EP0255450A2 - Device for gas-shielding a molten metal jet - Google Patents

Device for gas-shielding a molten metal jet Download PDF

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Publication number
EP0255450A2
EP0255450A2 EP87401801A EP87401801A EP0255450A2 EP 0255450 A2 EP0255450 A2 EP 0255450A2 EP 87401801 A EP87401801 A EP 87401801A EP 87401801 A EP87401801 A EP 87401801A EP 0255450 A2 EP0255450 A2 EP 0255450A2
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EP
European Patent Office
Prior art keywords
carbon dioxide
container
mold
gas
steel
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Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP87401801A
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German (de)
French (fr)
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EP0255450A3 (en
EP0255450B1 (en
Inventor
Guy Savard
Robert Gum Hong Lee
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Air Liquide Canada Inc
Canadian Liquid Air Ltd
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Air Liquide Canada Inc
Canadian Liquid Air Ltd
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Priority to AT87401801T priority Critical patent/ATE51352T1/en
Publication of EP0255450A2 publication Critical patent/EP0255450A2/en
Publication of EP0255450A3 publication Critical patent/EP0255450A3/en
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Publication of EP0255450B1 publication Critical patent/EP0255450B1/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D27/00Treating the metal in the mould while it is molten or ductile ; Pressure or vacuum casting
    • B22D27/003Treating the metal in the mould while it is molten or ductile ; Pressure or vacuum casting by using inert gases
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D11/00Continuous casting of metals, i.e. casting in indefinite lengths
    • B22D11/10Supplying or treating molten metal
    • B22D11/106Shielding the molten jet

