EP3757234A1 - Converter and method for fresh molten metal - Google Patents

Abstract

The invention relates to a converter for refining molten metal, in particular an iron or steel melt, comprising a converter vessel as well as at least one top lance and at least two side wall nozzles arranged in the side wall of the converter vessel, characterized in that the side wall nozzles are designed and arranged so that through them a substantially opposing flow of process gas can be generated into the converter vessel and a method for controlling and / or regulating the fresh process with special consideration of the states at the beginning of the decarburization process. The invention further relates to a method for controlling the decarburization process of a metallic melt in a metallurgical reactor, preferably a converter according to the invention.

Description

1. Field of invention

The invention relates to a converter for refining molten metal, in particular an iron or steel melt, comprising a converter vessel and at least one top lance and at least two side wall nozzles arranged in the side wall of the converter vessel. The invention also relates to a method for controlling the decarburization process of a metallic melt in a metallurgical reactor, preferably a converter.

2 . State of the art

The Linz-Donauwitz (LD) process is a steelmaking process in which oxygen is blown onto a surface of a carbon-rich (crude) iron melt in a converter. The design and construction of the converter as a suitable metallurgical reactor are known from the prior art (e.g. GB 1 276 029 ). At the beginning of the process, the molten iron is poured into the converter. For the decarburization process, oxygen is blown onto the bath surface through a usually water-cooled lance under high pressure and supersonic. The lance typically has one or more nozzles. In addition, an injection device can also have additional side wall nozzles and / or floor nozzles. An injection device consisting of a lance, bottom nozzles and side wall nozzles is for example in the EP 0 030 360 described.

Before the start of the process, but also under certain circumstances while the process is running, lime and / or other slag formers can be fed to the converter in pieces or blown into the converter as a powder. The slag thus formed has the task of absorbing unwanted accompanying elements in oxidized form and the Protect refractory lining. For this purpose, an emulsion of slag and steel is generated with the help of the injection device. The oxygen reacts in a multi-stage reaction with the carbon dissolved in the iron melt to form carbon monoxide (CO) and / or carbon dioxide (CO ₂ ), thereby reducing the carbon content in the iron melt. A possible intermediate product in the reaction chain is, for example, iron oxide (FeO).

The control of the fresh process, in particular the decarburization rate, and the system control are typically carried out using known automation technology. Empirical models are usually used to describe the chemical reactions that take place. Intervention in the fresh process is normally done by adjusting the distance between the lance tip and the bath surface.

However, the methods known from the prior art have the disadvantage that the control of the decarburization speed in the early phase of the fresh process is not sufficiently flexible. Since the converter cannot have ideal mixing and / or temperature distributions, reaction kinetic effects can dominate the decarburization speed and thus cause unwanted ejection or foaming of molten iron and / or slag. An increase in the mixing intensity that is desired if necessary has previously been achieved by lowering the lance tip. The lowering of the lance tip also leads to an undesired increase in the decarburization speed in the area of influence of the lance tip. The decarburization reaction removes the iron oxide necessary for a reactive slag from the slag too early in the process.

3 . Object of the invention

It was therefore an object of the invention to provide an apparatus and a method that make it possible to reduce the mixing intensity within the Converter with simple means and without significant influence on the decarburization reaction and thereby avoid reaction kinetic effects.

This object is achieved by a converter with the features of claim 1 and by the method with the features of claim 7. Advantageous embodiments of the invention are set out both in the respective dependent subclaims and in the following description of the invention.

4th Summary of the invention

According to a first aspect of the invention, a converter is provided which is designed for refining molten metal, in particular an iron or steel melt. This converter has a converter vessel and at least one top lance and at least two side wall nozzles arranged in the side wall of the converter. According to the invention, the side wall nozzles are designed and arranged in such a way that they generate a flow of process gas into the converter vessel that is essentially countercurrent to one another.

