (26) of the mold (6). Device according to claim 1, characterized in that said membrane (19) is made of a refractory felt based on graphite. Device according to claim 1 or 2, characterized in that said membrane (19) is coated, on its portion facing the outside of the space (27) surrounding the free surface (17) of the liquid metal (2) present in the mold (6), by a material impervious to inerting gas. Device according to one of claims 1 to 3, characterized in that said annular plate (25) has a window made of a transparent material giving access optical on the free surface (17) of the liquid metal (2) present in the mold (6).

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