EP0512658A1 - Plant for treatment of liquid steel and process for running the same - Google Patents

Abstract

The invention relates to plant for the secondary metallurgical treatment of molten steel, which is arranged within a production chain consisting of a melting device, such as an electric furnace or converter, and a casting device, in particular a continuous casting device. A solution is to be found which, at the lowest possible cost, ensures a high degree of flexibility and an adaptation of the VOD transformation time to the cycle times of the upstream and/or downstream melting and casting devices. For this purpose, the plant is designed with two stands for in each case one vessel (1, 1') which can be evacuated and contains a steel melt, which contain devices (6, 6') for feeding oxygen and devices (7, 7') for adding additives to the melt, and with pipes (3) which connect the vessels (1, 1') to a device for generating a vacuum, a device consisting of a water ring pump station (5') for generating a moderate vacuum and a device (4, 5) consisting of water ring pumps (4) and steam ejectors (5) for generating a deep vacuum being provided, and the vessels being selectively connectable only to the device for generating a moderate vacuum (5') or to the device for generating a deep vacuum (4, 5). <IMAGE>

Description

The invention relates to a plant for the secondary metallurgical treatment of liquid steel, which is arranged within a production chain consisting of a melting device, such as an electric furnace or converter, and a casting device, in particular a continuous casting plant.

Such systems are known in principle and with regard to the technical design of the individual units and process stages, for example made of steel and the like. Eisen 109 (1989), No. 22, pages 1047 to 1056. The crude steel is produced either in an electric arc furnace or in a converter. Then the liquid steel is fed to a station for secondary metallurgical treatment and finished and finally cast on a continuous caster or as block steel.

Such a process chain is also known from a brochure from Mannesmann Demag Hüttentechnik 6.13.3.11 E 08.09.2000. A VOD system is used here as an aggregate for secondary metallurgical treatment, see 11 with description.

The size of the individual parts of the plant or their capacity is coordinated with one another in such a way that a smooth flow of material within the process chain is guaranteed for a certain generation quantity.

• A - entspricht der Zeit für die Zuführung der Pfanne zum Ort der Behandlung sowie die Vorbereitung durch Inertgasanschluß und -einstellung der Spülintensität sowie Abdeckung mittels mit Feuerfestmaterial ausgekleidetem oder wassergekühltem Deckel.
  Letzterer reduziert die Zeit bei vorliegendem Beispiel um mehr als die Hälfte.
• B - enthält das eigentliche Vakuumfrischen. Angenommen wurden Eingangs-C-Gehalte von 0,60 % und Si-Gehalte von 0,20 % für die Stahlgüte V2A. Entsprechend einer sich ändernden Analyse sind kürzere oder längere Zeiten in Rechnung zu stellen.
• C - beinhaltet die Auskochzeit im Anschluß an das Sauerstofffrischen.
• D - ist die Zeit für die Aufgabe der Schlackenbildner und der Reduktionsmittel. Im Falle des zum Einsatz gelangten Deckels mit ff-Material ist dieser zu diesem Zeitpunkt zu entfernen, was im Unterschied zu dem in der Anlage installierten wassergekühlten Deckel einen zeitlichen Mehrbedarf beansprucht.
• E - umfaßt die Reduktionszeit, deren Dauer von Erfordernissen wie Reduktion, Entgasung, Entschwefelung abhängig ist.
• F - bezieht sich auf die Analysenkorrektur sowie die Temperaturmessung mit den Einzelaktivitäten wie Probenahme, Temperaturmessung, Legierung, Kühlschrottzugabe, Abdecken der Pfanne.