The converter vessel has a typical design that resembles an inverted bell with a tapering neck. The base of the converter vessel is usually round and forms the basis for a circumferential side wall. A top lance for blowing a process gas onto the molten metal and slag inside the converter vessel can be guided through the neck of the converter vessel. The interior of the converter vessel, in turn, is lined with a fire-resistant brick lining to protect the metal outer skin. The design of the converter vessel and the lining are selected in such a way that an amount and, consequently, filling level of molten metal and slag are appropriate for the design and lining can be included. Neither falling below nor exceeding this nominal amount for each converter vessel is desired; accordingly, the lining, the design and the arrangement of the top lance and other nozzles provided for the supply of process gases can be specifically tailored to the bath level for both the molten metal and the slag .

According to the invention, process gas is added not only via the top lance, but also via side wall nozzles which are able to generate a counter-current flow of process gases into the converter vessel. This achieves its property as a process gas when it participates in the process within the converter, i.e. interacts with the slag and possibly also the molten metal. The counter-current flow of the process gas consequently also causes a counter-current flow of slag and possibly metal melt, whereby counter-rotating and mixing or at least encountering slag and possibly also metal flows are generated with particularly simple means.

This causes an increased mixing of the phases involved or an increase in the mixing intensity. At the same time, this reduces the temperature distribution, the risk of overspraying (so-called slopping) or the excessive formation of foamed slag, and ultimately the entire fresh process is made safer and more manageable.

Definitions:

Process gas:

Mixture of oxygen and inert gas in variable proportions

Thermodynamic equilibrium:

Quasi-static thermodynamic equilibrium, chemical reactions and changes of state take place in such a way that kinetic effects are negligibly small

Decarburization process:

Feeding an oxygen carrier into the metallurgical reactor for the oxidation of a carbon content of the metallic melt. In addition, can also other unwanted elements (P, Cr, Si, ...) are removed from the melt by oxidation.

Mixing intensity:

Amount of the energy provided to a substance or mixture of substances, in particular the slag, in a mixing time to achieve a mixing quality

Jet:

Injection opening through which one or more process gases can be blown into the converter and / or powder can be fed to the converter with the aid of a conveying gas

Essentially opposing currents:
a flow of process gas or gases that is able to bring about the mixing of the substances involved, preferably an exactly opposing flow of process gases, viewed in vector terms with the same direction and opposite orientation. According to the invention, however, those flows of process gas are also regarded as essentially opposing one another, which in each case have a deviation of up to +/- 20 ° based on an exact alignment with one another. Likewise, such currents are viewed as essentially opposing one another, which are laterally offset to one another, possibly parallel to one another and / or with a deviation of up to +/- 20 ° in each case based on an exact alignment to one another. The decisive factor is whether the currents are capable of significantly increasing the mixing intensity within the substances involved, in particular the slag, preferably by at least 20, particularly preferably by at least 30%.

According to a preferred embodiment of the invention, the side wall nozzles are at the level of what is present in the converter during operation Slag level arranged above the molten metal. At least four side wall nozzles, particularly preferably in combination with at least one floor nozzle, are preferably arranged in the converter vessel. This provides a converter in which the side wall nozzles can be used specifically to influence the mixing intensity of the slag without undesirably increasing the decarburization rate within the molten metal. The fresh process and in particular the decarburization rate can be controlled in a targeted and unchanged manner via the top lance, and any floor nozzles that may be present can in turn be used to move the metal bath.

In a further, equally preferred embodiment of the invention, at the end of the top lance facing the interior of the converter vessel, there are at least two lateral outlet openings for process gas, which are arranged such that a substantially tangential flow or tangential flows of process gas relative to the circumference the end of the top lance can be generated.

The tangential flow or the tangential flows from the top lance are preferably generated essentially in the opposite direction to the flow or flows from the side wall nozzles. As a result, the increase in the mixing intensity within the converter vessel can be set particularly effectively and flexibly.