Definitions

  • the invention relates to a method of forming a protective gas shield around the steel to prevent oxidation, when this steel is poured from a container in the form of a liquid stream until the moment when it solidifies.
  • the liquid steel produced by any of the well known methods usually contains a high oxygen content. This is detrimental to its quality.
  • the steel is calmed by introducing into the liquid steel deoxidizing agents, for example, silicon, in the form of ferrosilicon, or aluminum or these two substances at the same time. This is usually done in a transfer pocket, on casting.
  • the quenched liquid steel has a strong affinity for oxygen, which it absorbs when it is exposed to the atmosphere, when it is poured into ingot molds, to form billets. or slabs. This results in defects in the resulting steel.
  • liquid argon is poured into the molds.
  • the argon evaporates when it comes into contact with the liquid steel and isolates the latter from the atmosphere during the rest of the casting in the ingot mold.
  • the main drawbacks of this process are that the storage and transport of the equipment is difficult to adapt to the severe working conditions of the casting platform and, moreover, the cost of argon is high, relatively at the price of normal steel grades.
  • Another method uses liquid nitrogen to form a protective shield for the stream of liquid steel as it is cast in a continuous casting machine.
  • This process is described in the brochure entitled "Conspal Surface Protection” published by Concast AG, Zurich, Switzerland, in March 1977, and in US Patent No. 4,178,980, issued in the name of L'Air Liquide.
  • liquid nitrogen gives a degree of protection which provides a good improvement compared to other processes.
  • handling this substance under the harsh conditions of the casting platform makes it difficult in some cases to obtain continuity of the casting during the operation.
  • CO2 carbon dioxide
  • the Applicant has found that the kinetics of the reactions are such that, on coming into contact with liquid steel, and although the carbon dioxide decomposes at the gas-metal interface, a negligible quantity of oxygen dissolves in the metal and the carbon monoxide formed behaves like a screen layer at the gas-metal interface. Not only oxidation is considerably reduced compared to the level it would reach in the absence of a shielding layer between the metal and the atmosphere, but also the absorption of nitrogen and hydrogen (coming from the humidity of the air) by liquid steel. The absorption of oxygen from decomposition is less than about 60 parts per million and can be reduced to 40 parts per million. Carbon dioxide is therefore capable of forming an effective screen between liquid steel and the surrounding atmosphere when this steel is poured from a container in the form of a liquid stream until it solidifies, which considerably reduces the rate of oxidation.
  • a protective carbon dioxide screen is formed around the stream of liquid steel, close to its source, and this screen is kept in contact with the steel until the latter is solidifies.
  • the general criteria to be observed for the use of carbon dioxide as a protective screen are generally the same as in the case of the use of argon or other inert gases.
  • the ingot mold is purged in advance using carbon dioxide to remove the oxygen and to form an anhydride atmosphere in the ingot mold. carbon dioxide into which and through which the steel is poured.
  • the oxygen content of the mold, before casting can be reduced to less than 3% by volume, and preferably, to 1% at most.
  • the protective screen can be formed by means of an annular ramp pierced with outlet orifices which are arranged around the stream of liquid steel, close to its source, for delivering carbon dioxide in the form of jets. which come together to form a cover that follows the surface of the steel stream.
  • an annular distribution ramp can surround the outlet nozzle of the ladle.
  • the steel forming the liquid stream is usually at a temperature between 1,625 ° C and 1,650 ° C.
  • the invention also relates to the use of mixtures of argon and carbon dioxide in steel casting to prevent oxidation.
  • FIG. 1 represents a pocket A containing liquid steel which is poured into an ingot mold B.
  • a protective gas composed of carbon dioxide, is conveyed through an annular distribution ramp (represented in FIG. 4), supplied by a supply line 15.
  • An ingot mold B1 which waits its turn to receive the liquid steel, is shown while receiving carbon dioxide purge gas via a line 17 and the following ingot molds B1 and B2 wait their turn to be processed.
  • each of the molds Before entering the treatment phase, each of the molds is provided with a cap 19 formed of an aluminum film.
  • the cap 19 has been torn locally to form an opening for the introduction of the gas pipe.
  • Figure 2 shows, in more detail, the mold B1 being purged with carbon dioxide.
  • Line 17 is passed through an opening 20 in the aluminum foil cap and it ends in a nozzle 18 through which carbon dioxide is introduced into the bottom of the mold to move the air and replace it with a carbon dioxide atmosphere.
  • the ingot mold B1 has a wall 22 which encloses a molding cavity 23 of decreasing section.
  • the base of the wall 22 is supported on a corrugated metal interlayer 24, which is itself supported by the plate of a carriage C and is intended to form a seal between the base of the wall 22 and the plate of the carriage, by letting a certain quantity of carbon dioxide gas escape laterally.
  • Carbon dioxide is injected into the mold B1 until this mold has an oxygen content of not more than 3%, and preferably not more than 1%.
  • the mold is now ready for casting. It is then brought to the position of the mold B and the casting operation is carried out as described with reference to FIG. 4.
  • a valve arranged in the pocket A is opened, by means of a remote control, for allow the liquid steel to flow through an outlet passage 25 formed in the pocket A and pass in the form of a vertical current at the level of a protective gas diffuser 27.
  • the diffuser 27 is supplied with gaseous carbon dioxide by a pipe 15, which has the effect that a gas screen surrounds the stream of liquid metal and accompanies the latter when it enters the carbon dioxide atmosphere contained in the ingot mold B.
  • the liquid steel is isolated from the atmosphere by a continuous curtain of carbon dioxide.
  • the valve of the ladle is closed to stop the flow of liquid metal and the next ingot mold and the ladle are brought into positions of mutual alignment so that this ingot mold receives its liquid steel content.
  • equipment which is substantially as shown in FIG. 4.
  • a bag is used having a capacity of 50 tonnes and ingot molds each having a capacity of 8 to 9 tonnes.
  • the pocket has a circular opening or nozzle with a diameter of 5 to 6.5 cm.
  • Each mold has a depth of 240 to 260 cm. The distance from the bottom of the nozzle to the upper surface of the mold is 75 cm.
  • Each ingot mold rests on a trolley-mounted interlayer, of the type used to remove solidified ingots from the casting station.
  • the bag is equipped with a perforated circular ramp, located just below the nozzle and capable of forming a protective screen for carbon dioxide gas.
  • This ramp is connected to a continuous source of carbon dioxide gas supply.
  • the installation includes conventional equipment for purging the ingot mold by means of carbon dioxide gas.
  • each mold is purged using carbon dioxide gas, at a rate of 2.8 cubic meters per minute, to expel the air from inside the mold.
  • the air is expelled from the interior of the ingot mold by the carbon dioxide purge at a flow rate of 2265 to 2832 liters / minute (80 to 100 sefm standard cubic foot minute), for approximately 3 minutes before the casting of each ingot .
  • a rubber hose with asbestos protective coating is introduced into the mold, through the aluminum film, so that the diffuser plunges as low as possible, as shown in Figure 2.
  • the gas flow is extended to the air has been expelled from the mold, to such an extent that the concentration of oxygen in the mold does not exceed 1% by volume.
  • the gas injection is extended to an instant immediately preceding the pouring into this ingot mold, this to take account of the gas leak between the ingot mold and its interlayer.
  • the molds are prepared for casting according to the following procedure.
  • a strong jet of compressed air is projected onto the interlayer to remove any free particles from it.
  • a coating composed of a dispersion of cement in dilute phosphoric acid is then applied to the interlayer.
  • Four strips of corrugated steel sheet of approximately 150 mm x 750 mm 1.6 mm are placed on the interlayer, in a square or a rectangle.
  • an oblong chimney made of thin sheet steel, measuring approximately 500 mm x 1,000 mm x 1,250 mm, to reduce the intensity of projections to the time of the start of the pouring of liquid metal into the ingot mold.
  • Exothermic "boards" are fixed (hot elevations or “hot tops"), on the upper end 12 ′ of the internal surface of the ingot mold, these boards generating heat by coming into contact with the liquid steel, this for to slow the cooling at the part of the ingot, and to thereby reduce the depth of the recess formed in the upper part of this ingot and which must be cut before the subsequent rolling.
  • a thin aluminum foil cap is placed over the top of the mold to limit exposure to the atmosphere before the mold has been purged with carbon dioxide.
  • the liquid steel punctures a small hole in the thin aluminum sheet, thereby reducing the amount of ambient air that is drawn into the mold.
  • the temperature of the current steel is from 1,625 ° C to 1,650 ° C.
  • a carbon dioxide screen forms near the source of the current, that is to say just below the bottom of the pocket, under the nozzle.
  • the screen formed around the current of liquid steel is entrained with the steel and forms a protective screen insulating from the atmosphere from the moment the steel leaves the nozzle until its impact in the mold.
  • the carbon dioxide flow rate sent to the screen is 2.8 cubic meters per minute.
  • the pocket containing the 50 tonnes of steel is positioned above the first ingot mold, already purged and the flow of screen gas is put into action.
  • the purge pipe was previously transferred to the second ingot mold without interrupting the flow of gas.
  • the valve is open to start casting (see Figure 4). At times, the nozzle is blocked by solidified metal or by slag. In each case, it is necessary to inject oxygen to the lance to clear the nozzle (see Figure 4).
  • CO2 gas is used at the two injection points (purging and forming a screen).
  • a device is therefore used which has a vaporization capacity to provide a flow rate comparable to that of an inert gas, for example argon.
  • the composition of the CO2 supply is shown in Figure 5.
  • the ingot mold is filled and the valve is closed (for approximately 20 to 30 seconds) while the crane operator positions the pocket above the second ingot mold. During this time, the purge gas pipe is transferred to the next ingot mold and the valve is opened again to fill the mold that has just been purged. The sequence is continued until the pocket is emptied of its metal charge.
  • each ingot mold is allowed to cool, in the conventional manner, with a layer of protective flux on its surface, so as to form a solid ingot.
  • the ingot molds are then emptied of their ingots.
  • Each ingot is hot rolled into a strip, according to standard practice, then subjected to ultrasonic control for the detection of surface defects.
  • the acceptable strip was then rolled into a sheet and the sheet was then made into a helically welded tube. The tube was then subjected to ultrasonic testing for fault detection.
  • the gas flow rate was 2.8 cubic meters per minute in the case of carbon dioxide and 2.8 cubic meters per minute in the case of l 'argon.
  • Each mold was purged for approximately 2 minutes and the stream of liquid metal was protected for the duration of the casting operation, approximately 25 minutes.
  • this gas constitutes an extremely useful gas when used according to the invention.
  • Carbon dioxide is heavier than air (1.5: 1) unlike argon (1.5: 2) and therefore it maintains an effective protective screen longer than lighter gases since it does not does not disperse into the atmosphere as easily.
  • Carbon dioxide can be used in the form of carbon dioxide snow to provide a concentrated form of CO2 gas for the use of the ingot mold in ingot casting or in the ingot mold of a continuous casting installation.