The procedure within the VOD station is explained using Figure 1. It is divided into sections A - F:

• A - corresponds to the time for the pan to be delivered to the place of treatment and the preparation by means of an inert gas connection and setting of the purging intensity and cover by means of a lid lined with refractory material or water-cooled lid.
  The latter reduces the time in the present example by more than half.
• B - contains the actual vacuum refresh. Inlet C contents of 0.60% and Si contents of 0.20% were assumed for the steel grade V2A. According to a changing analysis, shorter or longer times have to be charged.
• C - includes the boil-out time following the oxygen freshening.
• D - is the time for the abandonment of slag formers and reducing agents. In the case of the used cover with ff material, this must be removed at this time, which is different from the water-cooled one installed in the system Cover claimed an additional time requirement.
• E - includes the reduction time, the duration of which depends on requirements such as reduction, degassing, desulfurization.
• F - refers to the analysis correction as well as the temperature measurement with the individual activities such as sampling, temperature measurement, alloy, addition of cooling scrap, covering the pan.

In the context of the upstream or downstream production facilities, the variants shown in Figures 2 to 4 are possible and known.

Figure 2 (variant 1) shows the original treatment sequence at just one vacuum level. The variant 2 shown in Figure 3 provides for the final treatment of the melt in a separate rinsing station.

Variant 3 (Figure 4) contains a second treatment stand. A further reduction in the cycle sequence is limited by the availability of the conventional vacuum pump system, usually consisting of water ring pumps and steam jets.

These known concepts of the process chain melting device - VOD system - casting device are not basic solutions to even approximately achieve the low cycle times of melting and casting devices or to adapt them to one another. Changes within the line once defined would only be possible by including a costly additional metallurgical facility or by shifting the preparation time of the melts to a separate rinse after the reduction treatment. The overall system is also inflexible with regard to changes in metallurgy or casting techniques that affect the cycle time of the individual stages by reducing these cycle times.

The problem is therefore to find a solution that ensures a high degree of flexibility and adaptation of the VOD treatment time to the cycle tents of the upstream and downstream melting and pouring devices with the least possible effort.

The invention is based on a known VOD system. This usually consists of a combination of water ring pumps and the actual core of the vacuum system, the steam jets.

With regard to the plant part according to the preamble of claim 1, the problem is solved by the characterizing features of claim 1. Further developments according to the invention contain sub-claims 2 to 5.

The method for melt treatment according to the preamble of claim 6 is further developed according to the invention with regard to the aforementioned problem with the characterizing features of claim 6.

Advantageous further developments of the method according to the invention are specified in claim 7.

The invention is to be explained in more detail below, reference being made to FIGS. 6 and 7.

In FIG. 6, the usual line of treatment of a melt in a VOD system, as it results from FIG. 1, is shown only in the first line, with VAK level 1 (container 1), as shown in FIG Modification that the treatment section F was moved to a conditioning stand.

After all preparatory work has been completed (time period A), a medium vacuum of, for example, a vacuum of e.g. 180 mbar generated. In this time period B, oxygen is blown onto the melt by the device for supplying oxygen 6 'onto the melt in the ladle 2. Oxygen can also be supplied via a combustible lance.

Towards the end of this section B, when the amount of gas from the melt becomes less, the shut-off device 9 'is opened and the shut-off device 12' is closed, so that the container 1 is now driven by the water ring pumps 5 and the steam jets 4 to a desired low vacuum of a certain size . Oxygen can still be blown during this time. After the oxygen supply has ended, the treatment steps or treatment sections C - boil-out and E-reduce - (with the introduction of purge gases) follow.

During this treatment in container 1, a further pan 2 is inserted into VAK stand 2 (container 1 ') and treatment is carried out in the manner described for the first pan, ie the shut-off device 12 is opened so that in container 1 'A medium vacuum is generated by means of the water ring pumps 5' via the pipes 10, 11.

At the end of the treatment tent E for the first pan in the container 1, the pretreatment of the melt in the container 1 'is completed at the same time.

In the example chosen, the first melt is now transferred and finished in a conditioner not shown in FIG. 7. The container 1 is now available for receiving a third ladle, while the container 1 'can be subjected to a deep vacuum by appropriate actuation of shut-off devices.

