RU2532584C1 - Method for complex treatment of liquid metal in ladle-furnace unit - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to metallurgy, and namely to a method of complex out-of-furnace treatment of liquid steel in a ladle with inert gases. Electric-arc heating of metal with slag is performed with three hollow electrodes installed in the centre of the ladle-furnace unit arch, blowing and mixing of metal is performed at its surface and at the bottom at the bottom surface with inert gases supplied through holes made in hollow electrodes and through the device to the ladle bottom respectively. In addition, blowing and mixing of metal with inert gases is performed in the centre of the ladle volume by means of a lined tuyere with a protective cone, which is fixed on the ladle housing and arranged opposite the device for supply of inert gas to the ladle bottom; with that, blowing of metal with inert gases through the lined tuyere with the protective cone is performed simultaneously or separately with blowing through holes made in hollow electrodes and the device at the ladle bottom.

EFFECT: invention provides for intense mixing of liquid metal with gas flows in three horizons of the ladle, which allows achieving higher homogenisation of the melt as to composition and temperature, intensifying degassing of metal and removing non-metallic inclusions from it, and cooling degree of liquid metal from inert gases blown into it is controlled by electric-arc heating of metal and slag, which allows sufficient improvement of quality of the obtained metal goods.

4 cl, 1 dwg

Description

The invention relates to the field of metallurgy, and more particularly to a method for the out-of-furnace treatment of molten steel in a ladle with inert gases (argon, nitrogen, etc.) using electric arc heating of metal and slag [1] under a water-cooled arch with three electrodes from a furnace transformer. In the arch above the bucket there are three holes for the passage of electrodes and a hole for loading bulk materials from bunkers with weighing devices, and also provides [1] the supply of inert gases and oxygen for refining liquid metal using a workshop computer.

A known method of processing liquid metal in a bucket [2] using a lined lance and a device for supplying argon or nitrogen from below through the bottom of the bucket [3].

When liquid steel is purged with inert gases in a ladle through a lance with a protective cone [2, 4] or through the device nozzles in the ladle bottom [3], a bare part of the metal surface from slag [4] is formed on the surface of the blown metal, which is a disadvantage of the known methods of out-of-furnace treatment steel [1, 2] in the ladle-furnace assemblies.

To eliminate these drawbacks when using a lined lance, inert gas (nitrogen or argon) is supplied through nozzles under the protection cone [2, 4] to the exposed metal surface in the slag region, and to provide a more dispersed supply of inert gases to the volume of liquid metal in the ladle, a supply inert gases not only through the lance with a cone [2] and the device in the bottom of the bucket [1, 4], but also through the axial holes in the three hollow electrodes [3] installed in the arch above the bucket.

Closest to the invention is a method [5] of treating metal with inert gases in a ladle-furnace assembly by blowing liquid metal through the bottom of a ladle and slag through openings in hollow electrodes. This method is complemented by another method [3] of out-of-furnace treatment of liquid steel with inert gases based on the use of a lined lance with conical protection.

However, all of the above methods have major drawbacks in the fact that in the ladle-furnace assemblies, there is no simultaneous sharing of the methods of purging liquid metal with inert gases through the bottom of the bucket and the holes in the hollow electrodes, as well as when using a lined lance with a protection cone. All this does not allow to achieve high rates of refining liquid steel from gases (oxygen, hydrogen, etc.) and non-metallic inclusions (Al ₃ O ₃ , TiO ₂ , SiO ₂ , etc.), and also does not provide a high degree of metal desulfurization at the interface slag-metal with heated melt from electric arcs at the ends of the electrodes of the furnace installation.

The purpose of the invention is the elimination of these drawbacks and increasing the efficiency of out-of-furnace treatment of liquid metal in ladle-furnace assemblies when using the complex of the above methods of feeding inert gases through the ladle bottom, lance and hollow electrodes in the roof of the unit in the ladle.

The technical result of the invention, including flushing liquid metal in the bucket with inert gas flows, from below using a device in the bottom of the bucket and through axial holes in hollow electrodes installed in the vault of the unit allows intensive mixing of liquid metal with gas flows in three horizons of the bucket, i.e. below the surface of the bottom of the bucket, in the middle of the volume of the bucket and above the surface of the metal or on the surface of the slag-metal interface. Intensive mixing and movement of metal layers at different ladle horizons allows achieving higher melt homogenization in composition and temperature, intensifying metal degassing and removal of non-metallic inclusions from it, and the degree of cooling of liquid metal from inert gases blown into it is regulated by electric-arc heating of metal and slag in the aggregate ladle furnace.

The technical result is achieved as follows.

The method of complex processing of liquid metal in a ladle-furnace assembly, including electric arc heating of metal with slag by three hollow electrodes installed in the aggregate vault, purging and mixing the metal with inert gases supplied through openings in the hollow electrodes and a device installed in the bottom of the bucket, characterized in that purging and mixing with inert gases from above at the metal surface or at the slag-metal interface is carried out by a lined lance with a protective cone mounted on the bucket body and placed opposite the device in the bottom of the bucket, while three hollow electrodes are located in the center of the arch in the volume of the bucket in the space between the mentioned lance and the device and simultaneously or separately purge the metal with inert gases through the holes in the hollow electrodes, the device in the bottom of the bucket and a lined lance with a protective cone.

Inert gas purging through openings in three hollow electrodes is carried out separately or together with the supply of bulk materials to the area of electric arcs.

