EP0946761A1

EP0946761A1 - Installation and method for producing molten metal

Info

Publication number: EP0946761A1
Application number: EP98929118A
Authority: EP
Inventors: Stefan Dimitrov; Norbert Ramaseder; Wilfried Pirklbauer; Yoyou Zhai; Johannes Steins; Ernst Fritz; Johannes Müller
Original assignee: Voest Alpine Industrienlagenbau GmbH
Current assignee: Primetals Technologies Austria GmbH
Priority date: 1997-06-27
Filing date: 1998-06-26
Publication date: 1999-10-06
Also published as: CN1082548C; US6508853B2; CA2264665A1; WO1999000522A1; JP2001500243A; US6264883B1; ZA985594B; AT404942B; CN1236398A; ATA110997A; BR9806107A; RU2205878C2; US20020005083A1; KR20000068375A

Abstract

In order to produce molten metal from all types of metal carriers used in metallurgy, and in particular from a wide range of quantitative combinations, an installation for producing molten metal comprises the following components: an electric arc furnace (1) having a charge opening (11, 21) for molten metal and/or scrap and/or directly-reduced metal, especially directly-reduced iron and/or ore, and at least one electrode (16) and a slag tapping unit (22); and an oxygen lancing converter vessel (3) fitted with a slag tapping unit (41). Said oxygen lancing converter vessel (3) forms a single unit with the electric arc furnace (1) which unit is connected by means of an overflow weir (34) and rigidly mounted on the base. The bath surface specifically related to bath volume is smaller in the oxygen lancing converter vessel (3) than in the electric arc furnace (1). Lastly, the oxygen lancing converter vessel (3) shares a common reaction chamber with the electric arc furnace (1), which chamber is situated above the bath level of the two vessels.

Description

Plant and method for producing molten metals

The invention relates to a plant for producing metal melts, in particular iron melts, such as steel melts, crude steel melts or pig iron melts, and a method for producing these melts.

Nowadays, the AC or DC electric arc furnace serves as the standard unit for electric steel production. The iron carriers used are made of - 60 to 100% steel scrap, directly reduced iron sponge in various

Proportions, and occasionally iron carbide (currently up to about 10 to 20% of the total use) and

0 to 40% liquid and / or solid pig iron melted down with the help of one or more electric arcs using oxygen lance (s) - optionally burner (s), nozzles and / or inert gas flushing - and addition of carbon carriers and slag formers. The steel bath is then brought to the temperature and composition desired for tapping in a flat bath period (5 to 10 min) in the electric arc furnace and calmed down when tapping in the pan. The energy and material consumption as well as the plant productivity are quite different depending on the respective application conditions and the melting practice.

Due to the worldwide introduction of secondary metallurgical processes as well as a series of developments in the construction, electrical and technological area, the electric arc furnace melting shop has changed over the past few years into a flexible and powerful process with regard to feedstocks and the steel quality produced, which more and more often has significant advantages over the Converter metallurgy and competes successfully. Especially by using

Integrated scrap preheating and / or hot use of sponge iron / hot briquetted directly reduced iron,

Continuous addition of a large part of the input materials (iron carriers, carbon carriers, aggregates etc.) while minimizing the power-off time for carrying out charging operations,

• optimal foam slag operation and

• cheaper primary energies (coal, natural gas, etc.) to replace electrical energy, including improved exhaust gas afterburning practice and more efficient use of heat With new process developments, a significant reduction in melting time and a reduction in specific electrical energy consumption and thus a further reduction in the specific operating and investment costs of electrical steel production in the electric arc furnace was achieved.

In the known electrical steel production processes with electric arc furnaces as melting units, however, the potential advantages of the process developments mentioned above are only used to a limited extent. Furthermore, despite the increasing demand, it has not yet succeeded in high proportions of molten pig iron and / or other carbon-rich iron carriers (sponge iron, iron carbide, etc.) and problem scrap (old cars) of around 30 to 70% in electric arc furnace use with a high level Productivity and energy use, and in the case of car scrap also to be processed into liquid steel without impermissible environmental pollution. The large-scale application of a technology and plant based on an electric arc furnace that is economically highly effective under such conditions is still pending.

The limitations mentioned in the conventional electric arc furnace are caused exclusively by the furnace configuration, which does not allow a quasi-stationary, continuous process. The operations charging, melting, freshening, heating up and parting off take place in one place, inevitably more or less staggered and with interruption (s) of the feed and power supply - at least before and during tapping - to the desired composition and temperature (homogeneity and overheating with regard to the liquidus temperature) of the crude steel. The current process flow in the electric arc furnace is discontinuous and therefore limited in performance. In this regard, the following should be mentioned:

1. With tap-to-tap times of <50 min already achieved with conventional electric arc furnaces or <35 min for electric arc furnaces with a shaft for tap weights of 70 to 150 t, the possibility of further shortening the power-off phases is severely limited. The same also applies to the power-on phases - since under these conditions the limit for economic energy input per ton of use and time unit has almost been reached - and thus for the entire melting time.

2. In the case of continuous charging, as well as when refreshing and heating up in flat bath operation, the duration of which increases significantly with a high proportion of iron sponge and in particular liquid pig iron and iron carbide (approx. 6.1% C), as a result of which the heat losses also increase, the existing transformer power in electric arc furnaces is generally not fully utilized.

AT-B - 295.566 describes a process for the continuous production of steel by melting pre-reduced ore and then refining the melt from semi-steel (semi-steel) to steel in an arc melting furnace with a melting range, to which a fresh zone and at least one slag settling chamber are connected are known in which pre-reduced iron ore is introduced in lump or granular form into the arc zone of the melting furnace, the metal in the furnace is continuously stirred and brought into circulation and the metal by blowing in oxygen-containing gas as it flows through a fresh zone Steel is refurbished, whereas slag is caused to flow along at least part of the length of the fresh zone against the metal. In a slag settling chamber without intensive bath mixing, the slag calms down, which is then tapped from the slag settling chamber.

In this known process, scrap and molten pig iron can be used, but only in very limited quantities. The exhaust gases are removed directly in the fresh zone, i.e. not via the arc melting furnace. The fresh zone is designed as a channel reactor, which results in a high specific surface with high heat losses. Refreshing takes place with a C concentration gradient along the fresh zone of the channel reactor without a concentration compensation vessel, which is why the C content is difficult to adjust or regulate. This known method is therefore of limited use and is used primarily to produce crude steel from pre-reduced ore.

DE-C 3 609 923 discloses a method and a device for the continuous melting of scrap into crude steel. In this method, which is mainly limited to scrap melting (the use of liquid pig iron and / or sponge iron is not mentioned), the heat of the furnace gas is used to heat the scrap. The scrap is preheated in a shaft placed centrally on the hearth furnace and introduced centrally into the hearth furnace, whereby a scrap column is formed, which is supported on the bottom of the electric arc furnace with the formation of a pouring cone and can reach up to the scrap loading opening in the upper part of the scrap preheating shaft. Swiveling electrodes (preferably four electrodes) are arranged symmetrically around the scrap column in the electric arc furnace, with the aid of which the scrap is melted down. The angle of inclination between the central electrode axis and a vertical is more than 20 ° for each electrode during scrap melting. Here, the stove is exposed to an enormous heat load, since the arcs between the Burn the centrally placed scrap column and the walls or the lid of the stove. On the one hand, this leads to increased wear of the refractory lining, and thus to higher material and time costs for carrying out repairs. Furthermore, a large part of the energy introduced is transmitted to the furnace walls and the furnace cover by radiation and is lost. In addition, a possible bridge formation in the scrap column - above the melting caverns melted into it by the electrodes - does not rule out a fall of the scrap column (or parts thereof), which can lead to an electrode breakage and thus to a process interruption.

The Contiarc process is known from MPT International 2/1996, pages 56 to 60, in which scrap is melted down continuously, etc. in a ring shaft furnace. This process is used only for melting scrap; the use of sponge iron and / or liquid pig iron is not mentioned. A disadvantage of this method is the difficulty in setting the crude steel temperature immediately before the start and during the tapping process, since there is a very large contact area of the scrap, which is arranged in a ring, with the liquid bath. Difficulties may also arise with regard to concentration equalization or chemical homogeneity of the melt which has been discontinuously freshly and tapped in this process.

According to the method Consteel- ^® (known from Electric Furnace Conference Proceedings 1992, pages 309-313) is preheated with an elongated, horizontal preheating scrap ^'and charged into an electric furnace, u.zw. on one side of the electric oven. The exhaust gas generated in the electric furnace is removed via the elongated preheating device for the scrap. However, this does not result in optimal gas utilization, since the waste gas does not flow through the scrap, but only sweeps it over it. The elongated preheating duct for the scrap is arranged in a stationary manner, whereas the electric furnace is tiltably mounted so that a crude steel tapping can be carried out discontinuously in this process. The construction itself is therefore complex, as with all tilting ovens. The refractory lining of the furnace is mechanically stressed. The scrap is loaded batchwise, since the scrap is only introduced on one side of the furnace, etc. is deposited in an edge area of the furnace. As a result, the melting process and the mixing process cannot be carried out optimally; the use of burners in the electric furnace to support the scrap melting would only be possible with a low degree of efficiency. The dust content in the exhaust gas is relatively high because the exhaust gas is not filtered by the scrap.

The invention aims to avoid these disadvantages and difficulties and has as its object a plant and a method for producing molten metals. In particular to create iron smelting, which fundamentally requires the use of all metal supports that occur in metallurgical practice, preferably iron supports with different physicochemical properties, such as scrap iron, liquid and / or solid pig iron, iron carbide, sponge iron, iron ore with different degrees of pre-reduction, sinter, scale, metallurgical dust, dried sludge, etc., etc. in a wide variety of quantities, so that, for example, if one of the iron girders appears to be bottlenecked, it can be switched to another without significant capacity restrictions.

To achieve this object, a system is equipped with the following features:

An electric arc furnace vessel which is provided with at least one charging opening for a molten metal and / or scrap and / or direct-reduced metal, in particular direct-reduced iron and / or ore, and at least one electrode and at least one slag tapping device,

• an oxygen blowing converter vessel, which is provided with at least one metal tapping device, wherein

• The oxygen blowing converter vessel forms a unit connected by an overflow weir with the electric arc furnace vessel, and

• The bath surface in the oxygen blowing converter vessel, which is specific to the bath volume, is smaller than in the electric arc furnace vessel and

• The oxygen blowing converter vessel with the electric arc furnace vessel has a common reaction space above the bath level of these vessels.

In addition to the solution to the problem defined above, the system according to the invention has the advantage that in the case of continuous parting, or in the case of a discontinuous parting, only slight thermal cycling stresses take place on the refractory lining of the system parts.

As a result of the arrangement of the unit, which is preferably rigid compared to the foundation, formed from converter vessel and electric arc furnace vessel, there is no mechanical stress on the vessels, in particular the refractory lining thereof, due to tilting movements or weight displacements caused thereby. In addition, the refractory lining in the electric arc furnace is protected, since there a C-rich metal melt always has a reducing effect on the slag or reduces the FeO content of the slag. The temperature in the electric arc furnace is relatively low, e.g. less than 1600 ° C. For an optimal fresh process in the oxygen blowing converter vessel, it is advantageous if the tapping metal bath level of the oxygen blowing converter vessel is below the metal bath level of the electric arc furnace vessel, the bottom of the oxygen blowing converter vessel advantageously being arranged at a lower level than the bottom of the electric arc furnace.

The oxygen blowing converter vessel is preferably equipped with a blowing lance for oxygen or an oxygen-containing gas mixture.

According to a preferred variant, the oxygen blowing converter vessel is equipped with floor nozzles, preferably with oxygen blowing floor nozzles.

The electric arc furnace is advantageously equipped with at least one metal tapping device.

The slag tapping device is expediently provided on a decanter forming a unit with the electric arc furnace vessel, which is preferably diametrically opposite the overflow weir. This enables the slag that forms in the oxygen blowing converter vessel to flow into the electric arc furnace vessel in countercurrent to the molten metal.

The oxygen-blowing converter vessel and / or the electric-arc furnace vessel are expediently equipped with a charging opening for charging metallic feedstocks, ore, additives, alloys, carburizing agents and the oxygen-blowing converter vessel is also equipped with an oxygen-containing gas or afterburning nozzles and / or Lances equipped, preferably at least one of them in the vicinity of the transition between the two vessels.

According to a preferred embodiment, the electric arc furnace vessel is equipped with at least one preheating shaft which supplies fixed iron supports and is arranged above the electric arc furnace vessel and preferably on the side thereof or in a ring above the furnace vessel, as a result of which the introduction of preheated scrap and / or sponge iron or other iron carriers in a simple manner and by utilizing the heat content of the exhaust gases generated in the electric arc furnace vessel. The preheating shaft can be arranged centrally or decentrally and is preferably not equipped with gas-permeable shut-off elements (fingers), ie the preheating shaft opens directly and without obstacle into the electric arc furnace vessel. the fixed iron supports forming a column at the bottom of the electric arc furnace vessel.

According to a further preferred embodiment, at least one conveyor belt, preferably provided with a housing, opens into the preheating shaft, wherein heating devices, which are designed as afterburning devices and / or burners with lines supplying an oxygen-containing gas, installed in the housing, expediently open into the housing.