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  • Mechanical Engineering (AREA)
  • Engineering & Computer Science (AREA)
  • Continuous Casting (AREA)
  • Feeding, Discharge, Calcimining, Fusing, And Gas-Generation Devices (AREA)
  • Treatment Of Steel In Its Molten State (AREA)
  • Laminated Bodies (AREA)
  • Manufacture Of Alloys Or Alloy Compounds (AREA)
  • Ink Jet (AREA)
  • Glass Compositions (AREA)
  • Professional, Industrial, Or Sporting Protective Garments (AREA)
  • Coating With Molten Metal (AREA)
  • Air Bags (AREA)
  • Supply Devices, Intensifiers, Converters, And Telemotors (AREA)
  • Electrical Discharge Machining, Electrochemical Machining, And Combined Machining (AREA)
  • Manufacture Of Metal Powder And Suspensions Thereof (AREA)
  • Percussion Or Vibration Massage (AREA)
  • Waste-Gas Treatment And Other Accessory Devices For Furnaces (AREA)

Abstract

Selon l'invention, on protège l'acier liquide, qui s'écoule en un courant à partier d'un récipient tel qu'une poche (A), soit dans une lingotière (B), soit dans un moule de coulée continue, en l'isolant de l'atmosphère environnante au moyen d'un écran d'anhydride carbonique. L'anhydride carbonique se décompose pour former un écran protecteur de gaz inerte. L'absorption d'oxygène par l'acier reste négligeable. Les moules ou lingotières utilisés pour recevoir l'aicer liquide versé par la poche sont purgés au moyen d'anhydride carbonique avant la coulée.According to the invention, the liquid steel is protected, which flows in a current from a container such as a pocket (A), either in an ingot mold (B), or in a continuous casting mold, by isolating it from the surrounding atmosphere by means of a carbon dioxide screen. Carbon dioxide decomposes to form a protective shield from inert gas. The absorption of oxygen by the steel remains negligible. The molds or ingot molds used to receive the liquid aicer poured from the bag are purged by means of carbon dioxide before pouring.

Description

L'invention concerne un procédé de formation d'un écran protecteur de gaz autour de l'acier pour éviter l'oxydation, lorsque cet acier est coulé à partir d'un récipient sous la forme d'un courant liquide jusqu'au moment où il se solidifie.The invention relates to a method of forming a protective gas shield around the steel to prevent oxidation, when this steel is poured from a container in the form of a liquid stream until the moment when it solidifies.

Dans la pratique normale, l'acier liquide produit par l'un quelconque des procédés bien connus contient habituellement une forte teneur en oxygène. Ceci est préjudiciable à sa qualité. Pour éviter cet inconvénient, on calme l'acier en introduisant dans l'acier liquide des agents désoxydants, par exemple, du silicium, sous la forme de ferrosilicium, ou de l'aluminium ou encore ces deux substances à la fois. Ceci s'effectue habituellement dans une poche de transfert, à la coulée.In normal practice, the liquid steel produced by any of the well known methods usually contains a high oxygen content. This is detrimental to its quality. To avoid this drawback, the steel is calmed by introducing into the liquid steel deoxidizing agents, for example, silicon, in the form of ferrosilicon, or aluminum or these two substances at the same time. This is usually done in a transfer pocket, on casting.

A la suite du traitement de désoxydation, l'acier liquide calmé possède une forte affinité pour l'oxygène, qu'il absorbe lorsqu'il est exposé à l'atmosphère, au moment où on le coule dans des lingotières, pour former des billettes ou brames. Ceci se traduit par des défauts dans l'acier résultant.Following the deoxidation treatment, the quenched liquid steel has a strong affinity for oxygen, which it absorbs when it is exposed to the atmosphere, when it is poured into ingot molds, to form billets. or slabs. This results in defects in the resulting steel.

Pour éviter ou réduire cette absorption d'oxygène, on a déjà utilisé différents procédés de protection. Un procédé consiste à protéger les courants d'acier liquide coulés à l'air libre en les faisant passer dans des tuyaux céramiques entre le bassin de coulée et la lingotière. Cette technique constituait une pratique établie adoptée pour maintenir une qualité élevée dans la coulée continue de blooms et brames de forte section. Malheureusement, elle ne peut pas être appliquée aux blooms et billettes de plus petite section en raison de limitations d'espace. Un exemple de ce type de procédé est décrit dans le brevet canadien n o 1 097 881.To avoid or reduce this absorption of oxygen, various protection procedures have already been used. One method consists in protecting the streams of liquid steel poured in the open air by passing them through ceramic pipes between the casting basin and the ingot mold. This technique was an established practice adopted to maintain high quality in the continuous casting of large section blooms and slabs. Unfortunately, it cannot be applied to smaller blooms and billets due to space limitations. An example of this type of process is described in Canadian Patent No. 1,097,881.

Dans un autre procédé, on verse de l'argon liquide dans les lingotières. L'argon s'évapore en entrant en contact avec l'acier liquide et isole ce dernier de l'atmosphère pendant la suite de la coulée dans la lingotière. Les principaux inconvénients de ce procédé consistent en ce que le stockage et le transport de l'équipement sont difficiles à adapter aux sévères conditions de travail de la plate-forme de coulée et, par ailleurs, le coût de l'argon est élevé, relativement au prix des nuances normales d'acier.In another method, liquid argon is poured into the molds. The argon evaporates when it comes into contact with the liquid steel and isolates the latter from the atmosphere during the rest of the casting in the ingot mold. The main drawbacks of this process are that the storage and transport of the equipment is difficult to adapt to the severe working conditions of the casting platform and, moreover, the cost of argon is high, relatively at the price of normal steel grades.

La protection par gaz inerte de l'acier coulé en continu a également été décrite dans l'article "Gas Shrouding of Strand Cast Steel at Jones & Laughlin Steel Corporation" de Samways, Pollard & Fedenco, Journals of Metals, octobre 1974, ainsi que dans les brevets américains, 3 908 734, 3 963 224 et 4 023 614.The inert gas protection of continuously cast steel has also been described in the article "Gas Shrouding of Strand Cast Steel at Jones & Laughlin Steel Corporation" by Samways, Pollard & Fedenco, Journals of Metals, October 1974, as well as in U.S. patents, 3,908,734, 3,963,224 and 4,023,614.

Un autre procédé utilise de l'azote liquide pour former un écran protecteur pour le courant d'acier liquide au moment où il est coulé dans une machine de coulée continue. Ce procédé est décrit dans la brochure intitulée "Conspal Surface Protection" éditée par Concast AG, Zurich, Suisse, mars 1977, ainsi que dans le brevet américain n o 4 178 980, délivré au nom de L'Air Liquide. En général, l'azote liquide donne un degré de protection qui apporte une bonne amélioration comparativement aux autres procédés. Toutefois, la manipulation de cette substance dans les sévères conditions de la plate-forme de coulée rend dans certains cas difficile l'obtention de la continuité de la coulée pendant l'opération.Another method uses liquid nitrogen to form a protective shield for the stream of liquid steel as it is cast in a continuous casting machine. This process is described in the brochure entitled "Conspal Surface Protection" published by Concast AG, Zurich, Switzerland, in March 1977, and in US Patent No. 4,178,980, issued in the name of L'Air Liquide. In general, liquid nitrogen gives a degree of protection which provides a good improvement compared to other processes. However, handling this substance under the harsh conditions of the casting platform makes it difficult in some cases to obtain continuity of the casting during the operation.

