EP2055411A1 - Method and device for continuous casting of steel - Google Patents

Abstract

An assembly for the continuous casting of free cutting steel has a distributor (2) with an outlet (4), an ingot mould and a submerged tube (5) with an outlet to the ingot mould. The assembly has an additive injector (8) to the liquid steel in the tube (5) or outlet (4). Also claimed is a commensurate process in which an injector discharges solid or granular additives. The additives are expelled by inert gas e.g. Ar and/or N2 pressure at 20 to 50 mbar through a Laval jet at 7 to 13 m/s. The granule diameter is in the range 0.5 to 1 mm and incorporate materials from the periodic table: Pb, S, Ti, Ca, Zr, Ce, Bi, B, Te, Be, Se and P. The rate at which the additive is expelled is adjustable to vary the concentration within liquid steel.

Description

The invention relates to a device and a method for the continuous casting of steel and steel strands produced by the method.

A considerable part of steel production, in particular so-called free-cutting steel optimized for machining on automated machine tools, is produced by continuous casting. Free-cutting steels are usually optimized for automatic cutting by additives such as lead and / or sulfur. These aggregates form soft inclusions where chips can break. Furthermore, the easily fusible lead inclusions, together with possibly used in the machining machining coolants form a lubricant layer, which reduces tool wear.

The invention has for its object to provide a device and a method for introducing appropriate additives available that allow a good manageable and environmentally friendly introduction of appropriate additives.

The inventive apparatus for continuous casting of steel has a distributor with a spout and a mold and a dip tube for casting the steel in the mold. According to the invention, it is provided that an injector device is provided for feeding aggregates in the flowing through the spout or dip tube steel beam.

First, some terms used in the invention are explained.

Devices for continuous casting of steel such as conventional continuous casting plants are familiar to the expert and require no further explanation.

The term distributor refers to a storage vessel for liquid steel from which the casting molds are fed. As a rule, a distributor feeds several dies, but this is not mandatory in the context of the invention. The distributor has at least one spout, from which the steel is poured into the mold by means of a dip tube.

The term mold designates the casting mold for continuous casting of a steel strand. The dip tube dives with its outlet end into the molten steel in the mold. Immersion tube and spout of the manifold can be separate components, but they can also be combined to form a so-called mono-dipleg.

According to the invention, it is provided that an injector device for feeding additives into the steel jet flowing through the spout or the dip tube is provided. The aggregates are thus given neither before the continuous casting in the distributor or in the ladle, with which the distributor is filled, nor they are supplied only after the entry of the steel into the mold of this mold. Instead, the introduction takes place in the flowing steel jet in the area between distributor and mold, ie in the tube of the spout, the dip tube or possibly the mono dip tube.

The invention enables a very precise dosing of such additives that tend to segregation, for example, in a steel bath. As already explained above, lead is a common lubricant for improving the processability of free-cutting steels. In the prior art, the lead is usually supplied to the molten steel in the ladle furnace or the rinsing station. Lead has a much higher density than steel, so there is a strong tendency to segregation (segregation). Therefore, towards the end of the casting process, the lead content of the then cast steel remainder may drop, so that part of the melt no longer has the desired composition.

Furthermore, lead is very fluid at the high temperatures of molten steel and can penetrate fine gaps and crevices of the refractory lining of the ladle and manifold. Durability and reliability of these facilities are reduced. Lead-contaminated ladles and casting spreaders can no longer be used to make steel without the addition of lead. Furthermore, for environmental reasons, the disposal of lead-containing slag and contaminated with lead refractory breaking material consuming and expensive. In addition, during the alloying process of lead-added steel, special systems for evacuating lead vapors must be used. All of these disadvantages are avoided by the present invention. The feeding of the aggregates into the spout or dip tube and there directly into the flowing steel stream avoids that ladle and pouring spreader ever come into contact with aggregates such as lead. The dosage by means of injection device into the flowing steel jet allows a very fast homogeneous distribution by the dynamic mixing into the flowing steel. Since immediately after the injector device, the steel jet exits from the dip tube into the mold and solidifies there, it can not come after the introduction of aggregates or at best to a lesser extent segregation phenomena such segregation.

The inventively provided dynamic mixing in the flowing steel beam also has the great advantage that the type and amount of introduced aggregates can be changed during the casting. Suitable applications for this will be described below.

The invention also avoids problems due to the dynamic introduction into the flowing steel jet which could result from the fundamentally conceivable introduction of the aggregate material directly into the mold. An introduction directly into the already existing in the mold steel bath would make a homogeneous mixing difficult to impossible.

The injector device is preferably designed for supplying solid additives, more preferably granular additives. It can be provided that the additives are supplied by means of a propellant gas. The propellant gas is preferably not injected into the molten steel, but by means of a corresponding device (vacuum pump) before the addition of aggregates in the molten steel withdrawn again. In the context of the invention, the injector device may have a Laval nozzle.