When a metal is flushed with inert gases through a lined lance, inert gases are simultaneously supplied through nozzles in the protective cone of the lined lance to slag and metal around the lance.

The inert gas costs are coordinated with the rate of electric arc heating of the metal and slag in the ladle.

The proposed method, which has a significant difference from the prototype [5], is carried out as follows in accordance with the scheme (see drawing).

After the release of liquid steel from, for example, an arc furnace in a ladle (1), the latter is sent to a ladle-furnace assembly stand. At the stand, the bucket with the device in the bottom of the bucket (2), liquid metal (3), and slag (4) is covered with a vault (5) and the electrodes (7) are lowered using the electrode holder (6) with the inclusion of electricity to electrically heat the metal (3) and slag (4) in the bucket (1). Through hollow electrodes (7), it seems possible to supply an inert gas (8) and bulk materials into the zone of electric arcs (9) to slag (4) and liquid metal (3). The heating of metal and slag by electric arcs (9) is carried out simultaneously with the supply of inert gases (8), the flow rate of which is regulated and carried out continuously or periodically in accordance with the requirements of the out-of-furnace treatment technology for liquid steel. Moreover, in the bucket, liquid metal (10) is purged with inert gases (argon or nitrogen) through a lined lance (11) fixed permanently to the bucket body (12). The lance (11) in its upper part has a protective metal cone (13) with nozzles for supplying jets of inert gas to the slag and metal around the lance (11). To purge the metal through the hole (14), an inert gas (10) is fed into the lance to mix the melt with jets of gas (15) above the bottom of the bucket (16). In FIG. areas (A, B, C) of the predominant effect of inert gas flows on the volumes of liquid metal in the ladle are presented.

Moreover, the proposed method for processing liquid metal in a ladle-furnace assembly, including electric arc heating of metal with slag by three hollow electrodes, purging metal with inert gases through a device in the bottom of the bucket and a lined lance with a protective cone, is characterized in that the lined lance with a protective cone is fixed to the bucket’s body and placed opposite the device in the bottom of the bucket, and three hollow electrodes are located in the center of the arch in the space between them in the volume of the bucket, where they perform simultaneous or separate battening purge inert gases molten metal through the openings in the hollow electrodes, as well as through the device and the lined ladle bottom tuyere with a protective cone.

The method is characterized in that the inert gas purge through openings in three hollow electrodes is carried out jointly or separately with the supply of bulk materials in inert gas streams.

The method is characterized in that when inert gas is blown through the lined lance, inert gases are simultaneously fed over the slag and metal through nozzles in the lance's protective cone.

The method is characterized in that the metal is purged with inert gases both through three hollow electrodes, and in turn with each of them.

The efficiency of out-of-furnace metal processing in the ladle-furnace assembly [3, 4] in comparison with the prototype [5] increases significantly during the implementation of controlled dispersed melt blowing with inert gases.

The economic effect is ensured by accelerating the processes of mixing the metal in zones A, B and C, intensifying the degassing of the metal and removing non-metallic inclusions, which leads to a decrease in the duration of the mode of purging the melt in the ladle, reducing the specific energy consumption and improving the quality indicators of cast billets.

Bibliography

1. Electrical and structural features of the NSC ladle furnace installation. (Transl. From English), 1988 - p. 1129-1133. Ref. VINITI magazine. 15. Metallurgy. 15. B. Production of cast iron and steel No. 11, 1989 - p.64 (11 B491).

2. Merker E.E. et al. Rospatent, (19) RU (11) 20092090 (51) ⁵ C21C 7/072. BI No. 5, 1994. A method for nitriding liquid steel in a ladle.

3. Agapitov E.B. The development of a control system for an electric arc furnace ladle in order to increase heating // Izv. Universities. Electromechanics. 2006 - No. 4 - p. 81-84.

4. Merker E.E. and others. Patent RU No. 2369644 C2 on the application 2005130959/02 from 05.10.2005. Publ. 10/10/2009. Bull. No. 28. A method for nitriding liquid steel in a ladle.

5. Bigeev et al. Patent for utility model 62048 of the Russian Federation, IPC C21C 7/00. Installation of a ladle furnace. Application No. 2006138419/22 of 10.30.2006; Publ. 03/27/2007, BIMP No. 9, p. 597.

Claims (4)

1. A method of complex processing of liquid metal in a ladle-furnace assembly, including electric arc heating of metal with slag by three hollow electrodes installed in the center of the ladle-furnace vault, purging and stirring the metal at its surface and at the bottom at the bottom surface with inert gases supplied through openings in hollow electrodes, and through a device in the bottom of the bucket, respectively, characterized in that they further purge and mix the metal with inert gases in the middle of the bucket volume using a footer a bath lance with a protective cone mounted on the bucket body and placed opposite the inert gas supply device to the bottom of the bucket, while the metal is flushed with inert gases through a lined lance with a protective cone, carried out simultaneously or separately with blowing through openings in the hollow electrodes and the device in the bucket bottom . 2. The method according to claim 1, characterized in that the metal is purged with inert gases through openings in three hollow electrodes separately or together with the supply of bulk materials to the area of electric arcs. 3. The method according to claim 1, characterized in that when purging the metal with inert gases through the lined lance, inert gases are simultaneously fed to the slag through nozzles in the protective cone of the lined lance. 4. The method according to claim 1, characterized in that the inert gas flow rate is controlled in accordance with the electric-arc heating of metal and slag in the ladle.

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