According to a second aspect of the invention, a method is made available in which a deviation between a thermodynamic equilibrium state and an actual state in the metallurgical reactor during the decarburization process of the metallic melt is assessed by means of a comparison between the thermodynamic equilibrium on the one hand and the actual state on the other and / or is predicted. According to the invention, the mixing intensity of the substances involved in the metallurgical reactor is determined controlled or regulated by means of at least one injection device for process gases and / or dusts. In addition, at least one injection device for process gases and / or dusts controls or regulates the CO / CO ₂ formation rate and thereby, inter alia, the decarburization rate in the metallurgical reactor. If a deviation occurs, namely the assessed and / or predicted deviation, depending on this assessment and / or the prediction, the decarburization process is controlled or regulated in such a way that the mixing intensity increases and / or the decarburization speed and / or the CO / CO ₂ formation rate is reduced.

This provides a method with which, by minimizing and / or reducing the described deviation, an ejection (slopping) and / or over-foaming of metallic melt and / or slag is prevented in a targeted manner. This is preferably achieved without influencing the decarburization rate in any way, in particular without changing the distance between the outlet nozzle (s) for process gas from the top lance and the bath level or changing the blowing rate via the top lance.

In a preferred embodiment of the method according to the invention, possible courses of the decarburization process are continuously predicted on the basis of input variables by means of a calculation of the thermodynamic equilibrium. The actual state of the metallurgical reactor is preferably determined by means of manual inputs, measurements or empirical models. As a result, the deviation can be determined on the basis of a comparison between the actual state and predicted possible decarburization processes and assigned to a critical or non-critical category. The non-critical category is preferably characterized by a sufficiently high CO / CO ₂ formation rate and thus a sufficiently high decarburization rate to avoid oversaturation of the metallic melt with oxygen. Furthermore, the non-critical category is preferably defined by a sufficiently low CO / CO ₂ formation rate and / or Decarburization rate for the formation of a sufficient iron oxide content (FeO) in the slag.

Taking into account mathematical methods and models, the method according to the invention can make a prediction about possible courses of the decarburization process, a real decarburization speed and thus also the deviation between the two. For this purpose, the deviation is determined, preferably continuously, by comparing a prediction of the theoretical thermodynamic equilibrium within the metallurgical reactor, preferably the converter, with an actual state. The actual status is calculated using a combination of various input parameters. A temperature measurement, a measurement of the composition of the exhaust gas or a mass balance of the metallurgical reactor can be referred to as possible input parameters for this purpose.

A non-critical process sequence is preferably characterized in that the CO / CO ₂ formation rate and / or the decarburization rate is sufficiently high to avoid oversaturation of the molten steel with oxygen. For the formation of enough iron oxide (FeO) for a reactive slag, the CO formation rate and / or the decarburization rate should ideally be sufficiently low. If the decarburization process is carried out within these limits, the disadvantageous reaction kinetic effects are avoided. Overall, it is advantageous if the decarburization process takes place in an area in which the thermodynamic equilibrium within the substances involved, in particular the slag, does not cause the ejection or foaming.

On the process side, instructions are given to the person skilled in the art by means of which he is able to control the decarburization process, in particular the fresh process, with simple means and the mixing intensity of the desired phases within the metallurgical reactor, in particular the Mixing intensity within a slag floating on a molten metal, to avoid thermodynamic imbalances, to be controlled as required. At the same time, the occurrence of excessive amounts of foamed slag and / or the undesired ejection of slag and / or metal from the metallurgical reactor due to thermodynamic imbalances are avoided. All of this leads to a more stable and safe process sequence as well as an extension of the service life of the metallurgical reactor.

According to a further preferred embodiment of the method according to the invention, a process gas and / or dust is blown into the metallurgical reactor by means of an injection device. The injection device can consist of a top lance, side wall nozzles and / or bottom nozzles. The top lance has at least one or more nozzles. When using the top lance, one or more bottom nozzles and / or one or more side wall nozzles, the pressure, the volume flow and / or the composition of the process gas for individual or all nozzles can be controlled or regulated independently of one another.