For efficient use of the energy introduced, at least part of the inner surface of the preheating shaft and / or the housing and / or the lid of the electric arc furnace vessel and / or the lid of the oxygen blowing converter vessel is advantageously lined with refractory materials.

The electric arc furnace vessel is preferably equipped with a device which supplies a molten metal, preferably pig iron.

According to an alternative embodiment, the electric arc furnace vessel is equipped with a preheating shaft, which is arranged above the electric arc furnace vessel and opens into the electric arc furnace vessel via a gas-permeable, cooled shut-off device.

An alternative embodiment is characterized in that the preheating shaft is arranged centrally above the electric arc furnace vessel and the lid of the electric arc furnace vessel is ring-shaped, surrounding the preheating shaft and connecting it with side walls of the electric arc furnace vessel, whereby Electrodes, preferably graphite electrodes, protrude obliquely through the lid into the interior of the electric arc furnace.

Appropriately, nozzles and / or lances and / or burners opening into the interior of the electric arc furnace vessel are provided, which either connect to an iron carrier feed device and / or an ore feed device and / or a carbon or carbon carrier feed device and / or a slag-forming feed device and / or an oxygen or an oxygen-containing gas feed device and / or a hydrocarbon feed device and / or an inert gas feed device are connected. Nozzles and / or lances are advantageously arranged in the oxygen blowing converter, which either connect to an iron carrier feed device and / or an ore feed device and / or a coal or carbon carrier feed device and / or a slag generator feed device and / or an oxygen or an oxygen-containing gas supply device and / or a hydrocarbon supply device and / or an inert gas supply device are connected.

The nozzles are preferably designed as sub-bath nozzles and / or floor-flushing stones or the lances are arranged to be movable, in particular pivotable and / or movable in their longitudinal direction.

According to a preferred embodiment, the electric arc furnace vessel is provided with an approximately centrally arranged electrode (s) projecting into the vessel from above and optionally with a bottom electrode.

For a diverse use of the system, the preheating shaft is preferably designed as a unit that can be separated and exchanged from the electric arc furnace vessel and from the housing.

For ease of handling, the lid of the electric arc furnace vessel and the lid of the oxygen blowing converter vessel form one unit or are designed as one unit.

At least one inspection and / or repair opening is expediently provided, preferably above the transition from the electric arc furnace vessel to the oxygen-gas converter vessel.

In order to avoid major interruptions in operation when individual parts of the system are in need of repair, an advantageous embodiment is characterized in that the oxygen-blowing converter vessel is designed as a removable and replaceable structural unit that can be separated from the electric arc furnace vessel.

The electric arc furnace vessel is preferably equipped with a bottom that slopes in the direction of the decanter and merges into an approximately horizontal bottom part of the decanter, the deepest point of the bottom being arranged in the decanter and at the lowest point of the bottom of the decanter a metal tap hole is provided. A method for producing metal melts, in particular steel melts, such as crude steel melts, is characterized by the combination of the following process steps:

A premelt is produced in the electric arc furnace vessel and brought to a specific temperature level and to a specific chemical composition,

The premelt flows continuously and irreversibly into the oxygen-blowing converter vessel via the overflow weir,

• The premelt is continuously refined in the oxygen blowing converter vessel, preferably to raw steel and

The fresh melt is discharged continuously or discontinuously from the oxygen blowing converter vessel,

• The slag that forms in the oxygen blowing converter vessel flows in countercurrent into the electric arc furnace vessel, from which it is drawn off.

It is useful to pre-refresh the metal arc furnace in the electric arc furnace vessel and to finish-finish the metal product in the oxygen blowing converter vessel.

A chemical composition and a temperature of the molten metal which correspond to the chemical composition and the temperature of the finished melt or of the end product, which are desired during the tapping, are preferably set in a continuous manner in the oxygen blowing converter vessel.

To set a high melting capacity, the exhaust gases formed in the oxygen blowing converter vessel are advantageously discharged via the electric arc furnace vessel, with a CO + H ₂ afterburning being carried out both in the oxygen blowing converter vessel and in the electric arc furnace vessel, the expediently Exhaust gases arising in the electric arc furnace vessel and the exhaust gases flowing over into the electric arc furnace vessel from the oxygen blowing converter vessel are used for preheating the lumpy charging material introduced into the electric arc furnace vessel.

The exhaust gases used for preheating are gradually burned for better energy utilization during the preheating process.

A negative pressure is preferably maintained in the electric arc furnace vessel and in the oxygen blowing converter vessel. An alternative advantageous process for producing pig iron melts is characterized by the combination of the following process steps:

Pig iron in liquid form is charged into the electric arc furnace vessel and brought to a certain temperature level,

The Si and P content is reduced when pre-freshening in the electric arc furnace,

The molten pig iron flows continuously via the overflow weir into the oxygen blowing converter vessel,

The molten pig iron is also continuously partially refreshed in the oxygen blowing converter vessel,

• The partly freshed pig iron is discharged discontinuously or continuously from the oxygen blowing converter vessel and

• The slag that forms in the oxygen-blowing converter vessel flows in countercurrent into the electric-arc furnace vessel from which it is drawn off, the partially-freshed (pretreated) pig iron expediently in a converter or electric-arc furnace in a conventional manner provided in addition to the system, with or without a feed is finished fresh from other iron carriers to a liquid end product.

The metallic insert mix is preferably composed of at least one of the following components

Scrap, such as steel scrap, and / or solid pig iron or cast iron,

Direct-reduced iron as pellets and / or briquettes and / or iron carbide,

• molten pig iron formed.

For the production of alloyed steel melts or stainless steel melts or stainless steel melts, the metallic insert mix is formed at least from alloyed steel scrap and liquid and / or solid alloying agents and / or ferroalloys.

The steel melt tapped off from the blast converter converter vessel is preferably further treated as a preliminary melt in a subsequent secondary metallurgical treatment including decarburization, either with or without negative pressure (vacuum). The vacuum treatment can be done with a VOD, RH-OB or a KTB system. The premelt already has a C content which is higher than required for the quality to be produced.

If the C content after treatment in the oxygen blowing converter vessel is already as low as desired in the finished melt, the oxygen blowing converter vessel will tapped steel melt treated as finished melt in a subsequent secondary metallurgical treatment, for example on a ladle furnace or rinsing station.

In order to avoid debris from the slag and to be able to regulate the quantity of the slag, a liquefaction or. Reduction treatment of the slag is carried out in the oxygen blowing converter vessel.

The invention is explained in more detail below with reference to several exemplary embodiments schematically illustrated in the drawing, FIG. 1 showing a vertical section through a system according to the invention according to a first embodiment and FIG. 2 a section along the line II-II of FIG. 1. 3, 4 and 5, 6 and 7, 8 and 9, 10 each illustrate alternative embodiments in representations analogous to FIGS. 1 and 2.

A furnace vessel 1 of a direct current electric arc furnace is provided as an intermediate vessel between a decanter 2 and a converter vessel 3 designed as an oxygen blowing converter, etc. with these vessels 2 and 3 each directly connected so that a coherent reactor system with three functional zones is formed. The furnace vessel 1 of the electric arc furnace serves primarily as a melting or melting reduction and heating zone, the converter vessel 3 mainly as a fresh and heating zone, and the decanter 2 as a decanting zone (settling zone). At the side of the furnace vessel 1, a preheating shaft 5 is placed on the lid 4 thereof, which can preferably be fed via a conveyor belt 8 with metallic feedstocks 7 - in particular steel scrap, possibly also solid pig iron and / or sponge iron. The conveyor belt 8 is expediently surrounded by a housing 6, so that a heating part 9 is formed in which the feed materials 7 can be preheated during the belt conveying with the aid of burners and / or post-combustion nozzles 10. Heating part 9 and preheating shaft 5 are directly connected to each other. In the lid 4 of the furnace vessel 1 there is at least one charging opening 11 for the continuous supply of solid, lumpy iron carriers 12 (directly reduced iron, fine scrap, pre-reduced iron ore, sinter, scale, filter dust and / or sludge briquettes, possibly fine scrap, etc. .), and / or carbon carriers 13, (coal, coke, compacts from organic light fraction etc.) and / or slag formers 14 (lime, fluorspar, quartz sand, bauxite etc.). The feed takes place via a conveyor belt 15 or conveyor belts. The unit of furnace vessel 1, converter vessel 3, decanter 2, preheating shaft 5 and heating part 9 forms the core of a first embodiment of the system according to the invention, which is shown in FIGS. 1, 2. The furnace vessel 1 has a single graphite version or, in the case of an alternating current version, preferably a plurality of graphite electrodes 16 for the supply of electrical energy. The electrodes 16 can optionally be pivotable within an inclination angle of 0 to 30 ° relative to the vertical in the direction of the center of the furnace vessel 1 and up to 10 ° in the opposite direction to the wall of the furnace vessel 1. The angle of inclination can be set or regulated differently for each individual electrode 16 and is usually approximately 15 to 20 ° during melting operation. As a rule, the electrodes 16 are vertical and cannot be pivoted. A bottom anode mounted in the center of the bottom 18 of the furnace vessel 1 serves as the counter electrode 17 (with direct current).

The metallic feedstocks 7 preheated in the preheating shaft 5 by the rising, hot exhaust gases 19 pass continuously into the furnace vessel 1 of the system due to the continuous melting process with continuous power supply.

The charging of solid iron carriers 12 with oxidic iron content (sponge iron, fine scrap, pre-reduced ore, dust briquettes etc.) and if necessary - of carbon carriers 13, such as coke, pellets from organic light fractions etc., and slag formers 14 (lime, fluorspar, quartz sand, bauxite etc.) - in the furnace vessel 1 takes place continuously via charging openings 10 in the lid 4 at a speed adapted to the melting process from the furnace vessel 1 and from the converter vessel 3.

Liquid pig iron 20 is continuously fed into the furnace vessel 1 via a pig iron feed device 21 which opens into the furnace vessel 1 and is designed as a channel. A slag door 22, which is preferably provided on the side of the furnace vessel 1 opposite the channel 21 and through which slag can also be removed, can be used to carry out a process control, to introduce an additional lance manipulator 23 and to carry out maintenance work in the region of the furnace vessel 1.

Given the shape of the system, charging and melting in the furnace vessel 1 is always carried out with liquid sump 24. This enables continuous, quasi-stationary melting operation with foam slag 25 and with an arc 26 that is almost completely enveloped by it. This results in a high transformer and thermal efficiency and low noise emissions.

Furthermore, we will meet the following requirements: • Processing of fine-grained iron carriers 12 '(eg iron carbide, sponge iron sieve residue, filter dust etc.), Generation or regulation of the foam slag 25,

• Accelerate the melting process of the feed materials 7, 12, 13, 14 through increased energy inputs into the electric arc furnace (including post-combustion of CO and H ₂ in the exhaust gas 19 inside or above the foam slag 25) and compensation of concentration and temperature gradients in the melt bath 24 such as

• Replacement of part of the electrical energy required by cheaper primary energies

into the furnace vessel 1,

• fine-grained iron supports 12 'and / or

• fine-grained coal 13 'or other carbon carriers (processed organic light fraction, e.g. shredder light fraction) and / or

• fine-grained slag formers 14 '(lime, fluorspar, etc.) and / or

• gaseous oxygen and / or other oxidizing gases 27 (CO ,, H, 0 etc.) and secondary air including air with 0 ₂ enrichment 28 and / or

• CH ₄ or other hydrocarbons 29 and / or

Inert gases 30 (N ₂ , Ar)

in regulated quantities, adapted to local and time requirements, over one or more

• Protected and / or unprotected nozzles and / or lances 32 (movable and / or permanently installed lances, optionally as combination lances / burners 32a) at various points in the lid and / or wall area of the electric arc furnace above and / or below the surface of the slag for blowing in at least one of the above-mentioned substances 12 ', 13', 14 ', 27, 28, 29, 30 and / or

• Protected under bath nozzles 33 (preferably high pressure nozzles) and / or floor flushing stones or under bath nozzles for blowing in at least one of the substances 12 ', 13', 14 ', 27 to 30 or flushing stones for inert gases 30 supplied. For reasons of clarity, not all of these devices are shown in FIG. 1.

From a certain amount of liquid sump 24, the molten metal 24 formed in the furnace vessel 1 runs into the converter vessel 3 via a weir 34 and is refreshed there until it is tapped and at the same time heated. For this purpose, the converter vessel 3 has at least one, preferably several - nozzles, etc. protected (natural gas protected - but Ar, C0 ₂ and higher hydrocarbons can also be used as protective gas) and / or non-protected nozzles, such as overbath nozzles for afterburning and / or lances 35 (movable and / or permanently installed lances if necessary as a combination Lances / burners) at various points in the lid and wall area of the converter vessel 3 above and / or below the surface of the slag for blowing up at least one of the substances 12 ', 13', 14 ', 27 to 30 and / or

- Protected under bath nozzles 36 and / or floor purging stones for blowing in at least one of the substances 12 ', 13', 14 ', 27 to 30 and purging stones for inert gases 30, and / or

- At least one opening 39 for adding lumpy iron supports 12, carbon supports 13 and slag formers 14 - individually or in combination

A preferred embodiment variant of the converter vessel 3 provides the following:

- Only gaseous oxygen 27 is blown over several lances 35. The lances 35 are arranged approximately symmetrically on the cover 37 of the converter vessel 3, are movable in the vertical direction and can at the same time be pivoted out within an angle of inclination of approximately 0 to 30 ° to the vertical in or against the flow direction 38 of the molten metal 24.