Les textes de publications et brevets mentionnés ci-dessus sont incorporés ici à titre de références.The texts of publications and patents mentioned above are incorporated here for reference.

La demanderesse a constaté que, contre toute attente, l'anhydride carbonique (CO₂) peut être utilisé efficacement comme gaz protecteur pour protéger l'acier liquide de l'oxydation par l'atmosphère dans le cas de la coulée continue, ou de la coulée en lingots, lorsque cet acier est coulé à partir d'un récipient sous la forme d'un courant liquide jusqu'au moment où il se solidifie.The Applicant has found that, against all expectations, carbon dioxide (CO₂) can be used effectively as a protective gas to protect the liquid steel from oxidation by the atmosphere in the case of continuous casting, or casting in ingots, when this steel is poured from a container in the form of a liquid stream until it solidifies.

Il est connu d'utiliser l'anhydride carbonique pour protéger les métaux liquides tels q omb, le zinc, le cuivre, métaux qui possèdent un point de fusion inférieur à la température de décomposition de l'anhydride carbonique. En se basant sur des considérations thermodynamiques, on doit s'attendre à ce qu'une telle protection ne soit pas réalisée par le coulée de métaux ayant un point de fusion supérieur à la température de décomposition de l'anhydride carbonique. En particulier, on doit s'attendre à ce que, sous l'effet du contact entre l'anhydride carbonique et l'acier liquide, ce dernier soit oxydé par la décomposition du gaz, puisque sa température de décomposition est très inférieure à celle de l'acier liquide. De manière inattendue, la demanderesse a constaté que les cinétiques des réactions sont telles que, en entrant en contact avec l'acier liquide, et bien que l'anhydride carbonique se décompose à l'interface gaz-métal, une quantité négligeable d'oxygène se dissout dans le métal et l'oxyde de carbone formé se comporte comme une couche écran à l'interface gaz-métal. Non seulement l'oxydation est considérablement réduite comparativement au niveau qu'elle atteindrait en l'absence de couche écran entre le métal et l'atmosphère mais on évite également l'absorption d'azote et d'hydrogène (provenant de l'humidité de l'air) par l'acier liquide. L'absorption d'oxygène issu de la décomposition est inférieure à environ 60 parties par million et peut être réduite à 40 parties par million. L'anhydride carbonique est donc capable de former un écran efficace entre l'acier liquide et l'atmosphère environnante lorsque cet acier est coulé à partir d'un récipient dans la forme d'un courant liquide jusqu'au moment où il se solidifie, ce qui réduit considérablement le taux d'oxydation.It is known to use carbon dioxide to protect liquid metals such as omb, zinc, copper, metals which have a melting point below the decomposition temperature of carbon dioxide. Based on thermodynamic considerations, it should be expected that such protection will not be achieved by the casting of metals having a melting point above the decomposition temperature of carbon dioxide. In particular, it should be expected that, under the effect of contact between carbon dioxide and liquid steel, the latter will be oxidized by the decomposition of the gas, since its decomposition temperature is much lower than that of liquid steel. Unexpectedly, the Applicant has found that the kinetics of the reactions are such that, on coming into contact with liquid steel, and although the carbon dioxide decomposes at the gas-metal interface, a negligible quantity of oxygen dissolves in the metal and the carbon monoxide formed behaves like a screen layer at the gas-metal interface. Not only oxidation is considerably reduced compared to the level it would reach in the absence of a shielding layer between the metal and the atmosphere, but also the absorption of nitrogen and hydrogen (coming from the humidity of the air) by liquid steel. The absorption of oxygen from decomposition is less than about 60 parts per million and can be reduced to 40 parts per million. Carbon dioxide is therefore capable of forming an effective screen between liquid steel and the surrounding atmosphere when this steel is poured from a container in the form of a liquid stream until it solidifies, which considerably reduces the rate of oxidation.

Dans la mise en oeuvre du procédé, on forme un écran protecteur d'anhydride carbonique autour du courant d'acier liquide, à proximité de sa source, et on maintient cet écran en contact avec l'acier jusqu'à ce que ce dernier se solidifie. Les critères généraux à respecter pour l'utilisation de l'anhydride carbonique en tant qu'écran protecteur sont généralement les mêmes que dans le cas de l'utilisation de l'argon ou d'autres gaz inertes. Par exemple, dans le cas de la coulée d'un lingot par le haut dans une lingotière, on purge à l'avance la lingotière au moyen d'anhydride carbonique pour éliminer l'oxygène et pour former dans la lingotière une atmosphère d'anhydride carbonique dans laquelle et à travers laquelle l'acier est coulé.In the implementation of the process, a protective carbon dioxide screen is formed around the stream of liquid steel, close to its source, and this screen is kept in contact with the steel until the latter is solidifies. The general criteria to be observed for the use of carbon dioxide as a protective screen are generally the same as in the case of the use of argon or other inert gases. For example, in the case of casting an ingot from above into an ingot mold, the ingot mold is purged in advance using carbon dioxide to remove the oxygen and to form an anhydride atmosphere in the ingot mold. carbon dioxide into which and through which the steel is poured.

De cette façon, la teneur en oxygène de la lingotière, avant la coulée, peut être ramenée à moins de 3 % en volume, et de préférence, à 1 % au plus.In this way, the oxygen content of the mold, before casting, can be reduced to less than 3% by volume, and preferably, to 1% at most.

L'écran protecteur peut être formé au moyen d'une rampe annulaire percée d'orifices de sortie que l'on dispose autour du courant d'acier liquide, à proximité de sa source, pour débiter l'anhydride carbonique sous la forme de jets qui se rassemblent en formant un couvercle qui épouse la surface du courant d'acier. Dans le cas de la coulée dans une lingotière, une rampe de distribution annulaire peut entourer la busette de sortie de la poche de coulée.The protective screen can be formed by means of an annular ramp pierced with outlet orifices which are arranged around the stream of liquid steel, close to its source, for delivering carbon dioxide in the form of jets. which come together to form a cover that follows the surface of the steel stream. In the case of casting in an ingot mold, an annular distribution ramp can surround the outlet nozzle of the ladle.

L'acier formant le courant liquide est habituellement à une température comprise entre 1 625 °C et 1 650 °C.The steel forming the liquid stream is usually at a temperature between 1,625 ° C and 1,650 ° C.