If powder is blown in by means of a conveying gas, this can preferably be done by using the top lance, one or more bottom nozzles, and / or one or more side wall nozzles. For the control and / or regulation of the various above-mentioned parameters of the injection device, such as pressure, volume flow, composition of the process gas or the distance between the lance tip, specifications are made. These specifications influence, among other things, the mixing intensity in the metallurgical reactor in such a way that shear flows are generated in the different areas of the metallurgical reactor. According to the invention, these shear currents lead to increased mixing of the substances involved, in particular within the slag floating on the metal bath, and increase the mixing intensity with simple means while reducing thermodynamic imbalances.

Influencing the mixing intensity of the substances involved preferably includes increasing the mixing intensity within the slag, preferably only increasing the mixing intensity of the slag without influencing the bath movement within the molten metal.

According to a further preferred embodiment of the method according to the invention, this is used in particular in an early phase of the decarburization process to avoid undesired ejection (slopping) and / or over-foaming. This advantageously avoids reaction kinetic effects in the metallurgical reactor, the distance between the top lance and the bath surface advantageously not having to be changed.

The process is preferably monitored by evaluating exhaust gas measurements during the decarburization process. The results of the exhaust gas measurement and the evaluation of the measured parameters, in particular the rate of CO formation, are preferably included online in the process control. The deviation then preferably gives an indication of a delayed decarburization reaction. This supports the decarburization process with simple and easily controllable means and provides the system operator with targeted data that can be used to control the process in a targeted and safe manner. In particular, the measured parameters can be used to determine whether and how the process should be acted upon in order to ensure optimal process management.

The method according to the invention according to the second aspect of the invention is preferred in a converter according to the first aspect of the invention applied. The same effects that are disclosed in connection with the individual aspects can thus be achieved with both aspects of the invention.

The mixing intensity within the slag is preferably increased exclusively by increasing the volume flow of process gas from the side wall nozzles and possibly the at least one floor nozzle. This creates a method that is able to adjust the mixing intensity in a targeted manner within the slag without simultaneously influencing the decarburization rate or the rest of the fresh process in an undesired way.

The process gas from the side wall nozzles and possibly the at least one floor nozzle is then preferably free of oxygen. This means that the decarburization rate is controlled by the top lance alone, while the side wall nozzles and possibly also the bottom nozzle (s) contribute to increasing the mixing intensity within the slag and possibly the molten metal and to reducing thermodynamic imbalances.

5 . Brief description of the drawings:

Figur 1:

eine Seitenansicht auf einen Konverter mit typischer Bauform des Konvertergefäßes und mit Toplanze sowie Seitenwanddüsen,

Figur 2a):

eine erste schematische Darstellung erfindungsgemäß erzeugter gegenläufiger Scherströme innerhalb des Konvertergefäßes, und

Figur 2b):

eine zweite schematische Darstellung erfindungsgemäß erzeugter gegenläufiger Scherströme innerhalb des Konvertergefäßes.

The invention is explained in more detail below with reference to drawings. In the drawings are:

Figure 1:

a side view of a converter with a typical design of the converter vessel and with a top lance and side wall nozzles,

Figure 2a):

a first schematic illustration of opposing shear currents generated according to the invention within the converter vessel, and

Figure 2b):

a second schematic illustration of opposing shear currents generated according to the invention within the converter vessel.

6th Detailed description of embodiments:

Figure 1 shows a typical structure of a metallurgical reactor, here a BOF converter 100. The BOF 100 is usually used to decarburize a metallic melt 500. Also shown is a rotatable suspension 110 of the BOF, a top lance 210, side wall nozzles 220 blowing in at an angle α to the horizontal, a slag layer 400 and the metallic melt 500. The side wall nozzles 220 are arranged within the side wall of the BOF 100 so that they can or nominal conditions, consequently an operation with the intended fill quantity and height both in relation to the molten metal 500 and the slag 400, direct the flow of process gas solely onto or into the slag 400.