- Via a plurality of protected underbath nozzles 36 and / or flushing stones arranged in the bottom of the converter 3, only inert gas 30 (N, and / or Ar in any mixing ratio) is supplied. The under bath nozzles and / or flushing stones 36 are attached approximately symmetrically to the bottom of the converter vessel 3.

- Only lumpy slag formers 14 (lime, fluorite, quartz sand, bauxite etc.) and only via the lid opening 39 with the aid of the conveyor belt 40 are fed into the converter vessel 3.

- A control and repair opening 50 is attached approximately above weir 34.

The addition of the lumpy slag formers 14 through the lid opening 39 in the converter vessel 3 - approximately above a crude steel tap opening 41 - accelerates the lime dissolution or the formation of a reactive fresh slag 25 which has high iron oxide contents 3 in the region of the converter vessel.

Driven by its own gravity and by the impulse transmitted by the lances 35 and 35 ', the fresh slag 25 moves from the converter vessel 3 in the opposite direction to the molten metal 24 in the direction of the arrow 42 to the furnace vessel 1, whereby it acts on the molten metal 24 with ever decreasing temperature or increasing Content of Accompanying elements (C, Si, Mn, P, S etc.) meet and these are heated and freshened or cooled and reduced by this until the slag 25 is tapped through a slag door 22 at the end of the decanter 2.

The advantages of this "metal / slag countercurrent movement" are as follows:

1) Low heat and iron losses with the slag 25 when leaving the decanter 2 via the slag door 22 because, on the one hand, the slag 25 leaves the system on the “cold side” and, on the other hand, in addition to the iron oxide reduction that takes place primarily in the furnace vessel 1, a so-called “ Raining out "of metal droplets from the slag 25 in the decanter 2 is carried out.

2) Achievement of the desired steel quality with a significantly lower consumption of slag formers 14 or a lower specific amount of the slag 25 formed and consequently with less refractory wear of the plant. Since the amount of slag in the converter vessel 3 is determined by the level of the metal bath, long residence times or very good degrees of utilization of the slag can be achieved.

The hot exhaust gases 19 formed in the converter vessel 3 first get into the furnace vessel 1 and mix with the resulting exhaust gases before they then rise through the preheating shaft 5 and either (variant without heating part, Fig. 5, 9) the system through the exhaust pipe Leave 46 in the upper area of the preheating shaft 5 or get into the heating part 9 (variant with heating part, FIGS. 1, 2, 7, 8). On the way, depending on the local heat demand in the different parts of the system, the exhaust gases are partially post-combusted with oxygen 27, optionally with air 28 or air / oxygen mixtures via the lances 32, 35 and / or nozzles 47, nozzles 10 in the heating part. Under certain conditions of use and process control conditions, high degrees of post-combustion of over 50% when emerging from the furnace vessel 1, up to 90-100% when emerging from the preheating shaft 5 or from the heating part 9 are technically feasible. Thus, in the present process and plant concept, the vast majority of the chemical and sensible heat of the exhaust gases 19 to the metal bath 24 is either directly in the converter vessel 3 and in the furnace vessel 1 or indirectly through the preheating of the starting materials 7 in the heating part 9 and / or preheating shaft 5 transferred and used directly for the process. At the same time, the probability of uncontrollably high CO emissions is almost eliminated. The bed in the preheating shaft 5 performs a filter function and thus a reduction in the proportion of dust in the exhaust gas.

For the system and process concept according to the invention, there is a lower consumption of electrical energy compared to the conventional electric arc furnace without scrap preheating (by approx. 25 to 40%) and to the discontinuously operated electric arc furnace with integrated scrap preheating (by approx. 15 to 25%) with the same ingredients. The system productivity is roughly doubled compared to the conventional electric arc furnace without scrap preheating with the same size and configuration of the arc furnace (transformer power, lances, burners, etc.).

Design of the plant

The design of the individual parts of the system, such as

- furnace vessel 1,

- preheating shaft 5,

Heating part 9 (if provided, preferably with> 30% scrap in the insert mix),

- converter vessel 3,

- decanter 2,

- The number and arrangement of the charging openings 11 in the furnace vessel 1 and 39 in the converter vessel 3 is dependent on

- The starting materials to be used, in particular the iron carriers 7 (shape, size, composition, temperature and physical state)

- the desired production output

- the demands regarding steel quality

- the desired mode of operation of the plant (continuous or semi-continuous - with discontinuous tapping), also with regard to the desired integration with upstream and / or downstream plants (e.g. for pig iron extraction, direct reduction, secondary metallurgical treatment, continuous casting, etc.)

- the type and prices of the available energy sources.

The main goal in the design is to preheat, charge, melt or reduce melt, refresh, heat and cut-off the process steps within the system at the same time, but at different locations and thus as independently of one another as possible in different parts of the system with a controllable process under favorable physical-chemical processes, to carry out reaction-kinetic and thermal conditions, ie to receive an overall system of almost perfectly (highly effective) working partial reactors for the specific application.

The configuration of the system according to the invention enables the system area, consisting of oven vessel 1 and decanter 2, to be emptied independently of one another (Via the tap opening 43) and the converter vessel 3, on the other hand, via the tap opening 41 without requiring a tilting of the entire system, which means that control and minor repair work in the hot state of each of these two areas can be carried out at short notice with throttling of the system. According to the invention, all parts of the system are preferably locked together during operation as a unit, or cannot be moved or tilted. Due to the preferably section design of both the lower vessel and the lid 4 and 37 of the system, individual or several parts or vessels requiring repair can be replaced after extending laterally (this also applies to the preheating shaft 5). In order to avoid long production interruptions, the interchangeable container concept is preferred, ie ready-to-use, possibly preheated stand-by containers (e.g. converter container 3 and a unit consisting of furnace container 1 and decanter 2) are available at short notice.

System variants depending on the application mix (guidelines for choosing the overall system configuration):

An overall system configuration with scrap preheating shaft 5 and heating part 9, as shown in FIG. 1, can be used if a certain minimum proportion of solid scrap 7 is used in the mix of operations. The following table I can be used as a general guideline for the selection of the overall system configuration depending on the application mix:

Table I

3, 4, the scrap portion 12 in the furnace vessel 1 and / or in the converter vessel 3 is supplied via the lid openings 11 and 39 with the aid of conveyor belt and slide systems 15, 15 'and 40, the maximum dimension of the scrap pieces 12 must not exceed a certain dimension (e.g. 200 mm). 5, 6, the scrap preheating shaft 5 has only a small cross section, since only a little scrap is charged and it is continuously filled by a scrap conveyor belt 8 without a preheating function, ie without a heating part 9. With this variant, oversized scrap pieces may have to be sorted out and cut before use. The exhaust gases are removed in the upper, so-called hood area 5 ′ of the scrap preheating shaft 5 via the exhaust line 46.

According to the variants shown in Figs. 1, 2 and 7, 8, at least one scrap preheating shaft 5 is replaced by at least one scrap conveyor belt 8 with a preheating function, i.e. filled continuously by means of a heating part 9. Here are dependent on

• the use mix (especially scrap portion)

• the space and height conditions in the specific application (factory layout)

• the desired operating parameters (system productivity, consumption of electrical energy, availability of fossil fuels, such as natural gas, coal, etc.) e.g. The following variants of scrap preheating shaft 5 and heating part 9 are possible:

• A scrap preheating shaft 5 with a heating part 9 with a scrap conveyor belt 8 or a plurality of scrap conveyor belts 8 arranged in parallel (FIGS. 1, 2).

• Two scrap preheating shafts 5 (FIGS. 7, 8), each with one or a common heating part 9, each heating part 9 enclosing at least one scrap conveyor belt 8.

The exhaust gases 19 are removed via a hot gas line (not shown) arranged at the beginning of the heating part 9.

According to the variant shown in FIGS. 9 and 10, a preheating shaft 5 with a gas-permeable and water-cooled shut-off device 5 ″ is placed on the lid 4 of the furnace vessel 1, which preferably uses a conveyor belt with metallic feedstocks 7 - in particular steel scrap, and possibly also pig iron 15. The furnace vessel 1 has a plurality of cathodically connected, inclined graphite electrodes 16, which are optionally designed as hollow electrodes, preferably in a symmetrical arrangement with respect to the electric arc furnace and the preheating shaft 5. The electrodes 16 are within an inclination angle of 0 to 30 ° relative to the vertical in the direction of the center of the furnace vessel 1 and up to 10 ° in the opposite direction towards the wall of the furnace vessel 1. The angle of inclination can be set or regulated differently for each individual electrode 16. It is during melting usually about 15 to 20 °. Occasionally, the pivotability of the Electrodes 16 are dispensed with. A bottom anode mounted in the center of the bottom 18 of the furnace vessel 1 serves as the counter electrode 17.

The basic principles of process function and technology management can be summarized as follows:

Supply of the input materials / process media and removal of the products:

Continuous supply of the input materials and media at a controllable speed into the furnace vessel 1 (main quantity) and at the same time into the converter vessel 3 (a partial quantity thereof as a coolant).

Continuous removal of the products from at least two parts of the system, preferably crude steel from the converter vessel 3 and slag 25 from the decanter 2 directly connected to the furnace vessel 1, as well as exhaust gas 19 depending on the system configuration according to the application mix:

From the furnace vessel in the system variant Fig. 3, 4,

• from the preheating shaft 5 in the system variant Fig. 5, 6 and variant Fig. 9, 10 or

From the heating part 9 in the system variant FIGS. 1, 2 and 7, 8.

There is the possibility of discontinuous crude steel tapping from the converter vessel 3 with or without throttling of the entire system, with a barrier dam being placed on the overflow weir 34 on the furnace side in the event of high demands regarding crude steel quality, in order to allow the return flow of the furnace slag 25 into the converter vessel 3 during the discontinuous crude steel tapping and afterwards ( until the same slag levels are created in the furnace vessel 1 and in the converter vessel 3).

Timing and mixing ratios:

• With continuous crude steel tapping - continuously semi-steady state with regard to temperature, concentration, flow, mixing and quantity ratios for metal, slag and exhaust gas in every vessel of the overall system.

• In the case of discontinuous crude steel tapping - with a distinctive tapping cycle with regard to the above-mentioned criteria regarding metal and slag in converter vessel 3 and slag in furnace vessel 1, otherwise semi-stationary. Regardless of the type of crude steel tapping (continuous or discontinuous), the following process sequence conditions are continuously met: → intensive bath mixing in furnace vessel 1 and converter vessel 3, → high reaction and heat exchange area in all system parts, -> crude steel in converter vessel 3 is always used for tapping desired composition and temperature kept.

Preheating, melting, freshening and temperature control:

There is a gradual change in the physico-chemical properties of the input materials (in particular the temperature, the chemical composition and the state of matter) with regard to the production of a crude steel melt as the main product and of slag and exhaust gas as by-products with optimal use of energy according to the following scheme:

In the heating section 9 and preheating shaft 5:

Preheat the scrap (up to 100% of the scrap in the insert mix)

Consideration of the criteria for the selection of the system configuration, with preheating to a low temperature, e.g. Max.

400-450 ° C and in preheating shaft 5 (if provided) preheating to higher

Temperature, e.g. > 800 ° C (scrap preheating temperatures of 1000 ° C and more are quite possible, if necessary using a lined preheating shaft).

In addition to scrap, other feedstocks can also be preheated, e.g.

* lumpy slag formers (dolomite, quartzite etc.),

* Coal or coke,

* If necessary, sponge iron (up to a limited proportion of the input materials via heating section 9 and / or preheating shaft 5), but taking into account possible undesirable phenomena (reoxidation, increased sponging etc.) depending on their residence time and the preheating temperature in heating section 9 and / or Preheating shaft 5. In the oven vessel 1:

+ Melt the major part (main quantity) of the feed materials in the feed mix (except for the smaller part of the feed materials used as coolant in the converter vessel 3) and at the same time

+ Carburizing and pre-freshening the metal with the aim of producing one

Premelt with the following properties depending on the application mix:

% Si <0.10

% C = 1.0 - 3.0

T = 1540-1560 ° C (0 approx. 1550 ° C),

which premelt overflows into the converter vessel 3, the average decarburization speed depending on the feed mix being from 0.06 to 0.10 (max. 0.12)% C / min, and + with continuous feed of cold feed mix- Components, e.g. Sponge iron and / or iron carbide, possibly fine scrap and / or hot insert mix components, e.g. liquid pig iron (from an upstream blast furnace or a smelting reduction), hot sponge iron and or iron carbide and coal and or fine coal (coke, SLF), lumpy and or dusty slag formers (lime, dolomite, quartzite, fluorspar, etc.).

In converter vessel 3:

+ Continuous final freshening (mainly decarburization and deep dephosphorization) and at the same time heating of the C-rich melt that always overflows from furnace vessel 1 to the desired and already (always) set composition and temperature of the crude steel in the converter vessel with concentration and temperature compensation through intensive bath mixing (homogenization ) at

+ Continuous supply of chunky and / or fine-grained coolants (including insert mix components) and / or slag formers, and / or carbon carriers, e.g. iron sponge and / or iron carbide, fine scrap, ore, tinder, metallurgical dust / sludge, limestone, dolomite , Lime, quartzite, fluorspar etc, coal, (coke), processed shredder light fraction and + without interruption of the fresh process during a, if provided, discontinuous crude steel tapping, ie without interruption and significant influence on the process in the upstream parts of the plant (if necessary, slight throttling can be carried out),

+ whereby the preferred decarburization rate is 0.08 to 0.13 (max. 0.15)% C / min depending on the feed mix.