The invention further provides a method for feeding additives to liquid steel during the continuous casting of steel. According to the invention, the feeding by means of an injector device takes place in the steel jet flowing through the spout of the distributor or the dip tube.

In the context of the invention, the term injector device means any device which allows the introduction of the additives (preferably from the side, ie substantially transversely to the flow direction) in the flowing steel jet.

As already described above in the context of the device according to the invention, solid, in particular granular, additives are preferably used in the context of the method.

The average particle size of the additives is preferably 0.3 to 2 mm, more preferably 0.4 to 1.5 mm, more preferably 0.5 to 1 mm. For example, lead is preferably introduced as an additive as particles or particles of a size of 0.5 to 1 mm, more preferably 0.6 to 1 mm. Such lead particles can be prepared, for example, simply by pouring a lead melt in water. Lead balls of such size can be injected into and penetrate the flowing steel jet. Due to the low melting temperature of lead, they melt in a very short time and spread even further the exit of the steel jet from the dip tube substantially homogeneous in the molten steel.

The additives may, for example, be selected from the group consisting of Pb, S, Ti, Ca, Zr, Ce, Bi, B, Te, Be, Se and P.

The additives can be introduced either elementally, for example, elemental lead, sulfur or the like, or in the form of suitable compounds such as oxides, carbonates or the like. Within the scope of the invention, the following quantities of aggregates are preferred. The percentages given are percentages by weight. lead 0.15-0,3% sulfur 0.15-0.3% titanium 0.03-0.05% calcium 0.03-0.05% zircon 0.03-0.05% cerium 0.03-0.05% bismuth 0.03-0.05% boron 0.002 to 0.009% tellurium 0.04-0.05% beryllium 0.03-0.06 selenium 0.04-0.05% phosphorus 0.05-0.1

The stated percentages relate in each case to the elemental additive and may have to be converted if this is introduced in the form of a compound such as an oxide or the like.

In particular solid aggregates can be supplied by means of a propellant gas. As the propellant gas, an inert gas is preferably used. The term inert gas refers to any gas which under the conditions of the process Aggregate and possibly the molten steel from unwanted external influences, in particular the access of atmospheric oxygen protects. For example, the propellant may contain a noble gas such as argon, and may also contain nitrogen, for example. Preferably, the propellant gas is not injected into the steel jet, but withdrawn before the addition of aggregates in the steel beam by means of a suitable device such as a vacuum pump again. In this case, the propellant gas pressure can be metered so that an overpressure of preferably 10 to 100 mbar, more preferably 15 to 70 mbar, more preferably 20 to 50 mbar is set above the ambient pressure in the dip tube. Such a slight overpressure also prevents or reduces the access of atmospheric oxygen from the environment in the area of the dipping tube outlet in the mold or at the connection point of the spout and dip tube.

The aggregates are preferably accelerated in the injector device so that they have a speed of 2 to 20 m / s, preferably 3 to 15 m / s, more preferably 7 to 13 m / s when hitting the flowing steel jet. For lead balls with a diameter of 0.6 to 1 mm, for example, a speed of 7 to 13 m / s, in particular about 10 m / s, particularly preferred. With this speed fed lead balls can penetrate with a flowing steel beam of about 16 to 20 mm diameter and a flow rate of 30 mm / s to about the middle of the steel beam are melted there and by the dynamic effects in the flowing steel jet to the exit from the dip tube end evenly distributed in steel. It is preferred that the dip tube exits from the injection site to the dip tube still about a length of 300 to 700 mm, preferably 500 mm so as to allow a homogeneous distribution in the steel.

In the context of the invention, it is possible to change the amount of the additives supplied to the steel during continuous casting. Thus, different concentrations of aggregates can be adjusted in different lengths of a steel strand.

Optimized steel strips (also called steel billets) optimized for machining cutting steel have optimized lead and / or sulfur contents for machining. These surcharges, however, cause the beginning or the tip of a billet when entering the rolling stands are easily split. In the prior art, it is therefore often necessary to sharpen the leading end of such a billet.

According to the invention, it is now possible to provide a steel strand or steel billet produced by the continuous casting process, which has a concentration of additives which varies over its length. In particular, it is preferred that it has at least one end portion (preferably the leading end) in which the concentration of the additives, in particular the already mentioned additives lead and / or sulfur is less than in other lengths or in the entire remaining length of the steel strand. The steel billet then has in its tip on a lower lead and / or sulfur content, thus has a lower tendency to cleavage and does not have to be sharpened as in the prior art. The corresponding leading end may in particular have a length of 10 to 50 cm, more preferably 20 to 40 cm, for example, about 30 cm. The steel billet in total may have a length of, for example, 3 to 20 m.