In the event of a critical deviation in the decarburization rate, which is an indication of an expected ejection of slag 400 or molten metal 500 from the BOF 100 or foaming over of the slag 400, the blower device 200, having the top lance 210 and the side wall nozzles 220 , the decarburization process can be influenced. Both a mixing process in the BOF and the decarburization speed can be adapted by means of specifications for the control or regulation of the top lance 210 and / or the side wall nozzles 220. Typically, the mixing process in the BOF 100 is intensified and / or the decarburization speed is reduced by reducing the oxygen supply. With these specifications, the decarburization process then returns to the area of thermodynamic equilibrium and the deviation can be eliminated or at least assessed as uncritical.

For the method according to the invention it is advantageous that a blowing device 200 for the BOF 100 consists of several nozzles. The nozzles can be installed in a top lance 210, as a side wall nozzle 220 or as a floor nozzle (not shown) in the BOF 100. Ideally, for each nozzle for the process gas, the Composition, pressure, temperature or volume flow can be controlled or regulated individually and / or independently of one another. If a powder is also blown in with the aid of the nozzles, the feed should also be controllable or regulatable independently of the nozzle. Furthermore, it is advantageous for the use of a top lance 210 if the distance between the tip and the bath surface can be regulated or controlled. By supplying the process gas and / or powder to the BOF 100 in a controllable or adjustable manner, it is possible both to influence the decarburization speed directly and to change a mixing process, for example within the slag layer 400, via a pulse input. For this purpose, a pulse introduced by a side wall nozzle 220 is preferably used in such a way that the proportions and intensities of shear flows in the BOF 100 are adapted to the decarburization process. For this purpose, it is helpful to also consider and adapt the alignment of the nozzles in the blower device 200 with one another.

The Figures 2a ) and b) show two possible variants of nozzle alignment in the horizontal plane for generating shear flows: a) The side wall nozzles 220 are aligned in opposite directions, so that the shear flow is generated in the area of influence of the side wall nozzles 220. b) The alignment of the nozzles in the top lance 210 is opposite to the alignment of the side wall nozzles 220. The shear flows form in the area between the area of influence of the top lance 200 and the side wall nozzles 300.

Claims (23)