Slag guide

The process concept is based on a countercurrent movement of metal 24 and slag 25 in the furnace vessel 1 / converter 3 area, i.e. the slag moves from the converter vessel 3, the part of the plant with the highest temperature and the highest oxygen potential of the metal bath, over the furnace vessel 1 - this has a lower temperature and a lower oxygen potential of the metal bath, because it contains a C-rich molten metal - in the direction of Slag door 22 at the end of the decanting part 2, where the slag 25 can only leave the system. The driving force of this movement of the slag 25 is above all gravity, supported by impulses which are transmitted to the slag 25 as a result of the intensive bath mixing in the converter vessel 3 and in the furnace vessel 1. During this movement (in particular when crossing the furnace vessel 1), the slag 25 encounters metal melt 24 with a low temperature and higher contents of Si and C and is reduced by this, because of the intensive bath mixing, with respect to FeO content and at the same time cooled. In addition, the subset of the slag 25 from the converter vessel 3 mixes with non-metallic phases formed in the furnace vessel 1 and in the decanting part 2, etc.

- from the gait and ash of the insert mix components (sponge iron, HBI, iron carbide, scrap etc.),

- from the oxidation of Si, Mn, P and other oxygen-related elements in the insert mix (liquid and / or solid pig iron, scrap, etc.),

from the slag formers supplied to the furnace vessel 1, which e.g. added as correction / surcharge,

- From the refractory wear in the furnace vessel 1 and in the decanter 2, whereby the amount of slag 25 formed in the furnace vessel 1 is significantly higher than that of the slag formed in the converter vessel 3. After a certain "calming down" of the slag 25 in the decanting part 2 (without intensive bath mixing) and partial raining out of the metal drops contained therein, the slag 25 leaves the system through the slag door 22 at the end of the decanting part 2. An important process feature in contrast to discontinuous processes is that the specific amount of slag, based on the amount of metal in the converter vessel 3, is not the same as the very small amount of slag per ton of overflow from the furnace vessel 1, but much higher and at Operation with continuous crude steel tapping and almost constant level of the molten metal in the converter vessel 3 is determined by the height difference between the furnace vessel 1 and the converter vessel 3 or can be regulated within certain limits. This process feature also means that the residence time of the slag 25 formed in the converter vessel 3 (with very good properties with respect to dephosphorization and desulfurization) in the converter vessel 3 is considerably longer than, for example, in a discontinuous LD converter and can also be regulated, which results in the following advantages : - »better use of the refining properties of the converter vessel 3 supplied

Slag formers, -> • Possibility of achieving very low P and S contents in the crude steel (the process and plant configuration also contributes to this, which basically corresponds to a discontinuous process with intermediate removal of a partial amount of slag), → no risk of deterioration for the oxygen Blow lance 35 in the converter vessel 3 due to a very small amount of slag, which, for example in discontinuous converter processes with the use of pretreated pig iron (deSi + deP) and low-slag freshening (slag minimum process) at <30 kg slag / t steel is known to occur.

In order to make better use of the slag formers supplied in the furnace vessel 1, it is advantageous to supply them in the finest possible form so that they dissolve in the slag 25 as quickly and completely as possible. This applies in particular to lime and dolomite. The preferred supply of up to 100% of the lime or dolomite in the furnace vessel 1 in fine-grained condition (as dust lime or dust dolomite) can also significantly reduce the negative impact of the so-called hot spots in AC furnace designs. Chunky slag formers are preferably fed into the converter vessel 3 (fine-grained slag formers only when extreme requirements with regard to the raw steel quality have to be met).

The properties according to the invention of the slag 25 in the converter vessel 3 and in the furnace vessel 1 (approximately identical to the end slag when it emerges from the slag door 22 at the end of the decanting part 2) can be summarized as follows: Converter slag in the area of technical lime saturation

% CaO /% Si0 ₂ > 3.4

% MgO> 7

% FeO _n = 25-30 for crude steel

% C = 0.03-0.05 T _Absnch = 1620-1630 ° C preferred addition of lumpy slag formers (lime, dolomite, quartzite) preferred residence time in the converter vessel 3:> 80 min

Furnace slag = final slag when leaving the plant% CaO /% Si0 ₂ = 1.8-2.0% MgO> 7% FeO _n = 10-15% with premelt

% C = 1.0-3.0 _θbCTlauf ⁼ 1540-1560 ° C

EAF → LD preferred supply of fine-grained slag formers (especially dust lime, ^■ dust dolomite) via several nozzles / lances in / through the furnace cover 4, material supply into the hot spot areas

These basic principles of slag control also apply to the process variant with discontinuous crude steel tapping. There is no significant difference due to the dam that may be used in this case, which is only used for high quality requirements.

Exhaust characteristics (recording, post-combustion, temperature, dust and toxic components in the raw gas):

Exhaust gas from the converter vessel 3 and furnace vessel 1 is drawn off uniformly through the possibly existing scrap preheating shaft 5 and possibly through the heating part 9, the chemical and physical exhaust gas heat being used optimally (divided); if no preheating shaft 5 is provided, the exhaust gases pass from the furnace vessel 1 into the directly connected hot gas line. Almost 100% exhaust gas detection takes place through an encapsulated system with a minimum of uncontrolled emissions or a minimum exposure to heat, dust and toxic exhaust gas components, since no part of the system is opened for charging operations is required. The exhaust gases are increasingly afterburned on the way from the converter vessel 3 to the furnace vessel 1 and further to the preheating shaft 5 and to the heating part 9, depending on the need and the mix of uses.

The following guide values:

Preferred media for exhaust gas afterburning

Media type Preferred use of converter vessel 3

0 ₂ + air oven vessel 1, preheating shaft 5 air heating part 9

O / air mixtures with a freely adjustable mixing ratio are available for all parts of the system.

Additional heat sources / energy supply to cover the heat requirement Guide values according to the following table:

incl. heat of slag formation for slagging oxidation products Embodiments

The following three exemplary embodiments explain the technological processes and the achievable results when using the process and plant variants according to the invention for the continuous production of crude steel from the world's most important starting materials (iron carriers), such as steel scrap, sponge iron and liquid pig iron. The mix of uses is different for each embodiment, namely:

Embodiment 1: 100% steel scrap

Embodiment 2: 40% steel scrap

30% sponge iron

30% molten pig iron Example 3: 50% sponge iron

50% liquid pig iron

The process and plant variants according to the invention also enable the continuous production of crude steel from 100% sponge iron or from 100% liquid pig iron, in the latter case ore, carbonate, scale, dust briquettes etc. can be used individually or in combination as a coolant.

In addition to the Fe-containing feedstocks, those for the

Steel making practice usual

Supplements: soft burnt lime, dolomite, quartzite

Gases: oxygen, nitrogen, natural gas, air (compressor and fan)

Solid coal: coal, fine coal (blown coal)

Refractory materials: stones for delivery in the furnace as well as in the converter vessel 3,

Spray compounds (repair) graphite electrodes: for furnace vessel 1 and cooling water: for water-cooled panels of furnace vessel 1, des

Preheating shaft 5 and the heating part 9 used. Although more cost-effective and / or advantageous in terms of better steel quality, a possible application of alternatives is considered in the next exemplary embodiments

Fe-containing feedstocks: solid pig iron as Fe carriers and / or as coolants: iron carbide, filter dust, scale, dried

Mud, ore (Fe / Mn ore) Additives: fine lime, fine dolomite, fluorspar

Media: Ar (for inert gas flushing) Energy sources: Shredder light fraction dispensed with.

The quality and the temperature of the available feedstocks and gases can be seen from Tables II, III and IV.

The following system configurations are used to carry out the process:

Embodiments 1 and 2: Plant according to FIG. 1 consisting of

A heating part 9 (conveyor belt 8 with preheating function)

• A scrap preheating shaft 5 with an oval cross section

• An oven vessel 1 designed as an AC-EAF as a melting and pre-freshening vessel

A converter vessel 3 of the type LD-S ^*

• a decanting part 2 belongs to the furnace vessel 1

Example 3:

3, consisting of

• An AC electric arc furnace as furnace vessel 1, as a melting and pre-freshening vessel

A converter vessel 3 of the type LD-S ^*

• a decanting part 2

'' Converter with inert gas purging N _; / Ar Table II

Chemical composition and temperature of the Fe-containing feedstocks

Steel scrap 0.30% C 2.5% ash

0.50% Mn 0.2% moisture

0.20% Si

0.030% S 25 ° C

0.020% P

Sponge iron pellets 91.9% FE _dead

(MIDREX-DRI)

92.9% degree of metallization

1.8% C

4.6% gait approx. 0.5 gait basicity

25 ° C

Molten pig iron 4.2% C 1320 ° C 0.5% Mn 0.6% Si 0.04% S 0.09% P

Table III

Chemical composition, grain size and temperature of aggregates, solid energy sources and refractories

Table IV

Chemical composition (vol.%), Temperature of gases

Rest C (firing in red.atm at 1000 ° C - British Coking Test) In all three design cases, the furnace vessel 1 and the converter vessel 3 have the following identical configuration and equipment, the specification relating to conventional discontinuous systems in accordance with standard series:

Specification of the furnace vessel 1:

- approx. 6 m vessel diameter corresponds to a discontinuous tapping weight of 90 t crude steel with approx. 11 t liquid sump (residual sump),

- 70 MVA transformer power, AC,

- three pieces of graphite electrodes 16 with a diameter of 560 mm (no bottom anode 17 because AC supply),

a pig iron trough 21 for the continuous supply of liquid pig iron 20,

two charging openings 11 in the lid 4 for the continuous supply of sponge iron pellets and / or fine scrap 12, coal 13 and lumpy slag formers (lime, dolomite, quartzite) 14, which are transported in via a conveyor belt and slide system 15,

three pieces of lime nozzles in the lid 4 of the furnace vessel 1 for the continuous blowing in of up to 100% of the amount of lime and dolomite supplied in the furnace vessel 1 as dust lime or dust dolomite 14 into the hot spots by means of air 28 as carrier gas,

- Two pieces of water-cooled manipulator lances (a lance 32 through the side wall of the furnace vessel 1, a lance 23 through the slag door 22 in the decanting part 2 reaching into the furnace vessel 1) for continuously blowing in gaseous oxygen 27 and / or fine coal 13 (air 28 as carrier gas ) below the surface of the slag 25 in the furnace vessel 1,

three pieces of coal under bath nozzles 33 for the continuous blowing in of fine coal 13 by means of air 28 as carrier gas,

six pieces of inert gas under bath nozzles 33 for the continuous blowing in of inert gas 30 (N ₂ / Ar, ratio arbitrarily adjustable) for the purpose of intensive mixing of metal 24 and slag 25 in the furnace vessel 1,

three pieces of 0, under bath nozzles 33 for the continuous blowing in of gaseous oxygen 27, the O, under bath nozzles 33 being protected with natural gas or LPG (liquid propane gas) 29 and preferably arranged in the bottom of the furnace vessel 1 below the scrap preheating shaft 5,

- five natural gas / oxygen burners 32a with a capacity per burner of max. 3.5 MW, which are arranged in the side wall of the furnace vessel 1 approximately symmetrically below the scrap preheating shaft 5, three pieces of post-expansion nozzles 35 in the cover 4 of the furnace vessel 1 for gas oxygen 27 and / or air 28 (0 / air ratio can be set as desired), which are preferably designed as movable short lances, ie as post-combustion lances,

a lid 4 of the furnace vessel 1, which is made on the outside of water-cooled panels which are provided with a refractory layer from the inside (furnace space),

a large part of the side wall of the furnace vessel 1 on the side of the converter vessel 3, which is designed as a weir 34, which on the one hand divides the lower part of the system into a furnace vessel 1 and a converter vessel 3, and on the other hand forms an upper part common to both vessels, so that a continuous transfer of molten metal 24, slag 25 and exhaust gas 19 between the reactor parts 1 and 3 is achieved only by means of gravity, with metal 24 flowing in the opposite direction to the slag 25 (so-called metal / slag countercurrent movement), the exhaust gases the subspaces in the furnace vessel 1 and converter vessel 3 are driven by the scrap bed 7 in the furnace vessel 1 and the scrap preheating shaft 5 lying directly above them by the uniform exhaust gas extraction, or, as shown in FIG. 3, directly from the furnace vessel 1 into the hot gas line of the exhaust gas treatment system, not shown, if the total layer configuration does not provide a scrap preheating shaft 5 and or heating part 9.