L'invention concerne également l'utilisation de mélanges d'argon et d'anhydride carbonique dans la coulée d'acier pour éviter l'oxydation.The invention also relates to the use of mixtures of argon and carbon dioxide in steel casting to prevent oxidation.

L'invention sera mieux comprise à l'aide des exemples de réalisation suivants, donnés à titre non limitatif, conjointement avec les figures qui représentent :

  • la figure 1 est une vue en perspective qui montre les positions relatives de la poche de coulée et d'une rangée de lingotières, pendant la mise en oeuvre du procédé selon l'invention;
  • la figure 2 est une coupe verticale, en partie en élévation, d'une lingotière pendant l'opération de purge à l'anhydride carbonique qui sert à préparer cette lingotière pour la réception de l'acier liquide;
  • la figure 3 est une vue partielle à échelle agrandie qui montre un intercalair e en acier ondulé qui supporte la base de la lingotière ;
  • la figure 4 est une coupe verticale, en partie en élévation,qui montre une opération de coulée en lingots; et
  • la figure 5 est un schéma montrant la disposition des éléments d'un équipement approprié pour la mise en oeuvre d'un procédé selon l'invention, et les liaisons de transmission des fluides qui relient ces éléments.
The invention will be better understood with the aid of the following embodiments, given without limitation, together with the figures which represent:
  • Figure 1 is a perspective view showing the relative positions of the ladle and a row of molds, during the implementation of the method according to the invention;
  • Figure 2 is a vertical section, partly in elevation, of an ingot mold during the purging operation with carbon dioxide which is used to prepare this ingot mold for the reception of liquid steel;
  • Figure 3 is a partial view on an enlarged scale which shows a corrugated steel spacer which supports the base of the mold;
  • Figure 4 is a vertical section, partly in elevation, which shows an ingot casting operation; and
  • FIG. 5 is a diagram showing the arrangement of the elements of equipment suitable for implementing a method according to the invention, and the transmission links of the fluids which connect these elements.

La figure 1 représente une poche A contenant de l'acier liquide qui est coulé dans une lingotière B. Un gaz protecteur, composé d'anhydride carbonique, est acheminé à travers une rampe de distribution annulaire (représentée sur la figure 4), alimentée par une conduite d'alimentation 15.FIG. 1 represents a pocket A containing liquid steel which is poured into an ingot mold B. A protective gas, composed of carbon dioxide, is conveyed through an annular distribution ramp (represented in FIG. 4), supplied by a supply line 15.

Une lingotière B₁, qui attend son tour pour recevoir l'acier liquide, est représentée alors qu'elle reçoit de l'anhydride carbonique gazeux de purge par une conduite 17 et les lingotières suivantes B₁ et B₂ attendent leur tour pour être traitées.An ingot mold B₁, which waits its turn to receive the liquid steel, is shown while receiving carbon dioxide purge gas via a line 17 and the following ingot molds B₁ and B₂ wait their turn to be processed.

Avant d'entrer dans la phase de traitement, chacune des lingotières est munie d'un chapeau 19 formé d'une pellicule d'aluminium. Le chapeau 19 a été déchiré localement pour former une ouverture pour l'introduction de la conduite de gaz.Before entering the treatment phase, each of the molds is provided with a cap 19 formed of an aluminum film. The cap 19 has been torn locally to form an opening for the introduction of the gas pipe.

La figure 2 montre, d'une façon plus détaillée, la lingotière B₁ en cours de purge par l'anhydride carbonique. La conduite 17 est passée à travers une ouverture 20 du chapeau en pellicule d'aluminium et elle se termine par une buse 18 à travers laquelle l'anhydride carbonique est introduit dans le fond de la lingotière pour déplacer l'air et le remplacer par une atmosphère d'anhydride carbonique.Figure 2 shows, in more detail, the mold B₁ being purged with carbon dioxide. Line 17 is passed through an opening 20 in the aluminum foil cap and it ends in a nozzle 18 through which carbon dioxide is introduced into the bottom of the mold to move the air and replace it with a carbon dioxide atmosphere.

La lingotière B₁ possède une paroi 22 qui renferme une cavité de moulage 23 à section décroissante. La base de la paroi 22 est appuyée sur un intercalaire 24 en métal ondulé, qui est lui-même supporté par le plateau d'un chariot C et est destiné à former un joint entre la base de la paroi 22 et le plateau du chariot, en laissant une certaine quantité d'anhydride carbonique gazeux s'échapper latéralement.The ingot mold B₁ has a wall 22 which encloses a molding cavity 23 of decreasing section. The base of the wall 22 is supported on a corrugated metal interlayer 24, which is itself supported by the plate of a carriage C and is intended to form a seal between the base of the wall 22 and the plate of the carriage, by letting a certain quantity of carbon dioxide gas escape laterally.

On injecte de l'anhydride carbonique dans la lingotière B₁ jusqu'à ce que cette lingotière possède un contenu d'oxygène non supérieur à 3%, et de préférence, de 1 % au plus. La lingotière est maintenant prête pour la coulée. Elle est alors amenée à la position de la lingotière B et l'opération de coulée est exécutée de la façon décrite en regard de la figure 4. On ouvre une vanne agencée dans la poche A, au moyen d'une commande à distance, pour laisser l'acier liquide s'écouler à travers un passage de sortie 25 ménagé dans la poche A et passer sous la forme d'un courant vertical au droit d'un diffuseur de gaz protecteur 27. Le diffuseur 27 est alimenté en anhydride carbonique gazeux par une conduite 15, ce qui a pour effet qu'un écran de gaz entoure le courant de métal liquide et accompagne ce dernier lorsqu'il pénètre dans l'atmosphère d'anhydride carbonique contenue dans la lingotière B. Depuis l'instant où il sort de la poche jusqu'à l'instant où il atteint sa destination dans la lingotière, l'acier liquide est isolé de l'atmosphère par un rideau continu d'anhydride carbonique. Lorsque la lingotière est remple, on referme la vanne de la poche pour arrêter l'écoulement de métal liquide et on amène la lingotière suivante et la poche dans des positions d'alignement mutuel pour que cette lingotière reçoive son contenu d'acier liquide.Carbon dioxide is injected into the mold B₁ until this mold has an oxygen content of not more than 3%, and preferably not more than 1%. The mold is now ready for casting. It is then brought to the position of the mold B and the casting operation is carried out as described with reference to FIG. 4. A valve arranged in the pocket A is opened, by means of a remote control, for allow the liquid steel to flow through an outlet passage 25 formed in the pocket A and pass in the form of a vertical current at the level of a protective gas diffuser 27. The diffuser 27 is supplied with gaseous carbon dioxide by a pipe 15, which has the effect that a gas screen surrounds the stream of liquid metal and accompanies the latter when it enters the carbon dioxide atmosphere contained in the ingot mold B. From the moment it leaves the pocket until it reaches its destination in the mold, the liquid steel is isolated from the atmosphere by a continuous curtain of carbon dioxide. When the ingot mold is cast, the valve of the ladle is closed to stop the flow of liquid metal and the next ingot mold and the ladle are brought into positions of mutual alignment so that this ingot mold receives its liquid steel content.