In the present example, water ring pumps are always used as devices for the generation of a medium vacuum and a combination of water ring pumps and steam jets for the generation of the low vacuum, but a steam jet system of corresponding design can also be used for the medium vacuum.

With the solution according to the invention the purpose is pursued, a higher time utilization of the upstream and downstream melting and pouring equipment by z. B. Sequence casting in continuous casting to achieve higher melting capacity or reduced size of the furnaces.

The advantages achieved are an increase in production of the plant with reduced investment and operating costs, increased utilization of the vacuum device and increased possibility of adapting the VOD treatments to the cycle sequence of the melting or pouring devices.

5 shows a timing diagram of the solution according to the invention, including an electric arc furnace or converter and a continuous casting installation, the cycle time of the vacuum installation being 55 minutes.

The possible effects of the solution according to the invention can be seen in the following overview with their effects on treatment time, productivity and plant size consequences on Modification of the solution according to the invention (Var. 4) compared to the previously known solutions Var. 1 100% or t Var. 2 100% or t Var. 3 100% or t Treatment time 37% 50% 54% productivity 269% / t 200% / t 186% / t Plant size 37 t 50 t 54 t

It should be added that - provided the cycle time is the same - these effects also occur in the upstream and downstream melting and casting equipment. For example, in comparison with Var. 3 (Fig. 4) in the solution according to the invention - assuming the same production level - the plant size can be reduced from 100 to 54 t, both with regard to the melting device, vacuum and continuous casting plant.

Claims (7)

Plant for the secondary metallurgical treatment of liquid steel within a production chain consisting of a melting device and a casting device, in particular a continuous casting plant, with two stands for each evacuable container (1, 1 ') containing a steel melt, the devices (6, 6') for supplying oxygen and Have devices (7, 7 ') for adding additives to the melt and pipes (3) which connect the containers (1, 1') to a device for generating a vacuum, a device consisting of a water ring pump station (5 ') for generating a medium vacuum and a device (4, 5) consisting of water ring pumps (4) and steam jets (5) for generating a low vacuum and the containers are optionally only the device for generating a medium vacuum (5 ') or the device can be switched on to generate a low vacuum (4, 5). System according to claim 1,
characterized,
that the containers (1, 1 ') are designed to accommodate ladles (2). System according to claim 1,
characterized in that the containers (1, 1 ') are formed by ladles (2) with attachable, vacuum-tight lids. System according to one of claims 1 to 3,
characterized,
that the containers (1, 1 ') have devices (8, 8') for introducing gases into the melt. System according to one of claims 1 to 4,
characterized,
that the containers (1, 1 ') are connected to a branch pipe (3') of the pipe (3) which leads to the device (4, 5) for generating the vacuum, and between the branch point (3 '') and the containers (1, 1 ') shut-off device (9, 9') are arranged and a suction line (10) coming from the water ring pumps (5 ') via its branches (11, 11') via shut-off devices (12, 12 ') to the pipeline ( 3 ') is connected in an area between the container (1, 1') and the respective shut-off devices (9, 9 '). Process for the secondary metallurgical treatment of molten steel under vacuum, in particular using a plant according to claims 1 to 5, with the process steps 1. Fresh the melt with simultaneous oxygen supply, 2. allowing the melt to boil out following the oxygen supply, 3. Addition of reducing agents with subsequent treatment time for degassing and desulfurization of the melt and 4. Analysis correction and alloying, wherein at least one process step is carried out with the simultaneous introduction of a further gas, in particular inert gases, into the melt and two melts are exposed to the vacuum at the same time,
characterized,
that the melts are exposed to the vacuum at different times such that one of the melts is treated under a medium vacuum and during this time the other melt - which was previously exposed to the medium vacuum - is treated in the same container under a low vacuum. Method according to claim 6,
characterized in that the average vacuum is operated in a range from 1 bar to 200 mbar and the lower vacuum below this value.

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