Specification of converter vessel 3:

- Internal volume after relining approx. 76.5 m \

- specific volume approx. 0.85 m ³ / t metal content (corresponds approximately to a discontinuous tapping weight of approx. 90 t / crude steel for conventional systems),

- a piece of water-cooled converter lance (top lance) for inflating max. 10000 Nm ³ 0, / hour,

three pieces of afterburning nozzles 35 for gas oxygen 27 and / or air 28 (O ₂ / air ratio can be set as desired) in the lid 37 and in the upper conical part of the converter vessel 3, which are preferably designed as movable short lances, ie as afterburning lances,

- Two charging openings 39, preferably only one in operation (only one of them is shown in FIGS. 1 and 3) in the converter cover 37 for continuous feeding of fine scrap (here shredder scrap with a piece size of <100 mm) and / or sponge iron pellets (DRI ) 12, lump coal 13 and lumpy slag formers (lime, dolomite, quartzite) 14, which are transported in via a conveyor belt / slide system 40,

six pieces of inert gas under bath nozzles 36 for the continuous blowing in of inert gas 30 (N ₂ / Ar, ratio arbitrarily adjustable) for the purpose of intensive mixing of metal 24 and slag 25 in the converter vessel 3, a crude steel tapping opening 41 with a control unit for the tapping speed of the crude steel 24 and an automatic closure device (not explained in more detail here) for interrupting the otherwise continuous tapping process if necessary,

- A lid 37 of the converter vessel 3 which is designed in an identical design as the lid 4 of the furnace vessel 1 and forms a unit (section design) with it in the locked state during operation. Approximately above the weir 34, it is provided with a control and repair opening 50. This remains closed during the continuous process.

Specification of the scrap preheating shaft 5, the heating part 9 and the scrap conveyor belt 8:

In order to meet the very different requirements regarding scrap supply and preheating for the three execution cases considered (100%, 40%, 0% scrap in the mix of operations), the following facilities are provided:

1. A scrap preheating shaft 5 with a large internal useful cross section of approximately 11.5 m ² and rounded edges, as shown in FIGS. 1 and 2.

- Approx. constant shaft cross-section over the shaft height,

- shaft height above the lid 4 of the furnace vessel 1, i.e. about 6.50 m above the shaft opening level into the furnace vessel 1 to the upper hood area (cover) of the preheating shaft 5, whereby

the preheating shaft 5 is formed from water-cooled panels which are provided on the inside in the upper hood area with refractory plates (as can be seen in FIG. 1),

the preheating duct 5 is provided with twelve post-combustion nozzles 47 for oxygen 27, air 28 or an oxygen / air mixture, these post-combustion nozzles 47 being arranged approximately symmetrically on the outer duct perimeter in two levels, each with six nozzles per level,

- Two natural gas / oxygen / air combi burners 10 are arranged in the upper hood area of the preheating shaft 5, which can also be used as afterburning lances and as a burner with max. 3.5 MW can be operated per burner.

In principle, the entire preheating shaft 5 can be made of water-cooled panels with an inner lining, whereby the following advantages can be achieved: - »little heat loss with the cooling water in the preheating shaft or a smaller amount of cooling water is necessary → higher scrap preheating and flue gas temperatures can be set at the exit of the shaft without risk of malfunction.

2. A scrap preheating shaft 5 with a small inner useful cross section of approximately 5 m ² and rounded edges (as shown in FIG. 1):

- Approx. Constant shaft cross-section over the shaft height,

- total shaft height approx. 6.50 m, whereby

- the preheating shaft 5 consists of water-cooled panels which are provided on the inside in the upper hood area with refractory plates,

the preheating duct 5 is provided with eight post-combustion nozzles 47 for oxygen 27, air 28 or oxygen / air mixtures, these post-combustion nozzles 47 being arranged approximately symmetrically on the outer duct perimeter in two levels, four nozzles per level,

- In the upper hood area of the shaft 5, a natural gas / oxygen / air combi burner 10 is arranged, which can also be used as a post-combustion lance and as a burner for an output of max. 3.5 MW is designed.

3. A heating part 9 is provided with two identical scrap conveyor belts 8 arranged parallel to one another within the heating part 9, which are spatially separated from one another within the common housing by a refractory dam (not shown in the drawings). The design of the heating part 9 and the scrap conveyor belts 8 can be summarized as follows:

Scrap conveyor 8

Number (same version): 2

Band width: 2.0 m

Band length: 40.2 m

Average strip load (t scrap / m ² strip area): 0.30 t / m ²

Belt speed: max. 8 m / min

Scrap conveying capacity per belt 8: max. 4.8 t / min

Heating part 9

Form of housing above: part-circular, water-cooled panels with walling on the inside below: rectangular, water-cooled panels, without

Masonry Ten natural gas / oxygen / air combi burners / lances 10 (in burner operation with max.3.5 MW per burner or in operation as post-combustion lance with max. 3000 NmVh air or air / O, mixture per lance 10), which in two Rows (five pieces per row) are arranged symmetrically above each of the two scrap conveyor belts 8 in the brick cover of the heating part 9.

A vertically aligned refractory dam (wall), which divides the entire interior of the heating part 9 in the longitudinal direction into two sub-spaces that are almost completely separate from one another, each with a scrap conveyor belt 8.

Process flow and results

Embodiment 1

The insert mix consists of 100% steel scrap (mixed scrap) with the composition according to Table II. The system variant according to FIG. 1 with the scrap preheating shaft 5 with an internal useful cross section of serves to carry out the method

11.5 m ² and with two scrap conveyor belts 8 (belt width 2.0 m, belt length 40 m), which are arranged side by side in parallel and before unloading the scrap 7 in the

Preheating shaft 5 pass through a common, 10 m long heating part 9, the

Heating part 9 opens directly in the upper hood area of the preheating shaft 5.

A small portion (11.50%) of the scrap with a piece size of <100 mm is fed continuously as a coolant 12 into the converter vessel 3 at a temperature of 25 ° C. The rest of the scrap with a max. A scrap piece length of 1.5 m (ie the main part quantity 7 of 88.50%) is charged onto the two scrap conveyor belts 8 with the aid of four scrap loading cranes and, after preheating in the heating part 9 and in the preheating shaft 5, is continuously fed to the furnace vessel 1 and melted there. The average height of the scrap column 7 in the preheating shaft 5 is approximately 2.5 m. The sensible heat (enthalpy) and chemical heat (heat from the partial afterburning) of the exhaust gases flowing mainly from the furnace vessel 1 into the preheating shaft 5 and into the heating part 9 serve as the heat source for preheating the scrap 7 in the heating part 9 and in the preheating shaft 5 19 as well as the heat from a certain scrap oxidation taking place during the preheating of the scrap. The partial afterburning of the exhaust gases 19 in the preheating shaft 5 takes place in two stages, with cold air 28 and gas oxygen 27 being blown in continuously by the twelve post-combustion nozzles 47 arranged in two levels in a volume ratio of approx. In the heating part 9, the afterburning takes place gradually along the heating part 9 by means of continuous Blowing in cold air 28 through a total of ten combination burners / lances 10 (here only as afterburning lances), which are arranged in the lid of the heating part 9 (2 x 5 combination burners / lances 10 above each scrap conveyor belt 8).

Important process variables for the process sequence in the heating section 9 and in the preheating shaft 5 are given in the following table:

The continuous melting of the scrap 7 preheated in the heating part 9 and in the preheating shaft 5 takes place in the furnace vessel 1, the resulting metal melt 24 in the furnace vessel 1

including non-metallic components '' part of the furnace vessel 1

(t Met.Product / t Met.Eιπsatz) xl00 at the same time to a low-Si, but C-rich melt with the properties

1.86% C approx. 1550 ° C

0.20% Mn <0.05% Si liquidus temperature approx. 1400 ° C

0.032% S 0.005% P

is carburized and partially refreshed before it overflows over the weir 34 into the converter vessel 3. The molten metal 24 in the furnace vessel 1 always has approximately the properties mentioned above.

The melting and fresh process in the furnace vessel 1 runs continuously and takes place quasi-steadily with very intensive bath mixing with continuous supply of the following substances, media and energies or under the following process conditions:

4.61 t / min preheated scrap 7 with a temperature of approx. 834 ° C,

liquid, FeO _n -rich, highly basic (CaO / SiO ₂ = 3.55) and hot converter slag 25 with a temperature of approximately 1620 ° C., which flows from the converter vessel 3 against the metal flow direction via the weir 34 into the furnace vessel 1,

- Lime 14 (approx. 60% thereof as blown lime via the lime nozzles 35 and approx. 40% thereof as lump lime via the charging openings 11 in the lid 4 of the furnace vessel 1, blown lime / lump lime ratio can be changed as desired),

- Charcoal (piece coal) 13 via the charging openings 11 in the lid 4 of the furnace vessel 1,

Blow coal (fine coal) 13 via the manipulator lances 32 and 23 as well as via the coal under bath nozzles 33 of the furnace vessel 1,

Natural gas 29 and gas oxygen 27 via the burners 32a of the furnace vessel 1,

N, 30 and natural gas 29 via the inert gas bottom nozzles 33 of the furnace vessel 1,

Gas oxygen 27 via the manipulator lances 32 and or 23 of the furnace vessel 1,

Gas oxygen 27 via the afterburning lances 35 in the lid 4 of the furnace vessel 1,

Converter exhaust gas 19 including dust in the converter exhaust gas, which flow directly from the converter vessel 3 into the furnace vessel 1,

False air, which is sucked in from the outside into the furnace vessel 1 due to the negative pressure in the furnace vessel 1, above all through the slag door 22, but also via electrode gaps in the lid 4,

Blow air 28 as conveying gas via the lances / nozzles 35, 32, 23 and 33,

- About 53.1 MW continuous electrical energy input via the electrodes 16 to cover the heat requirement in the furnace vessel 1, which entry in the Total plant productivity of approx. 4.87 t crude steel / min (approx. 292 t crude steel / operating hour), which corresponds to an electrical energy consumption of approx. 181.6 kWh / t crude steel.

The products of the furnace vessel 1 are also continuously and semi-continuously removed, including:

4.46 t / min C-rich, low-Si melt 24 with the above-mentioned properties via the weir 34 in the direction of the converter vessel 3,

- approx. 416 kg / min slag 25 with the following properties:

approx.12.2% FeO _n 0.46% P, 0 ₅ approx.5.0% Fe _met 0.21% S

40.9% CaO basicity (CaO / SiO,) = 2.0

7.8% MgO temperature ~ 1550 ° C

5.8% MnO 20.4% SiO, 7.0% A1.0 ₃

which continuously leaves the system via the decanting part 2 through the slag door 22,

- approx. 522 NmVmin exhaust gas 19 and approx. 79.1 kg / min dust in the exhaust gas with the following properties

Flue gas (gas phase ^) Flue gas f. Dust

37.0 vol.% CO 72.5% FeO _n

23, l vol.% C0 ₂ 9.0% CaO

3.3 vol. % H, 3.4% SiO,

8.4 vol. % H ₂ O 4.8% C 25.8 vol. % N ₂ 5.7% ZnO

1, 7 vol. % O, balance = MgO + MnO + Al, O ₃ + SnO, + P, 0 ₅

Rest = Ar + SO, + F, total degree of afterburning 43.9% temperature - 1570 ° C which get from the furnace vessel 1 into the scrap preheating shaft 5.

After the overflow over the weir 34, the C-rich, low-Si melt reaches the converter vessel 3 continuously and mixes with the crude steel melt 24 which is always present in the converter vessel 3 during a very intensive bath movement Properties regulated within narrow tolerances:

- quantity of approx. 90 t,

- metal bath level in converter vessel 3 approx. 0.5 m below the level of weir 34,

- Composition (in particular C content) and temperature equal to the desired crude steel tapping values, in the present case as follows:

C = 0.05% T = 1620 ° C

Above the crude steel melt 24, the liquid converter slag 25 collects in the converter vessel 3, the surface of which at a slag layer height in the converter vessel 3 of approximately 1.8-2.0 m up to 0.5-1.0 m higher than that in the furnace vessel 1 lies and as a result, driven by gravity and impulses from the bath movement in the converter vessel 3, continuously overflows via the weir 34 into the furnace vessel 1.

This results in the following task for the technology management in converter vessel 3, which is carried out continuously / continuously:

- Fresh and heating of the C-rich, Si-poor premelt flowing in from the furnace vessel 1 to the desired properties of the crude steel 24 when tapping from the converter vessel 3 via the crude steel tap opening 41 and at the same time mixing this partial flow of the metal melt with the metal bath 24 which is always present in the Converter vessel 3, ie Homogenizing the crude steel melt 24, which flows out or is tapped through the tap opening 41, in the converter vessel 3,

- Removal of the converter slag 25 and converter exhaust gases 19 continuously generated during converter operation in the direction of the furnace vessel 1 and

- Setting of approximately constant conditions with respect to the amount, composition and temperature of crude steel melt 24, slag 25 and exhaust gases 19 in the converter vessel 3, which depends on the required properties and the desired tapping speed of the crude steel 24 via the tap opening 41 (ie the desired one Plant productivity) are adapted and in turn are regulated within certain limits by the crude steel tapping speed and the fresh speed in the converter vessel 3.