Pour assurer une alimentation en anhydride carbonique en temps voulu, sur ordre, on utilise un équipement d'alimentation tel que celui représenté sur la figure 5.To ensure a supply of carbon dioxide in due time, on order, use is made of feeding equipment such as that shown in FIG. 5.

EXEMPLEEXAMPLE

Pour les besoins de cet exemple, on utilise un équipement sensiblement tel que représenté sur la figure 4. On utilise une poche possédant une capacité de 50 tonnes et des lingotières possédant chacune une capacité de 8 à 9 tonnes. La poche possède une ouverture ou busette circulaire d'un diamètre de 5 à 6,5 cm. Chaque lingotière possède une profondeur de 240 à 260 cm. La distance séparant l e bas de la busette de la surface supérieure de la lingotière est de 75 cm. Chaque lingotière repose sur un intercalaire monté sur chariot, du type utilisé pour évacuer les lingots solidifiés du poste de coulée.For the purposes of this example, equipment is used which is substantially as shown in FIG. 4. A bag is used having a capacity of 50 tonnes and ingot molds each having a capacity of 8 to 9 tonnes. The pocket has a circular opening or nozzle with a diameter of 5 to 6.5 cm. Each mold has a depth of 240 to 260 cm. The distance from the bottom of the nozzle to the upper surface of the mold is 75 cm. Each ingot mold rests on a trolley-mounted interlayer, of the type used to remove solidified ingots from the casting station.

La poche est équipée d'une rampe circulaire perforée, située juste au-dessous de la busette et capable de former un écran protecteur d'anhydride carbonique gazeux. Cette rampe est reliée à une source continue d'alimentation d'anhydride carbonique gazeux. En outre, l'installation comprend un appareillage classique pour purger la lingotière au moyen d'anhydride carbonique gazeux.The bag is equipped with a perforated circular ramp, located just below the nozzle and capable of forming a protective screen for carbon dioxide gas. This ramp is connected to a continuous source of carbon dioxide gas supply. In addition, the installation includes conventional equipment for purging the ingot mold by means of carbon dioxide gas.

Juste avant la coulée, on purge chaque lingotière au moyen d'anhydride carbonique gazeux, à un débit de 2,8 mètres cubes par minute, pour expulser l'air de l'intérieur de la lingotière. L'air est expulsé de l'intérieur de la lingotière par la purge d'anhydride carbonique à un débit de 2265 à 2832 litres/minute (80 à 100 sefm standard cubic foot minute), pendant environ 3 minutes avant la coulée de chaque lingot. On introduit un tuyau de caoutchouc à revêtement protecteur d'amiante dans la lingotière, à travers la pellicule d'aluminium, de façon que le diffuseur plonge aussi bas que possible, comme représenté sur la figure 2. On prolonge l'écoulement de gaz jusqu'à ce que l'air ait été expulsé de la lingotière, à un point tel que la concentration de l'oxygène dans la lingotière ne soit pas supérieure à 1 % en volume. L'injection de gaz est prolongée jusqu'à un instant précédant immédiatement la coulée dans cette lingotière, ceci pour tenir compte de la fuite de gaz entre la lingotière et son intercalaire.Just before casting, each mold is purged using carbon dioxide gas, at a rate of 2.8 cubic meters per minute, to expel the air from inside the mold. The air is expelled from the interior of the ingot mold by the carbon dioxide purge at a flow rate of 2265 to 2832 liters / minute (80 to 100 sefm standard cubic foot minute), for approximately 3 minutes before the casting of each ingot . A rubber hose with asbestos protective coating is introduced into the mold, through the aluminum film, so that the diffuser plunges as low as possible, as shown in Figure 2. The gas flow is extended to the air has been expelled from the mold, to such an extent that the concentration of oxygen in the mold does not exceed 1% by volume. The gas injection is extended to an instant immediately preceding the pouring into this ingot mold, this to take account of the gas leak between the ingot mold and its interlayer.

Pendant que l'acier se trouve dans le four, on prépare les lingotières pour la coulée selon la procédure suivante. On projète un fort jet d'air comprimé sur l'intercalaire pour en éliminer les éventuelles particules libres. On applique ensuite sur l'intercalaire une enduction composée d'une dispersion de ciment dans l'acide phosphorique dilué. On place quatre bandes de tôle d'acier ondulé d'environ 150 mm x 750 mm 1,6 mm sur l'intercalaire, en carré ou en rectangle. Lorsque la lingotière est placée en position, son poids a écrasé les ondulations pour réduire ainsi les risques de fuites de l'acier liquide (voir détail sur la figure 2).While the steel is in the oven, the molds are prepared for casting according to the following procedure. A strong jet of compressed air is projected onto the interlayer to remove any free particles from it. A coating composed of a dispersion of cement in dilute phosphoric acid is then applied to the interlayer. Four strips of corrugated steel sheet of approximately 150 mm x 750 mm 1.6 mm are placed on the interlayer, in a square or a rectangle. When the mold is placed in position, its weight has crushed the corrugations to reduce the risk of leakage of the liquid steel (see detail in Figure 2).

On place sur l'intercalaire, à l'intérieur de la lingotière, une cheminée de forme oblongue, faite de tôle d'acier mince, mesurant environ 500 mm x 1 000 mm x 1 250 mm, pour réduire l'intensité des projections au moment du début de la coulée de métal liquide dans la lingotière. On fixe des "planches" exothermiques (rehausses chaudes ou "hot tops"), sur l'extrémité supérieure 12' de la surface interne de la lingotière, ces planches engendrant de la chaleur en entrant en contact avec l'acier liquide, ceci pour ralentir le refroidissement à la partie du lingot, et pour réduire de cette façon la profondeur de la retassure formée dans la partie supérieure de ce lingot et qui doit être coupée avant le laminage consécutif. On place un chapeau en pellicule d'aluminium mince sur la partie supérieure de la lingotière pour limiter l'exposition à l'atmosphère avant que la lingotière n'ait été purgée au moyen d'anhydride carbonique.On the insert, inside the mold, an oblong chimney, made of thin sheet steel, measuring approximately 500 mm x 1,000 mm x 1,250 mm, to reduce the intensity of projections to the time of the start of the pouring of liquid metal into the ingot mold. Exothermic "boards" are fixed (hot elevations or "hot tops"), on the upper end 12 ′ of the internal surface of the ingot mold, these boards generating heat by coming into contact with the liquid steel, this for to slow the cooling at the part of the ingot, and to thereby reduce the depth of the recess formed in the upper part of this ingot and which must be cut before the subsequent rolling. A thin aluminum foil cap is placed over the top of the mold to limit exposure to the atmosphere before the mold has been purged with carbon dioxide.