In the context of the invention, it is likewise possible to introduce a plurality of different additives either simultaneously through an injector device or sequentially through a plurality of injector devices distributed over the length of the spout and / or dip tube. An embodiment will be described below with reference to the drawings. Show: Fig. 1 schematically a section of a continuous casting plant according to the invention; Fig.2 a detailed view FIG. 1 , From a ladle 1, molten steel is poured into a distributor 2. The distributor 2 distributes the molten steel to a plurality of molds 3, only one of which is shown in the drawing.

The distributor 2 has a spout 4, which opens into a dip tube 5. In the context of the invention, the spout 4 and the dip tube 5 may also be formed as a one-piece so-called monotube. The dip tube 5 extends to below the Stahlbadspiegel the mold. 3

Lead balls with an average diameter of about 1 mm are supplied from an injection system 6 via a delivery line 7 to a nozzle 8. The supply takes place by means of argon as propellant gas. Within the nozzle 8, the lead first emerges together with the propellant gas from a Laval nozzle 13. At the Outlet of this nozzle is accelerated to a speed of about 10 m / s. With this speed, it passes through the connecting line 14 and enters within the spout 4 in the steel beam. Within the steel, the lead balls melt immediately and are mixed homogeneously by the dynamic effects in the flowing steel immediately, so that at the outlet of the dip tube 5 is a homogeneous alloy.

The propellant gas is sucked behind the outlet of the Laval nozzle 13 through a suction line 9 by means of a vacuum blower 12. By means of a pressure measuring line 10 and a pressure regulating valve 11, a constant pressure is set in the suction line 9. Desirable is usually an overpressure between 10 and 50 mbar.

The pouring stream in the spout 4 and dip tube 5 is in this embodiment between 16 and 20 mm. At a flow rate of the steel of 30 mm / s, a usual addition requires an injection of about 3000 lead balls / s a 1 mm diameter.

According to the invention, it is possible to handle lead substantially completely without lead fumes being able to enter the environment. Furthermore, it is possible to change the dosage of lead or other additives during casting. In this way, it is possible, for example, to produce steel billets whose initial region contains a lower lead content or no additives supplied in this way at all.

Claims (21)

Apparatus for the continuous casting of steel, comprising a distributor (2) having a spout (4), a mold (3) and a dip tube (5) for casting
of the steel into the mold (3), characterized in that an injector device (8) for supplying additives in the through the spout (4) or the dip tube (5) flowing steel beam is provided. Device according to claim 1, characterized in that
in that the injector device (8) is designed to supply solid aggregates. Device according to claim 2, characterized in that
in that the injector device (8) is designed to supply granulated additives. Device according to one of claims 1 to 3, characterized in that the additives are supplied by means of a propellant gas. Device according to claim 4, characterized in that
in that a device (9, 12) for removing the propellant gas prior to the exit of the additives from the nozzle of the injector device (8) is provided. Device according to one of claims 1 to 5, characterized in that the injector device comprises a Laval nozzle (13). Process for feeding additives to liquid steel in the course of continuous casting, characterized
by feeding by means of an injector device (8) into the steel jet flowing through the spout (4) of the distributor (2) or the dip tube (5). Method according to claim 7, characterized in that
that the aggregates are solid. Method according to claim 8, characterized in that
that the aggregates are grained. Method according to claim 8, characterized in that
The average particle size of the aggregates from 0.3 to 2 mm, preferably 0.4 to 1.5 mm more preferably from 0.5 to 1 mm. Method according to one of claims 7 to 10, characterized
in that the additives are selected from the group consisting of Pb, S, Ti, Ca, Zr, Ce, Bi, B, Te, Be, Se and P. Method according to one of claims 7 to 11, characterized
characterized in that the additives are supplied by means of a propellant gas. Method according to claim 12, characterized in that
that the propellant gas is an inert gas. Method according to claim 13, characterized in that
that the propellant gas Ar and / or N ₂ contains. Method according to one of claims 7 to 14, characterized
characterized in that the additives from the injector device (8) at a speed of 2 to 20 m / s, preferably 3 to 15 m / s, more preferably 7 to 13 m / s. Method according to one of claims 7 to 15, characterized
characterized in that in the dip tube (5) an overpressure of 10 to 100 mbar, preferably 15 to 70 mbar, more preferably 20 to 50 mbar is set. Method according to one of claims 7 to 16, characterized
characterized in that the amount of the additives supplied to the steel is changed during the continuous casting. Continuously cast steel strand,
characterized in that it has a variable over its length concentration of aggregates. Steel strand according to claim 18, characterized
in that it has at least one end section in which the concentration of the aggregates Pb and / or S is less than in the remaining lengths of the steel strand. Steel strand according to claim 19, characterized
that has at least one end portion of a length of 10 to 50 cm, preferably 20 to 40 cm. Steel strand according to one of claims 7 to 16,
characterized in that it has a length of 4 to 20 m, preferably 5 to 15 m, more preferably 6 to 10 m.

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