In the case under consideration, the fresh process in converter vessel 3 takes place quasi-steadily with very intensive bath mixing with continuous supply of the following substances, media and energies or under the following process conditions:

- approx. 4.46 t / min C-rich, low-Si premelt with the above properties of furnace vessel 1, - Approx. 0.59 t / min fine scrap 12 as coolant through the charging openings 39 in the converter cover 37, the composition of the fine scrap 12 roughly corresponding to the mixed scrap composition according to Table I and the max. Piece length is <100 mm,

Lump lime 14, quartzite and lump coal 13 also through the charging openings 39 in the converter cover 37,

Gas oxygen 27 via the water-cooled converter lance 35 ',

- Gas oxygen 27 via the afterburning lances 35 and

- N, 30 and natural gas 29 via the bottom flushing nozzles 36 of the converter vessel 3

The products of the converter vessel 3 are also continuously and semi-continuously removed, including:

- approx.4.87 t / min (= approx. 292 t / h) crude steel 24 with the properties

0.05% C approx. 620 ppm O dissolved

0.14% Mn approx. 30 ppm N

Traces Si <1.5 ppm H

0.026% S

0.0038% P T = 1620 ° C

0.21% Cu via the tap opening 41 in the converter vessel 3,

- Liquid, FeO _n -rich, highly basic converter slag 25 with the properties approx.25.0% FeO _n 0.27% P, O ₅ approx.5.0% Fe _met 0.21% S

42.0% CaO basicity (CaO / SiO,) = 3.55

7.9% MgO temperature ~ 1620 ° C

4.8% MnO 11.8% Si0 ₂

2.9% Al, O ₃ over weir 34 towards furnace vessel 1 and

- Converter exhaust gas 19 including dust in the converter exhaust gas with the following properties:

Exhaust gas phase ') Exhaust gas (dust)

84.0 vol. % CO 91.2% FeO _n

9.3 vol. % CO, 3.5% CaO 3.0 vol. % H ₂ 0.7% SiO ₂

1.4 vol. % H, O 0.8% C 0.6 vol. % N, 1.7% ZnO

1, 2 vol. % O, balance = MgO + MnO + Al ₂ O ₃ + SnO- + P ₂ O _s

Rest = Ar + SO, + F 2

Total degree of afterburning 11.0% temperature - 1620 ° C. which reaches the furnace vessel 1 directly from the converter vessel 3.

Important process variables for the process flow in furnace vessel 1 and in converter vessel 3 are given in the following table:

Embodiment 2

The bet mix consists of

40% steel scrap

30% sponge iron (pellets) and

30% liquid pig iron with the properties given in Table II.

'(t Met.Product / t Met.Use) xl00 In this case, with regard to the system configuration to be used and the basic process sequence, there is in principle no significant difference from the above-mentioned exemplary embodiment 1. Differences in the system configuration and the technology management result from the different quantity ratios and properties of the components in the application mix. The system variant according to FIG. 1 also serves to carry out the method, however

- Using the scrap preheating shaft 5 with the small useful cross section of approx. 5 m ² , the difference to the scrap preheating shaft 5 with the large useful cross section of approx. 11.5 m ² due to an additional cover piece matching the preheating shaft 5 with the small useful cross section in the lid 4 of the furnace vessel 1 is replaced. The additional cover piece (not shown) is identical to the cover 4 of the furnace vessel 1 and, when using the shaft 5 with the small useful cross-section, is firmly locked with it, so that a gas-tight unit is produced,

- and using only one of the two scrap conveyor belts 8 for transporting, preheating (within the same, already described heating part 9) and filling the scrap 7 in the scrap preheating shaft 5 with the small usable cross section, i.e. is active, with only that half of the total of ten natural gas / oxygen / air combi burners / lances 10 being operated above the active scrap conveyor belt 8 in the heating part 9, while the second half of the heating part 9 (behind the refractory dam already mentioned) and the second scrap conveyor belt 8 remain passive, ie not be operated.

Further differences from exemplary embodiment 1 are that in the present case there is a continuous supply of molten pig iron 20 via pig iron channel 21 and sponge iron pellets 12 via charging openings 11 into furnace vessel 1. Sponge iron pellets 12 are introduced as coolant into the converter vessel 3, etc. in an amount of approx.8.8% of the mix, i.e. approx. 29.3% of the iron sponge pellets contained in the insert mix, the total proportion of which in the insert mix is 30%.

The total amount of scrap in the insert mix is charged with scrap loading cranes onto the scrap conveyor belt 8 and, after preheating in the heating part 9 and in the preheating shaft 5, continuously fed or melted into the furnace vessel 1. The average height of the scrap column 7 in the preheating shaft 5 is 2.5 m. The physical and chemical heat, partial afterburning of the exhaust gases 19 from the furnace vessel 1 and heat from a partial scrap oxidation during the preheating serves as the heat source for preheating the scrap 7 in the heating part 9 and in the preheating shaft 5. The partial post-combustion of the exhaust gases 19 in the preheating shaft 5 takes place in two stages, with cold air 28 and gas oxygen 27 being blown in continuously by the eight post-combustion nozzles 47 arranged in two levels in a volume ratio of approx. In the heating part 9, the preheating takes place gradually along the half with the active scrap conveyor belt 8 by continuously blowing in cold air 28 and gas oxygen 27 through the five combi burners / lances 10 in the lid of the heating part 9, which are arranged above the active scrap conveyor belt 8.

The continuous melting of the scrap 7 preheated in the heating part 9 and in the preheating shaft 5 takes place in the furnace vessel 1 with likewise continuous supply of the liquid pig iron 20 via the pig iron channel 21 and approx. 70.7% of the sponge iron pellets 12 contained in the insert mix via the charging openings 11. The resulting molten metal 24 is simultaneously carburized in the furnace vessel 1 to form a low-Si, C-rich melt and partially freshed. The metal melt has the following properties before it overflows into the converter vessel 3 via the weir 34:

including non-metallic components '' portion of furnace vessel 1

"(t Met.Product / t Met.Use) xl00 1.69% C approx. 1550 ° C

0.14% Mn liquidus temperature approx. 1413 ° C

<0.05% Si

0.025% S

0.008% P

The molten metal 24 in the furnace vessel 1 has approximately the above-mentioned properties during the entire process.

The melting and fresh process in the furnace vessel 1 takes place continuously and quasi-steadily with very intensive bath mixing with continuous supply of the following substances, media and energies or under the following process conditions:

2.19 t / min of preheated scrap 7 with a temperature of approx. 1057 ° C. via the shaft 5,

1.60 t / min of molten pig iron 20 with properties according to Table II via pig iron gutter 21,

1.13 t / min sponge iron pellets 12 with properties according to Table II through the charging openings 11,

liquid, FeO _n -rich, highly basic (CaO / SiO ₂ = 3.55) and hot converter slag 25 with a temperature of approximately 1620 ° C., which flows from the converter vessel 3 into the furnace vessel 1 against the metal flow direction via the weir 34,

- Lime 14 (approx. 60% thereof as blown lime via the lime nozzles 35 and approx., 40% thereof as lump lime via the charging openings 11 in the lid 4 of the furnace vessel 1, blown lime lump lime ratio can be changed as desired),

Blow coal (fine coal) 13 via a manipulator lance 32 or 33 and via the coal under bath nozzles 33 in the furnace vessel 1,

Natural gas 29 and gas oxygen 27 via three burners 32a of the furnace vessel 1,

N ₂ 30 and natural gas 29 via the inert gas bottom nozzles 33 of the furnace vessel 1,

Gas oxygen 27 via the manipulator lances 32 and / or 23 of the furnace vessel 1,

False air (not shown in FIG. 1), which is sucked in from the outside environment primarily through the slag door 22, but also via the electrode gaps in the lid 4, due to the negative pressure in the furnace vessel 1, into the furnace vessel 1,

- Blow air 28 as a conveying gas via the lances / nozzles 35, 32, 23 and 33 and approx. 53.2 MW continuous electrical energy input via the electrodes 16 to cover the heat requirement in the furnace vessel 1, which entry in the present case with an overall system productivity of approx. 4.94 t crude steel min (approx. 296 t crude steel / operating hour) an electrical energy consumption of approx. 179.6 kWh t of crude steel.

4.67 t / min C-rich, low-Si melt 24 with the above-mentioned properties via weir 34 in the direction of converter vessel 3,

- approx. 428 kg min slag 25 with the following properties approx. 12.4% FeO „0.87% P, 0 ₅ approx. 5.0% Fe _met 0.16% S 42.1% CaO basicity (CaO / SiO,) = 2.0

7.3% MgO temperature - 1550 ° C,

4.4% MnO 21.0% SiO,

6.8% A1.0 ₃

which leaves the system continuously via the decanting part 2 through the slag door 22, approx. 452 Nm ³ / min exhaust gas 19 and approx. 79.8 kg / min dust in the exhaust gas with the following

characteristics

Exhaust gas phase) Exhaust gas f dust) 40.7 vol.% CO 79.7% FeO _n 25.5 vol.% CO, 9.4% CaO l, 4 vol.% H, 3.5% SiO,

3.6 vol.% H, 0 1.4% C 26.5 vol. % N ₂ 2.0% ZnO

1.7 vol. % 0, rest = MgO + MnO + Al ₂ 0 ₃ + SnO, + P, 0 ₅ rest = Ar + SO, + F ₂

Total degree of afterburning 40.9%

Temperature - 1570 ° C, which get from the furnace vessel 1 into the scrap preheating shaft 5. After the overflow over the weir 34, the C-rich, low-Si melt 24 reaches the converter vessel 3 continuously and at an average speed of 4.67 t / min and mixes with the crude steel melt which is always present in the converter vessel 3 during a very intensive bath movement 24 with continuously regulated properties within narrow tolerances:

- quantity of approx. 90 t,

C = 0.05% T = 1620 ° C

Above the crude steel melt 24, the liquid converter slag 25 collects in the converter vessel 3, the surface of which at a slag layer height in the converter vessel 3 of approximately 1.8-2.0 m up to 0.5-1.0 m higher than that in the furnace vessel 1 lies and consequently overflows, driven by gravity and impulses from the bath movement in the converter vessel 3, via the weir 34 into the furnace vessel 1.

In the present case, the same task applies to the continuous technology management in the converter vessel 3 as for the exemplary embodiment 1.

The fresh process takes place in the converter vessel 3 with very intensive bath mixing quasi-steadily with continuous supply of the following substances, media and energies or under the following process conditions:

4.67 t / min C-rich, low-Si premelt 24 with the above-mentioned properties from the furnace vessel 1,

0.47 t / min sponge iron pellets 12 as coolant through the charging openings 39 of the converter cover 37, the properties of the sponge iron pellets 12 being given in Table II,

Lump lime 14, quartzite and lump coal 13 also through the charging openings 39 of the converter cover 37,

Gas oxygen 27 via the water-cooled converter lance 35 ',

- Gas oxygen 27 via the afterburning lances 35 and

- Nitrogen 30 and natural gas 29 via the bottom flushing nozzles 36 of the converter vessel 3. The products of the converter vessel 3 are also continuously and semi-continuously discharged, etc.

- approx. 4.94 t min (= approx. 296 t / h) crude steel 24 with the properties 0.05% C approx. 620 ppm 0 dissolved 0.08% Mn approx. 30 ppm N traces Si <1.5 ppm H 0.022% S 0.0038% PT = 1620 ° C 0.08% Cn via tap hole 41 the converter vessel 3,

- Liquid, FeO _n -rich, highly basic converter slag 25 with the properties approx.25.0% FeO _n 0.28% P ₂ O ₅ approx.5.0% Fe _met 0.145% S

41.9% CaO

8.4% MgO basicity (CaO / SiO,) = 3.55 2.6% MnO temperature - 1620 ° C 11.8% SiO, 4.8% Al, O ₃ via weir 34 towards furnace vessel 1 and

- Converter exhaust gas 19 including dust of the converter exhaust gas with the following properties

Exhaust gas (gas phase) Exhaust gas (dust 84.8 vol.% CO 93, l% FeOn 9.4 vol.% CO, 3.5% CaO 2.3 vol.% H, 0.7% SiO, 1.1 vol .% H, 0 0.7% C 0.5 vol.% N, 0.3% ZnO l, 3 vol.% O, rest = MgO + MnO + Al, 0 ₃ + Sn0 ₂ + P, 0 ₅ rest = Ar + SO, + F, total degree of afterburning 10.8% temperature - 1620 ° C, which go directly from the converter vessel 3 into the furnace vessel 1.

Embodiment 3

The bet mix consists of

50% sponge iron pellets and 50% liquid pig iron

Values for the preheated scrap

(t Met.Product / t Met.Use) x! 00 with the properties given in Table II. In this case, the system variant according to FIGS. 3 and 4 is used to carry out the method. Since there is no scrap in the mix of uses, neither a heating part 9 nor a preheating shaft is required. The basic process sequence is very similar to that of embodiment 2, differences in terms of system configuration and technology testing primarily concern the furnace vessel 1, if in the present case

The scrap preheating shaft 5 is replaced with a conventional water-cooled furnace manifold as a connecting piece between the furnace vessel 1 and a hot gas line, not shown in FIG. 3, as is common today for any conventional electric arc furnace,

• The five natural gas / oxygen burners 32a in the furnace vessel 1 are not operated as a burner and are either protected with air to prevent damage until the next need for use or occasionally (but not in the present case) as additional post-combustion nozzles 32a to those in the lid 4 of the furnace vessel 1 existing post-combustion lances 35 are used, and

• provided there is no significant difference to the conventional electric arc furnace with this system and process variant with regard to exhaust gas characteristics (temperature, degree of afterburning, dust content, etc.), ie that the physical and chemical heat of the exhaust gases 19 from the furnace vessel 1 remains largely unused and the dust content in the Exhaust gas 19 is comparable to that of the conventional electric arc furnace.