Au début de la coulée, l'acier liquide perfore un petit trou dans la feuille mince d'aluminium en réduisant ainsi la quantité d'air ambiant qui est attiré dans le moule. La température de l'acier du courant est de 1 625 °C à 1 650 °C. Pendant le remplissage de chaque lingotière, il se forme un écran d'anhydride carbonique à proximité de la source du courant, c'est-à-dire juste au-dessous du bas de la poche, sous la busette. L'écran formé autour du courant d'acier liquide est entraîné avec l'acier et forme un écran protecteur isolant de l'atmosphère depuis l'instant où l'acier quitte la busette jusqu'à son impact dans la lingotière. Le débit d'anhydride carbonique envoyé à l'écran est de 2,8 mètres cubes par minute.At the start of casting, the liquid steel punctures a small hole in the thin aluminum sheet, thereby reducing the amount of ambient air that is drawn into the mold. The temperature of the current steel is from 1,625 ° C to 1,650 ° C. During the filling of each ingot mold, a carbon dioxide screen forms near the source of the current, that is to say just below the bottom of the pocket, under the nozzle. The screen formed around the current of liquid steel is entrained with the steel and forms a protective screen insulating from the atmosphere from the moment the steel leaves the nozzle until its impact in the mold. The carbon dioxide flow rate sent to the screen is 2.8 cubic meters per minute.

La poche contenant les 50 tonnes d'acier est positionnée au-dessus de l a première lingotière, déjà purgée et le débit de gaz d'écran est mis en action. Le tuyau de purge a précédemment été transféré à la deuxième lingotière sans interrompre l'écoulement du gaz.The pocket containing the 50 tonnes of steel is positioned above the first ingot mold, already purged and the flow of screen gas is put into action. The purge pipe was previously transferred to the second ingot mold without interrupting the flow of gas.

La vanne est ouverte pour commencer la coulée (voir figure 4). A certains moments, la busette est bouchée par du métal solidifié ou par du laitier. Dans chaque cas, il est nécessaire d'injecter de l'oxygène à la lance pour dégager la busette (voir figure 4).The valve is open to start casting (see Figure 4). At times, the nozzle is blocked by solidified metal or by slag. In each case, it is necessary to inject oxygen to the lance to clear the nozzle (see Figure 4).

Bien que l'anhydride carbonique soit fourni sous la forme liquide, on utilise du CO₂ gazeux aux deux points d'injection (purge et formation d'un écran). On utilise donc un dispositif qui possède une capacité de vaporisation pour fournir un débit comparable à celui d'un gaz inerte, par exemple de l'argon. La composition de l'alimentation en CO₂ est représentée sur la figure 5.Although carbon dioxide is supplied in liquid form, CO₂ gas is used at the two injection points (purging and forming a screen). A device is therefore used which has a vaporization capacity to provide a flow rate comparable to that of an inert gas, for example argon. The composition of the CO₂ supply is shown in Figure 5.

C'est le premier lingot qui demande le moins de temps pour la coulée, puisque la pression statique du métal décroît progressivement au cours de la coulée. En environ 3 minutes, la lingotière est remplie et la vanne est fermée (pour environ 20 à 30 secondes) pendant que l'opérateur du pont roulant positionne la poche au-dessus de la deuxième lingotière. Pendant ce temps, le tuyau de gaz de purge est transféré à la lingotière suivante puis la vanne est ouverte à nouveau pour remplir la lingotière qui vient d'être purgée. La séquence est poursuivie jusqu'à ce que la poche soit vidée de sa charge de métal.It is the first ingot that requires the least time for casting, since the static pressure of the metal gradually decreases with during casting. In approximately 3 minutes, the ingot mold is filled and the valve is closed (for approximately 20 to 30 seconds) while the crane operator positions the pocket above the second ingot mold. During this time, the purge gas pipe is transferred to the next ingot mold and the valve is opened again to fill the mold that has just been purged. The sequence is continued until the pocket is emptied of its metal charge.

On laisse la charge contenue dans chaque lingotière se refroidir, de la façon classique, avec une couche de flux protecteur sur sa surface, de manière à former un lingot solide. Les lingotières sont ensuite vidées de leurs lingots.The charge contained in each ingot mold is allowed to cool, in the conventional manner, with a layer of protective flux on its surface, so as to form a solid ingot. The ingot molds are then emptied of their ingots.

Chaque lingot est laminé à chaud en un feuillard, selon la pratique standard, puis soumis à un contrôle aux ultrasons pour la détection des défauts de surface. Le feuillard acceptable a été ensuite laminé en une tôle et la tôle a été ensuite transformée en un tube soudé en hélice. Le tube a été ensuite soumis à un contrôle aux ultrasons pour la détection des défauts.Each ingot is hot rolled into a strip, according to standard practice, then subjected to ultrasonic control for the detection of surface defects. The acceptable strip was then rolled into a sheet and the sheet was then made into a helically welded tube. The tube was then subjected to ultrasonic testing for fault detection.

Des chauffes témoins ont été ensuite exécutées d'une façon identique.Control heaters were then performed in an identical fashion.

Au cours de l'ensemble de l'opération de coulée en lingotière, le débit de gaz était de 2,8 mètres cubes par minute dans le cas de l'anhydride carbonique et de 2,8 mètres cubes par minute dans le cas de l'argon. Chaque lingotière a été purgée pendant environ 2 minutes et le courant de métal liquide a été protégé pendant toute la durée de l'opération de coulée, d'environ 25 minutes.During the entire mold casting operation, the gas flow rate was 2.8 cubic meters per minute in the case of carbon dioxide and 2.8 cubic meters per minute in the case of l 'argon. Each mold was purged for approximately 2 minutes and the stream of liquid metal was protected for the duration of the casting operation, approximately 25 minutes.