Converter for refining molten metal, in particular an iron or steel melt, comprising a converter vessel and at least one top lance and at least two side wall nozzles arranged in the side wall of the converter vessel,
characterized in that
the side wall nozzles are designed and arranged in such a way that they can be used to generate a flow of process gas into the converter vessel that is essentially opposite to one another. Converter according to claim 1,
characterized in that
the side wall nozzles are arranged above the molten metal at the level of the slag level present in the converter during operation. Converter according to one of the preceding claims,
characterized in that
at least four side wall nozzles, preferably in combination with at least one floor nozzle, are arranged in the converter vessel. Converter according to one of the preceding claims,
characterized in that
At the end of the top lance facing the inside of the converter vessel, at least two lateral outlet openings for process gas are arranged, which are designed in such a way that they can generate a substantially tangential flow or tangential flows of process gas based on the circumference of the end of the top lance. Converter according to claim 4,
characterized in that
the tangential flow or the tangential flows from the top lance can be generated essentially in opposite directions to the flow or flows from the side wall nozzles. Converter according to one of the preceding claims,
characterized in that
the mixing of the slag within the converter vessel can be adjusted by the flows from the side wall nozzles and / or the top lance. Method for controlling the decarburization process of a metallic melt in a metallurgical reactor, preferably a converter, wherein - a deviation between a thermodynamic equilibrium state and an actual state in the metallurgical reactor during the decarburization process of the metallic melt is assessed and / or predicted by means of a comparison between the thermodynamic equilibrium on the one hand and the actual state on the other; - a mixing intensity of the substances involved in the metallurgical reactor is controlled or regulated by means of at least one injection device for process gases and / or dusts; and or a decarburization rate and / or a CO / CO ₂ formation rate in the metallurgical reactor is controlled or regulated by means of at least one injection device for process gases and / or dusts; and - When the assessed and / or predicted deviation occurs, depending on the assessment and / or prediction, the decarburization process is controlled or regulated in such a way that ∘ the mixing intensity is increased; and or ∘ the rate of decarburization and / or the rate of CO / CO ₂ formation is reduced. Method according to claim 7,
characterized in that - possible courses of the decarburization process by means of a calculation of the thermodynamic equilibrium are continuously predicted on the basis of input variables. Method according to one of Claims 7 or 8,
characterized in that
the actual state of the metallurgical reactor is determined by means of manual inputs, measurements or empirical models. Method according to one of Claims 7 to 9,
characterized in that - the deviation is determined on the basis of a comparison between the actual state and predicted possible decarburization processes; and - the deviation is assigned to a critical or non-critical category. Method according to claim 10,
characterized in that the uncritical category is indicated by - a sufficiently high CO / CO ₂ formation rate and thus a sufficiently high decarburization rate to avoid oversaturation of the metallic melt with oxygen; and - the sufficiently low CO / CO ₂ formation rate and / or decarburization rate for the formation of a sufficient iron oxide content (FeO) in the slag. Method according to one of claims 7 to 11, characterized in that - Process gas and / or dust are blown into the metallurgical reactor by means of an injection device; - The injection device can consist of a top lance, side wall nozzles and / or bottom nozzles; - The top lance has at least one or more nozzles; - When using the top lance, one or more bottom nozzles, and / or one or more side wall nozzles, the pressure, the volume flow and / or the composition of the process gas for individual or all nozzles can be controlled or regulated independently of one another; and or - When using a top lance, the distance between the lance tip and the bath surface can be controlled or regulated; and or - When using the top lance, one or more bottom nozzles, and / or one or more side wall nozzles, powder can be blown in by means of a conveying gas. Method according to one of Claims 7 to 12,
characterized in that - Specifications for the control or regulation of pressure, volume flow and / or composition of the process gases of the injection device are made; and or - Specifications for the control or regulation of pressure, volume flow of a conveying gas for the dust and / or the dust of the injection device are made. Method according to one of Claims 7 to 13,
characterized in that
To influence the mixing intensity in the metallurgical reactor by means of at least one injection device for process gases and / or dusts, the type, number, position and / or orientation of the injection devices in the metallurgical reactor and the specifications for the injection device are selected so that shear flows in the different areas of the metallurgical reactor. Method according to one of Claims 7 to 14,
characterized in that - the method is used in an early phase of the decarburization process to avoid undesired ejection and / or over-foaming; and or - reaction kinetic effects in the metallurgical reactor are avoided. Method according to one of Claims 7 to 15,
characterized in that
the distance between the top lance and the bath surface is not changed. Method according to one of Claims 7 to 16,
characterized in that
the process is monitored by evaluating exhaust gas measurements during the decarburization process. Method according to claim 17,
characterized in that
the exhaust gas measurement and the evaluation of the measured parameters, in particular the rate of CO formation, are included online in the process control. Method according to one of Claims 7 to 18,
characterized in that
the deviation indicates a delayed decarburization reaction. Method according to one of Claims 7 to 19,
characterized in that
influencing the mixing intensity of the substances involved includes increasing the mixing intensity within the slag, preferably only increasing the mixing intensity of the slag without influencing the bath movement within the molten metal. Method according to one of Claims 7 to 20,
characterized in that
it is used in a converter according to any one of claims 1 to 6. Method according to claim 21,
characterized in that
to increase the mixing intensity within the slag exclusively by increasing the volume flow of process gas from the side wall nozzles and possibly the at least one bottom nozzle. Method according to one of Claims 21 or 22,
characterized in that
the process gas from the side wall nozzles and possibly the at least one floor nozzle is free of oxygen.

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