In the present case, approx. 24% of the iron sponge pellets 12 contained in the insert mix, i.e. approx. 12% of the total insert mix, continuously used as coolant in the converter vessel 3. The remaining amount (main amount) of the insert mix components is also continuously charged into the oven vessel 1, namely

- The liquid pig iron 20 via the pig iron channel 21 and

- Approx. 76% of the iron sponge pellets 12 contained in the insert mix via the charging openings 11.

The metal melt 24 which arises with the supply of electrical energy in the furnace vessel 1 is simultaneously carburized to a low-Si and C-rich melt (here very limited coal supply) and partially refreshed, so that it follows the weir 34 before overflow into the converter vessel 3 Features:

1.98% C approx. 1550 ° C

0, 10% Mn liquidus temperature approx. 1394 ° C <0.05% Si 0.023% S 0.009% P

The molten metal 24 in the furnace vessel 1 has approximately the above-mentioned properties over the entire process.

2.56 t / min of molten pig iron 20 with properties according to Table II via pig iron channel 21,

1.94 t / min sponge iron pellets 12 with properties according to Table II through the charging openings 11,

liquid, FeO _n -rich, highly basic (CaO / SiO, = 3.53) and hot converter slag 25 with a temperature of approximately 1620 ° C., which flows from the converter vessel 3 against the metal flow direction via the weir 34 into the furnace vessel 1,

- Lime 14 and dolomite 14 (approx. 60% thereof as blown lime or blown dolomite via the lime nozzles 35 and approx. 40% thereof as lump lime or lump dolomite 14 via the charging openings 11 in the lid 4 of the furnace vessel 1, the ratio blown material / lump material freely changeable),

Blow coal (fine coal) 13 via one or more of the manipulator lances 32, 33 and / or the coal sub-bath nozzles 33 of the furnace vessel 1,

Nitrogen 30 and natural gas 29 via the inert gas bottom nozzles 33 of the furnace vessel 1,

Gas oxygen 27 via the manipulator lances 32 and 23 of the furnace vessel 1,

False air (not shown in FIG. 3), which is sucked into the furnace vessel 1 primarily through the slag door 22 but also via the electrode gaps in the lid 4 due to the negative pressure in the furnace vessel 1,

Blow air 28 as conveying gas via the lances / nozzles 35, 32, 23 and 33,

- Approx. 53.2 MW of continuous electrical energy input via the electrodes 16 to cover the heat requirement in the furnace vessel 1, which entry in the present case with a total plant productivity of approx. 4.67 t crude steel / min (approx. 280 t crude steel / operating hour) Corresponds to electrical energy consumption of approx. 190.0 kWh t of crude steel. The products of the furnace vessel 1 are also continuously and semi-continuously removed, including:

4.27 t / min C-rich, low-Si melt 24 with the above-mentioned properties via the weir 34 into the converter vessel 3,

- approx. 415 kg / min slag 25 with the following properties approx. 12.0% FeO _n 1.13% P ₂ 0 ₅ approx. 5.0% Fe _mct 0.15% S

43.1% CaO basicity (CaO / SiO ₂ ) = 2.0

7.2% MgO temperature - 1550 ° C,

3.1% MnO 21.5% SiO, 6.7% Al, O ₃ which continuously leaves the system via the decanting part 2 through the slag door 22 and

- approx. 500 Nm ³ / min exhaust gas 19 and approx. 74.7 kg / min dust in the exhaust gas with the following properties

Exhaust gas (gas phase) Exhaust gas (dust ^* )

50.9 vol.% CO 82.2% FeOn

21.8 vol.% CO, 10.0% CaO l, 0 vol.% H, 3.7% SiO, l, 6 vol.% H ₂ O 0.7% C

22.8 vol.% N, balance = MgO + MnO + Al, O ₃ + P, O ₅ l, 5 vol.% O, balance = Ar + SO, + F ₂ total degree of afterburning 31, 2% temperature - 1545 ° C, which get from the furnace vessel 1 via the furnace manifold into the hot gas line of an exhaust gas treatment system.

After the overflow over the weir 34, the C-rich, low-Si melt 24 reaches the converter vessel 3 continuously at an average speed of 4.27 t / min and mixes with the crude steel melt 24 which is always present in the converter vessel 3 during a very intensive bath movement with continuously regulated properties within narrow tolerances:

- quantity of approx. 90 t,

- metal bath level in converter vessel 3 approx. 0.5 m below the level of weir 34, - Composition (in particular C content) and temperature equal to the desired crude steel tapping values, in the present case as follows:

C = 0.05% T = 1620 ° C

In the present case too, the same task applies to the continuous technology management in the converter vessel 3 as for the exemplary embodiments 1 and 2.

The fresh process takes place in the converter vessel 3 with very intensive bath mixing, quasi-steadily with continuous supply of the following substances, media and energies or under the following process conditions:

4.27 t / min C-rich, low-Si premelt 24 with the above-mentioned properties from the furnace vessel 1,

0.62 t / min iron sponge pellets 12 as coolant through the charging openings 39 of the converter cover 37, the properties of the iron sponge pellets 12 being given in Table II,

Lump lime 14 and lump coal 13 also through the charging openings 39 of the converter cover 37,

Gas oxygen 27 via the water-cooled converter lance 35,

Gas oxygen 27 via the afterburning lances 35,

Nitrogen 30 and approx. Natural gas 29 via the bottom flushing nozzles 36 of the converter vessel 3,

The products of the converter vessel 3 are also discharged continuously and semi-stationary, including:

approx. 4.67 t min (= approx. 280 t / h) crude steel 24 with the properties 0.05% C approx. 620 ppm O dissolved

0.05% Mn approx. 30 ppm N

Traces Si <1.5 ppm H

0.021% ST = 1620 ° C 0.0038% 0 via the tap opening 41 of the converter vessel 3. Liquid, FeO _n -rich, highly basic converter slag 25 with the properties approx. 25.0% FeO _n 0.30% P ₂ O _s approx. 5.0% Fe _mcl 0.13% S 42.4% CaO basicity (CaO / SiO,) = 3.53 7.8% MgO temperature - 1620 ° C 1.7% MnO 12.0% SiO, 5.6% Al ₂ O ₃ over the weir 34 in the direction of the furnace vessel 1 and converter exhaust gas 19 including dust in the converter exhaust gas with the following properties

Exhaust gas (gas phase exhaust gas (dust 79.6 vol.% CO 92.8% FeO _n 14.1 vol.% CO, 4.1% CaO 2.1 vol.% H, 0.9% SiO, 1.6 vol .% H, 0 1.0% C 0.4 vol.% N ₂ rest = MgO + MnO + AUOj + PjOj l, 6 vol.% O ₂ rest = Ar + SO, + F ₂ total afterburning degree 16.1 % Temperature - 1635 ° C, which reach the furnace vessel 1 directly from the converter vessel 3.

Important process parameters and the achievable productivity for the above-mentioned exemplary embodiments can be seen in Table V, while Table VI contains a summary of the consumption figures for the production of 1 t of crude steel using the process and plant variants according to the invention.

Values for molten pig iron

(t Met.Product / t Met.Use) xl00 Table V Process parameters and productivity for working examples 1 to 3

Table VI Consumption figures for working examples 1 to 3:

In addition to the production of crude steel, the described system concept, etc. in the variant without preheating shaft 5 and without heating part 9, can also be used for the pretreatment of molten metals with or without iron, in special cases operation with negative pressure (e.g. up to 0.1 bar residual pressure in the entire vessel) would also be conceivable.

Example 4:

Pretreatment of molten pig iron, etc. Desilication, dephosphorization and

Desulfurization, which according to the invention takes place as follows:

• Continuous supply of molten pig iron (e.g. directly from the pig iron gutter of a blast furnace or a smelting reduction system or from an intermediate container) with the properties

T = 1440 ° C (blast furnace) 4.3% C

0.6% Si 0.5% Mn 0.100% P 0.040% S

• Continuous pre-freshening and, if necessary, heating with electrical energy in the furnace vessel 1 to produce a low-Si intermediate product with the properties

4.0 - 4.1% C T 1300 - 1400 ° C

<0.10% Si (can be set as required)

0.4-0.5% Mn 0.060-0.080% P 0.030-0.035% S

continuous finishing of the low-Si intermediate product in the converter vessel 3 and, if necessary, heating (by partial decarburization) to pretreated pig iron with the properties

3.5 - 4.0% C T = 1350 - 1400 ° C

<0.05% Si 0.3-0.4% Mn

<0.020% P

<0.025% S This pig iron pretreated in this way is tapped continuously from the converter vessel 3 (e.g. into a downstream intermediate container) or discontinuously into an intermediate container or in pig iron pans) and later used either in a converter or in an electric arc furnace or cast on a casting machine to pig iron pellets. • During the process, both in the furnace vessel 1 and in the converter vessel 3

- Oxygen in the form of gas oxygen (lances, nozzles) and / or oxide oxygen in the form of Fe ore, Mn ore, scale, dried FeO _n -rich sludge, etc. via lances, nozzles or charging chutes and

- Slag formers (lime, fluorspar, etc.), preferably in pieces and if necessary

- Carbon carriers (coal, coke etc.) as well

- Inert gas (N ₂ ) continuously fed as a floor purging, so that the process parameters necessary to achieve the desired results, such as temperature control, slag control (basicity approx. 3.0 - 3.5 in converter vessel 3, approx. 1.8 - 2 in furnace vessel 1 ), Bath mixing and proportions of metal / slag in the converter and in the furnace vessel can be set.

Since the need for electrical energy in the above application example is low (5 - 10 kWh / t pig iron) at the same temperature of the used and the pretreated pig iron, liquid pig iron (= 600 t / h) is required for a system productivity of 10 t min Furnace vessel 1 provided only a weak transformer of 20 MVA. For most practical cases (pig iron with P <0.200%), the electrodes in the furnace vessel 1 can be omitted.

With appropriate technology management, the above process flow can also be used effectively for the pretreatment of special pig iron with a high content of V, Ti, Mn and P. However, the process and the system are also suitable for the production of molten pig iron with a very low content of accompanying elements (Si, Mn, P and S at the same time), i.e. very suitable for producing a "SORELMETAL" type pig iron from conventional pig iron.

Embodiment 5

The process and system application is further explained using an example for the production of a Cr and Ni-rich premelt for the production of stainless steel by subsequent VOD treatment. The process flow according to the invention is as follows: The solid feed materials 7, consisting of

• unalloyed and / or alloyed steel scrap

• FeCrHc, FeMo

• Ni metal and or FeNi

Ore, e.g. Chromium, nickel, manganese, molybdenum etc. ores are continuously introduced in a system according to FIGS. 1 and 2 with the conveyor belt 8 via the heating part 9 into the preheating shaft 5 or into the electric arc furnace vessel 1 and preheated. When using liquid feedstocks 20, e.g.

• Pig iron, preferably pre-phosphorous pig iron (% P <0.025), and / or

Liquid FeCrHC (from an electric arc furnace or an induction furnace) are fed continuously into the electric arc furnace vessel 1 via the filler trough 21.

The melting process in the electric arc furnace 1 takes place continuously with intensive bath mixing under the following conditions:

Continuous supply of gaseous oxygen 27 and inert gas 30 (N, Ar) via nozzles 33, the O, / NJ Ar ratio being arbitrarily adjustable,

• continuous supply of gas oxygen 27 via lances 23, 32, and

• Continuous addition of slag formers 14, such as burnt lime, burnt dolomite, fluorspar etc. - in pieces via the charging openings 11 and / or fine-grained via the nozzles 33 and / or lances 23, 32.

The aim of the process control in the electric arc furnace 1 is the quasi-stationary setting of certain process parameters, which are as follows when producing a premelt for austenitic steel grade 304:

• The molten metal 24 always has approximately constant properties within the tolerances

1.5-2.0% C (depending on application mix) T = 1620-1630 ° C

<0.2% Si

<0.5% Mn 17.0-18.5% Cr approx.6.5% Ni • Liquid slag 25 always with an approximately constant composition, for example as a directional analysis

48% CaO rest = MnO, A1.0 ₃ etc.

31% SiO, (depending on the mix of uses)

<5% MgO

<4% Cr, O ₃

<2% FeO _n

which continuously leaves the system via the decanting part 2 through the slag door 22.

During operation, the molten metal 24 with the properties mentioned above runs continuously from the electric arc furnace vessel 1 via the weir 34 into the converter vessel 3 and mixes with the very intense bath movement with the crude steel melt 24 which is always present in the converter vessel 3, which in the present case is a Represents premelt for the next VOD treatment and is always kept in the converter vessel 3 at the composition and temperature desired for tapping about 0.25% C about 1700-1710 ° C.

The fresh run (mainly decarburization) takes place in converter vessel 3 under the following process conditions:

• Continuous supply of gas oxygen 27 and inert gas 30 (N ₂ Ar) via nozzles 36, the O, / N, / Ar ratio being freely adjustable; in the present case the top lance 35 'is not used, the preferred decarburization rate is 0.03-0.05% C / min,

Temperature of the metal bath 24 from 1700-1710 ° C,

• Continuous supply of insert mix components as coolants and alloying agents 12 - Ni and / or FeNi, low-Si FeCrHC and or FeMnHC etc.