Une comparaison des résultats est donnée ci-après en termes de défauts de surface sur les feuillards formés par laminage à partir de billettes produites :

Figure imgb0001
A comparison of the results is given below in terms of surface defects on the strips formed by rolling from billets produced:
Figure imgb0001

Défauts détectés par l'effet aux ultrasons sur un tube soudé en hélice :

Figure imgb0002
Faults detected by the ultrasonic effect on a helically welded tube:
Figure imgb0002

Grâce au coût relativement faible de l'anhydride carbonique et à la facilité avec laquelle on peut se le procurer, comparativement, par exemple, à l'argon, et grâce au fait qu'il peut être produit et fourni en continu, ce gaz constitue un gaz extrêmement utile lorsqu'il est utilisé selon l'invention. L'anhydride carbonique est plus lourd que l'air (1,5 : 1) contrairement à l'argon (1,5 : 2) et il maintient donc un écran de protection efficace plus longtemps que les gaz plus légers puisqu'il ne se disperse pas dans l'atmosphère aussi facilement.Thanks to the relatively low cost of carbon dioxide and the ease with which it can be obtained, compared, for example, to argon, and thanks to the fact that it can be produced and supplied continuously, this gas constitutes an extremely useful gas when used according to the invention. Carbon dioxide is heavier than air (1.5: 1) unlike argon (1.5: 2) and therefore it maintains an effective protective screen longer than lighter gases since it does not does not disperse into the atmosphere as easily.

L'anhydride carbonique peut être utilisé sous la forme de neige carbonique pour fournir une forme concentrée de gaz CO₂ pour l'utilisation de la lingotière dans la coulée en lingots ou dans la lingotière d'une installation de coulée continue.Carbon dioxide can be used in the form of carbon dioxide snow to provide a concentrated form of CO₂ gas for the use of the ingot mold in ingot casting or in the ingot mold of a continuous casting installation.

On constate également des résultats comparatifs ci-dessus que l'utilisation d'argon au niveau de l'écran et d'anhydride carbonique pour la purge de la lingotière donne, de manière inattendue, des résultats encore améliorés. Il est clair également à partir de ce s exemples, qu'un mélange d'anhydride carbonique et d'argon, au niveau de l'écran, quelles que soient les proportions, associé à une purge de la lingotière à l'anhydride carbonique, donnera des résultats supérieurs ou égaux à ceux obtenus avec l'anhydride carbonique seul. It is also noted from the above comparative results that the use of argon at the level of the screen and carbon dioxide for purging the ingot mold unexpectedly gives further improved results. It is also clear from these examples, that a mixture of carbon dioxide and argon, at the screen, whatever the proportions, associated with a purging of the mold with carbon dioxide, will give results greater than or equal to those obtained with carbon dioxide alone.

Claims (1)

1. Appareil pour la réalisation d'une protection gazeuse d'un jet de métal fondu coulé d'un récipient supérieur (A) dans un récipient inférieur (B₁), une enveloppe gazeuxe protectrice étant formée autour du jet de métal fondu pour le protéger contre les impuretés de l'atmosphère environnante lors de la coulée du jet de métal dans le récipient inférieur, caractérisé en ce qu'il comporte :
- un récipient supérieur (A) muni d'un système d'ouverture et de fermeture placé à la partie inférieure du récipient, l'ouverture du système permettant la coulée du jet de métal ;
-un récipient inférieur (B₁) muni d'une ouverture pour recevoir le métal coulé lorsque le système d'ouverture et de fermeture est ouvert ;
- des moyens d'injection (15) d'anhydride carbonique gazeux autour du jet de coulée placés dans le premier récipient et entourant le trou de coulée ;
- des moyens d'injection (17) d'anhydride carbonique gazeux dans le récipient inférieur pour assurer sa purge ;
- un réservoir contenant de l'anhydride carbonique sous forme liquide dans sa partie inférieure et sous forme gazeuse dans sa partie supérieure ;
- des moyens pour soutirer de l'anhydride carbonique liquide de la partie inférieure du réservoir, le vaporiser et l'injecter dans la partie supérieure du réservoir afin de remplacer le gaz prélevé ;
- une canalisation placée dans la partie supérieure dudit réservoir pour véhiculer l'anhydride carbonique gazeux vers les moyens d'injection de gaz carbonique autour du jet de coulée et les moyens d'injection de gaz carbonique dans le récipient inférieur ;
- des moyens pour contrôler l'injection d'anhydride carbonique dans le second récipient pour assurer la purge de celui-ci avant la coulée du métal ;
- des moyens pour contrôler l'injection d'anhydride carbonique autour du jet de coulée de métal issu du premier récipient.1. Apparatus for producing a gas protection of a jet of molten metal poured from an upper container (A) into a lower container (B₁), a protective gaseous envelope being formed around the jet of molten metal to protect it against impurities from the surrounding atmosphere when the metal jet is poured into the lower container, characterized in that it comprises:
- an upper container (A) provided with an opening and closing system placed at the lower part of the container, the opening of the system allowing the casting of the metal jet;
-a lower container (B₁) provided with an opening for receiving the cast metal when the opening and closing system is open;
- Means for injecting carbon dioxide gas around the pouring jet placed in the first container and surrounding the tap hole;
- Means for injecting (17) gaseous carbon dioxide into the lower container to ensure its purging;
- a tank containing carbon dioxide in liquid form in its lower part and in gaseous form in its upper part;
- Means for withdrawing liquid carbon dioxide from the lower part of the tank, vaporizing it and injecting it into the upper part of the tank in order to replace the gas withdrawn;
a pipe placed in the upper part of said tank for conveying gaseous carbon dioxide towards the means for injecting carbon dioxide around the pouring jet and the means for injecting carbon dioxide into the lower container;
- Means for controlling the injection of carbon dioxide into the second container to ensure the purging thereof before the metal is poured;
- Means for controlling the injection of carbon dioxide around the metal pouring jet from the first container.
EP87401801A 1984-02-24 1985-02-22 Device for gas-shielding a molten metal jet Expired - Lifetime EP0255450B1 (en)

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Also Published As

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ZA85911B (en) 1985-09-25
JPS60203338A (en) 1985-10-14
AU3904285A (en) 1985-09-05
EP0255450A3 (en) 1988-05-18
ES540622A0 (en) 1985-12-01
EP0154585A2 (en) 1985-09-11
EP0255450B1 (en) 1990-03-28
DE3576792D1 (en) 1990-05-03
ES8602460A1 (en) 1985-12-01
EP0154585A3 (en) 1986-02-26
US4614216A (en) 1986-09-30
AU573779B2 (en) 1988-06-23
ATE51352T1 (en) 1990-04-15

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