Continuous supply of slag formers 14, such as burnt lime, burnt dolomite, fluorspar, etc. - preferably in pieces via the charging openings 39, optionally also in fine-grained form via the nozzles 36, Formation of an almost solid slag 25 with an approximately constant composition, for example as a directional analysis approx. 30% CaO 2-5% Al ₂ O ₃ <5% CaF,

<15% SiO, <5% FeO _n

13-17% Cr, O ₃ approx. 10% Fe _met

5-8% MgO <4% Cr _met

The metal product 24 - a premelt with the properties mentioned above for subsequent VOD treatment - is tapped from the converter vessel 3 via the metal tapping device 41. The metal tapping can be carried out continuously or discontinuously without interrupting the process in the electric arc furnace vessel 1.

The exhaust gases 19 which arise in the converter vessel 3 and in the electric arc furnace vessel 1 are drawn off uniformly via the preheating shaft 5 and the heating part 9 and at the same time are used for preheating the solid starting materials 7. The bed in the preheating shaft 5 performs a pre-filter function with regard to dust content in the exhaust gas 19.

In order to avoid an excessive accumulation of the slag 25 in the converter vessel 3 or to prevent the resulting fermentation, a so-called “washing-out process” is carried out after about 3 hours of operation, for example by feeding somewhat higher amounts of FeSi, lime and fluorspar into the converter vessel 3 This process enables liquefaction of the slag 25 in the converter vessel 3 and at the same time a reduction in the Cr, O ₃ content, so that the slag 25 can easily move in countercurrent movement to the metal 24 via the weir 34 into the adjacent electric arc furnace vessel 1 can occur, without causing high Cr losses, before it then mixes with the slag portion formed in the electric arc furnace 1. The so-called washing process is carried out both when the system is operated with continuous and when operated with discontinuous tapping of the metal 24 from the converter vessel 3 without special effort and essential produktivi throttling feasible.

The method according to the invention can also be used for the production of stainless grades with a low C content (<0.05%), ie without a VOD system. In this case, the deoxidation and desulphurization of the steel takes place in a manner similar to that for carbon steel production during tapping off the converter vessel 3 and the subsequent secondary metallurgical treatment (for example in a ladle furnace or at a rinsing station). Significant advantages of the method according to the invention compared to known, discontinuous stainless production methods are:

- Much higher process and plant productivity

- Ensuring optimized slag guidance and high decarburization efficiency Saving of reduction silicon, slag formers and energy sources - (C-carrier and / or electrical energy)

Reduction of electricity consumption

Claims

Claims:

1. Plant for the production of metal melts, in particular iron melts, such as steel melts or crude steel melts, with

• An electric arc furnace vessel (1) which has at least one charging opening (11, 21) for a molten metal and / or scrap and / or direct reduced metal, in particular direct reduced iron and / or ore and at least one electrode (16) and at least one a slag tapping device (22) is provided,

• An oxygen blowing converter vessel (3) which is provided with at least one metal tapping device (41), wherein

The oxygen-blowing converter vessel (3) with the electric arc furnace vessel (1) forms a unit connected by an overflow weir (34),

• The bath surface in the oxygen blowing converter vessel (3), which is specific to the bath volume, is smaller than in the electric arc furnace vessel (1) and

• The oxygen blowing converter vessel (3) with the electric arc furnace vessel (1) has a common reaction space above the bath level of these vessels.

2. Plant according to claim 1, characterized in that the unit of oxygen blowing converter vessel (3) and electric arc furnace vessel (1) is rigidly mounted on the foundation.

3. Plant according to claim 1 or 2, characterized in that the metal bath level of the oxygen blowing converter vessel (3) is below the metal bath level of the electric arc furnace vessel (1).

4. Plant according to one or more of claims 1 to 3, characterized in that the bottom of the oxygen blowing converter vessel (3) is arranged at a lower level than the bottom (18) of the electric arc furnace vessel (1).

5. Plant according to one or more of claims 1 to 4, characterized in that the oxygen blowing converter vessel (3) is equipped with at least one blowing lance (35, 35 ') for oxygen or an oxygen-containing gas mixture.

6. Plant according to one or more of claims 1 to 5, characterized in that the oxygen blowing converter vessel (3) is equipped with floor nozzles (36), preferably with oxygen blowing floor nozzles.

7. Plant according to one or more of claims 1 to 6, characterized in that the electric arc furnace vessel (1) is provided with at least one metal tapping device (43).

8. Plant according to one or more of claims 1 to 7, characterized in that the slag tapping device (22) is provided on a with the electric arc furnace vessel (1) forming a unit decanting vessel (2), (Fig. 3, 6, 8) preferably diametrically opposite the overflow weir (34).

9. Plant according to one or more of claims 1 to 8, characterized in that the oxygen blowing converter vessel (3) and or the electric arc furnace vessel (1) with a charging opening (11, 39) for charging metallic feedstocks, ore , Additives, alloys, carburizing agents.

10. Plant according to one or more of claims 1 to 9, characterized in that the oxygen blowing converter vessel (3) and / or the electric arc furnace vessel (1) with an oxygen-containing gas or oxygen-supplying afterburning nozzles and / or lances (35 ), preferably at least one of them in the vicinity of the transition between the two vessels (1, 3).

11. Plant according to one or more of claims 1 to 10, characterized in that the electric arc furnace vessel (1) with at least one fixed iron support (7) leading preheating shaft (5) above the electric arc furnace vessel (1 ) and is preferably arranged laterally on this or in a ring above the furnace vessel (1).

12. Plant according to claim 11, characterized in that in the preheating shaft (5) at least one preferably with a housing (6) provided conveyor belt (8) opens (Fig. 1, 5, 7).

13. Plant according to claim 12, characterized in that in the housing (6) open heating devices (10) which are designed as built-in afterburning devices (10) and / or burners with an oxygen-containing gas supply lines (Fig. 1, 7).

14. Plant according to one or more of claims 1 to 13, characterized in that at least part of the inner surface of the preheating shaft (5) and / or the housing (6) and / or the lid (4) of the electric arc furnace vessel (1) and / or the lid (37) of the oxygen blowing converter vessel (3) is lined with refractory materials.

15. Plant according to one or more of claims 1 to 14, characterized in that the electric arc furnace vessel (1) is equipped with a device (21) supplying a molten metal (20), preferably liquid pig iron.

16. Plant according to one or more of claims 11 to 15, characterized in that the electric arc furnace vessel (1) is equipped with a preheating shaft (5) which is arranged above the electric arc furnace vessel (1) and above a gas-permeable cooled shut-off device (5 ") opens into the electric arc furnace vessel (1) (Fig. 9, 10).

17. Plant according to claim 16, characterized in that the preheating shaft (5) is arranged centrally above the electric arc furnace vessel (1) and the cover (4) of the electric arc furnace vessel (1) in an annular manner, the preheating shaft (5 ) surrounding and connecting them to the side walls of the electric arc furnace vessel (1), wherein electrodes (16), preferably graphite electrodes, protrude obliquely through the cover (4) into the interior of the electric arc furnace vessel (1) ( 9, 10).

18. Installation according to one or more of claims 1 to 17, characterized in that in the interior of the electric arc furnace vessel (1) opening nozzles (33) and / or lances (32) and or burners (32a) are provided, which either to an iron carrier feed device and / or an ore feed device and / or a coal or carbon carrier feed device and / or a slag former feed device and or or an oxygen or an oxygen-containing gas feed device and / or a hydrocarbon feed device and or an inert gas supply device is connected.

19. Plant according to one or more of claims 1 to 18, characterized in that in the oxygen blowing converter (3) nozzles (36) and / or lances (35) are arranged, which either to an iron carrier feed device and / or an ore feed device and / or a carbon or carbon carrier feed device and / or a slag generator feed device and / or an oxygen or an oxygen-containing gas feed device and or a hydrocarbon feed device and / or an inert gas feed device are connected. 00

20. Plant according to claim 18 or 19, characterized in that the nozzles (33, 36) are designed as Unterbaddüsen and / or floor purging stones or the lances (32, 35) are arranged to be movable, in particular pivotable and / or in their longitudinal direction -3gb ¹ - ar are.

21. Plant according to one or more of claims 1 to 20, characterized in that the electric arc furnace vessel (1) with approximately centrally arranged (arranged), projecting into the vessel (1) from above (n) electrode (s) (16) and optionally provided with a bottom electrode (17) (Fig. 1).

22. Plant according to one or more of claims 11 to 21, characterized in that the preheating shaft (5) as the electric arc furnace vessel (1) and from the housing (6) detachable and replaceable unit is designed.

23. Plant according to one or more of claims 1 to 22, characterized in that the lid (4) of the electric arc furnace vessel (1) and the lid (37) of the oxygen blowing converter vessel (3) form a unit or as a unit are executed.

24. Plant according to one or more of claims 1 to 23, characterized in that at least one control and or repair opening (50) is provided, preferably above the transition from the electric arc furnace vessel (1) to the oxygen blowing converter vessel (3) .

25. Plant according to one or more of claims 1 to 24, characterized in that the oxygen blowing converter vessel (3) is designed as a removable and replaceable structural unit from the electric arc furnace vessel (1).

26. Plant according to one or more of claims 1 to 25, characterized in that the electric arc furnace vessel (1) with a in the direction of the decanter (2) sloping bottom (18) is equipped and in an approximately horizontal bottom part of the decanter (2) passes, the deepest point of the bottom being arranged in the decanter (2) and a metal tapping device (43) being provided at the deepest point of the bottom (18) of the decanter (2).

27. Process for producing molten metals, in particular molten steel, such as crude steel melts or alloyed steel melts or stainless steel melts or Stainless steel melting, using a system according to one or more of claims 1 to 26, characterized by the combination of the following process steps:

A premelt is produced in the electric arc furnace vessel (1) and brought to a certain temperature level and to a certain chemical composition,

The premelt flows continuously via the overflow weir (34) into the oxygen blowing converter vessel (3),

• The premelt is continuously refined in the oxygen blowing converter vessel (3), preferably to raw steel and

The fresh melt is discharged continuously or discontinuously from the oxygen blowing converter vessel (3),

• The slag that forms in the oxygen blowing converter vessel (3) flows in countercurrent to the metal into the electric arc furnace vessel (1), from which it is drawn off.

28. The method according to claim 27, characterized in that the electric arc furnace vessel (1) is pre-freshened and in the oxygen blowing converter vessel (3) the finished freshening.

29. The method according to claim 27 or 28, characterized in that in the oxygen blowing converter vessel (3) a chemical composition and a temperature of the molten metal are set in a continuous manner, which correspond to the chemical composition and the temperature of the finished melt or the end product, respectively are desired at racking.

30. The method according to one or more of claims 27 to 29, characterized in that the exhaust gases formed in the oxygen blowing converter vessel (3) are derived via the electric arc furnace vessel (1), with a CO + H, afterburning both in the Oxygen blowing converter vessel (3) as well as in the electric arc furnace vessel (1) is carried out.

31. The method according to one or more of claims 27 to 30, characterized in that the exhaust gases arising in the electric arc furnace vessel (1) and in the electric arc furnace vessel (1) from the oxygen blowing converter vessel (3) overflowing exhaust gases can be used to preheat the lumpy charging material introduced into the electric arc furnace vessel (1).

32. The method according to one or more of claims 27 to 31, characterized in that the exhaust gases used for preheating are afterburned during the preheating process.

33. The method according to one or more of claims 27 to 32, characterized in that a negative pressure is maintained in the electric arc furnace vessel (1) and in the oxygen blowing converter vessel (3).

34. Method for producing pig iron melts using a plant according to one or more of claims 1 to 26, characterized by the combination of the following process steps:

• Pig iron is charged in liquid form into the electric arc furnace vessel (1) and brought to a certain temperature level,

The Si and P content is reduced in the electric arc furnace vessel (1),

The liquid pig iron flows continuously via the overflow weir (34) into the oxygen blowing converter vessel (3),

The molten pig iron is continuously partially refreshed in the oxygen blowing converter vessel (3),

• The partially freshed pig iron is removed continuously or discontinuously from the oxygen blowing converter vessel (3) and

• The slag which forms in the oxygen blowing converter vessel (3) flows in countercurrent to the metal into the electric arc furnace vessel (1), from which it is drawn off.

35. The method according to claim 34, characterized in that the partly freshed pig iron is finished fresh in a conventional manner in a converter or electric arc furnace provided in addition to the system.

36. The method according to one or more of claims 27 to 35, characterized in that the metallic insert mix of at least one of the following components

Scrap (7), such as steel scrap, and / or solid pig iron or cast iron,

Direct-reduced iron (12) as pellets and / or briquettes and or iron carbide,

• liquid pig iron (20) is formed.

37. The method according to 36, characterized in that for the production of alloy steel melts or stainless steel melts or stainless steel melts the metallic Use mix is formed at least from alloyed steel scrap and liquid and / or solid alloying agents and or ferro alloys.

38. The method according to claim 37, characterized in that the steel melt tapped from the fuel blowing converter vessel (3) is further treated as a preliminary melt in a subsequent secondary metallurgical treatment including decarburization, either with or without negative pressure (vacuum).

39. The method according to claim 37, characterized in that the steel melt tapped from the oxygen blowing converter vessel (3) is used as a finished melt in a subsequent secondary metallurgical treatment, e.g. is further treated at a pan oven or flushing stand

40. The method according to one or more of claims 27 to 39, characterized in that after certain process times a liquefaction or reduction treatment of the slag is carried out in the oxygen blowing converter vessel (3).